Open Access Article
This Open Access Article is licensed under a Creative Commons Attribution-Non Commercial 3.0 Unported Licence

Classification, synthesis, characterization, and applications of metal nanoparticle-containing hybrid microgels: a comprehensive review

Muhammad Arif *a, Hamid Raza a and Toheed Akhter *b
aDepartment of Chemistry, School of Science, University of Management and Technology, Lahore 54770, Pakistan. E-mail: Muhammadarif2861@yahoo.com; Muhammadarif@umt.edu.pk
bDepartment of Chemical and Biological Engineering, Gachon University, Seongnam 13120, Republic of Korea. E-mail: toheed@gachon.ac.kr

Received 5th June 2024 , Accepted 4th July 2024

First published on 6th August 2024


Abstract

In the last ten years, there has been significant interest in the integration of metal nanoparticles (MNPs) in smart microgels (SMGs). These combined structures of metal nanoparticles and smart microgels possess unique behaviors that make them suitable for a wide range of applications in catalysis, environmental and biological fields. The intrinsic responsiveness of microgels within these hybrid systems shows significant potential for application across multiple fields. Extensive literature provides diverse insights into the morphologies and compositions of metal nanoparticles in microgels. The design of these hybrid microgels plays a crucial role in determining their applicability, leading to tailored solutions for specific purposes under specific conditions. This review aims to summarize the latest advancements in the classification, synthesis, responsiveness, characterizations, and applications of hybrid microgel systems. Additionally, it explores the recent advancements in the applications of metal nanoparticle-decorated microgels in catalysis, adsorption, sensing, biomedical and environmental fields.


image file: d4ra04128c-p1.tif

Muhammad Arif

Dr Muhammad Arif has been Professor (Assistant) of Chemistry in the Department of Chemistry, University of Management and Technology, Lahore, since 2022. He was previously a lecturer in Chemistry in the Department of Chemistry, School of Science, University of Management and Technology, Lahore, from 2017 to 2022. He received his PhD in Chemistry from the University of The Punjab, Lahore, Pakistan. He obtained his M.Phil in Chemistry and MSc in Organic Chemistry from Quaid-i-Azam University Islamabad, Islamabad, and the Institute of Chemistry, University of the Punjab, Lahore, Pakistan, respectively. His research area includes the synthesis, characterization and applications of metal nanoparticle-fabricated microgels and ligands.

image file: d4ra04128c-p2.tif

Hamid Raza

Dr Hamid Raza is a researcher in the field of MOFs, currently serving as Associate Professor in the Department of Chemistry and Dean at the Center for Teaching and Learning (CTL) at the University of Management and Technology (UMT), Lahore. He holds a PhD from UET, an M.Phil. from FCCU, an MSc. in Chemistry from Punjab University, an M.S. Ed from IER (PU), and a BSc from GCU, Lahore. His research spans materials science, environmental sustainability, and biotechnology, focusing on water purification, carbon capture, and photocatalytic activity. With 280 citations, an h-index of 9, and an i10-index of 9, Dr Raza's work is widely recognized. Published in diverse journals with a cumulative impact factor of 71.02, his contributions significantly advance the understanding and addressing of critical issues in these fields.

image file: d4ra04128c-p3.tif

Toheed Akhter

Dr Toheed Akhter, PhD, is Assistant Professor at Gachon University, South Korea, specializing in polymer and porous materials. He completed his PhD jointly at KIAST, South Korea, and Quaid-i-Azam University, Pakistan. Dr Akhter has held postdoctoral positions at KAIST and UNIST, South Korea, and previously served as Assistant and Associate Professor at UMT, Pakistan. His research focuses on synthesizing and characterizing innovative materials for diverse applications.


1. Introduction

Crosslinked networks that have the capacity to absorb a suitable solvent and thereby transform them from a deswelling state to a swelling state are called gels.1 If the swelling/deswelling behavior occurs in an aqueous medium, the gel is called a hydrogel.2,3 Further, gels falling in the three-dimensional micro-range diameter are termed microgels4,5 and have emerged as a focal point of research interest over the past decade owing to their versatile applications.6–8 Furthermore, microgels that show deswelling and swelling behaviors under external stimuli are termed smart microgels (SMGs).9–11 This stimuli-responsive behavior of microgels creates a potential in their structure, which is essential for various applications in catalysis,12–14 adsorption,15,16 biomedicine,17–19 and nanotechnology.20–22 These applications are greatly affected by the rapid response of smart microgels to external stimuli, such as the ionic strength,23,24 temperature,25–27 and pH28,29 of the medium, through their swelling/deswelling behavior. Moreover, extensive research has been conducted on microgels as micro-reactors, focusing on their ability to fabricate and stabilize inorganic particles (IPs).30–32 These inorganic particles such as metal oxides, including SiO2 and Fe2O3; metal sulfides; and metal nanoparticle-containing microgels are called hybrid microgels (HMGs). Among these hybrid microgels, metal nanoparticle (MNP)-containing microgels are an important type due to the easy identification, high catalytic performance, very small size, and large surface area of the metal nanoparticles in the microgels.

MNPs have various applications in different fields,33–36 but their poor stability limits their long-term usage. To address this limitation, different types of stabilizers have been reported in the literature, such as microgels,37 dendrimers,38 block polymers,39 and surfactants.40 Among these, microgels have demonstrated significant potential in maintaining the stability of MNPs over prolonged periods41–43 in addition to enhancing their performance.44,45 Consequently, they are suitable candidates for the production and stabilization of MNPs. In this review article, hybrid microgels represent microgels incorporated with MNPs. Hybrid microgels are very important with respect to their superior catalytic activity.46 These systems have the properties of both the metal nanoparticles and crosslinked polymer microgels. As they possess the properties of both components, hybrid microgels can be used for various applications, including drug delivery,47 anticancer,48 antibacterial,49 adsorption,50 sensing,33 and catalysis.51

A lot of research work has been done on these hybrid systems. As part of this, some researchers have published some reviews on single-metal-nanoparticles-loaded microgels,52–55 but to the best of our knowledge, no review article has yet provided all the information on all types of metal nanoparticles-loaded microgel systems that have been developed in the last decade. Therefore, this review article is very important to new researchers because it provides all the information related to metal nanoparticles-decorated microgel systems.

2. Classifications

Metal nanoparticles embedded within microgels are categorized into different classes based on (i) the nature of the metal nanoparticles present in the microgels, and (ii) the morphologies of the hybrid microgels. Further information related to these classifications is given below.

2.1. Types of metal nanoparticles in smart microgels

On the basis of the metal nanoparticles incorporated in the system, the hybrid microgels can be classified into two classes as: (i) noble metal nanoparticles integrated into microgels (ii) non-noble metal nanoparticles integrated into microgels. These two classes of metal nanoparticles have a significant influence on the applications of hybrid systems. We discuss these classes below.
2.1.1. Noble metal nanoparticles integrated into microgels. Based on the Scopus database, it appears that there has been more work on noble metal nanoparticles integrated into microgels than non-noble metal nanoparticles integrated into microgels, likely due to the higher performance of noble metal nanoparticles than non-noble metal nanoparticles. Regarding noble metal nanoparticles, Ag and Au nanoparticles-containing hybrid systems have been frequently reported in the literature, while there are less reports on other noble metal nanoparticles-containing hybrid systems. The reason for the frequent reports on these two noble metal nanoparticles is their interesting surface plasmon resonance property. Due to this property, the identification of these two metal nanoparticles can easily be achieved and they can be monitored using a spectrophotometer. Their surface plasmon resonance wavelengths (λSPR) also provide information related to the shape and size of the particles; where the λSPR value for Ag nanoparticles occurs at approximately at 430 nm (ref. 56) and for Au nanoparticles it is approximately at 520 nm.57 If a hybrid microgel shows a single peak in its UV-Vis spectrum, then spherical nanoparticles are present; while if two peaks appear in the spectrum, then the shape of the nanoparticles is rod-like. For example, Arif et al.43 synthesized Au nanoparticles-based core–shell hybrid microgels. They obtained a single peak for λSPR at 521 nm, which indicated the presence of spherical-shaped Au nanoparticles. For clarification of this point, they also performed TEM analysis, which confirmed that the Au nanoparticles in the core–shell systems were spherical in shape. Similarly, Naseem et al.58 also synthesized Ag nanoparticles-based core–shell hybrid microgels and investigated their optical properties. They observed a single peak for λSPR at 440 nm, which together with the TEM results, indicated that the Ag nanoparticles were spherical in shape.

Noble metal nanoparticles-containing hybrid systems have frequently been used as catalysts due to their high catalytic activity,59–61 which is due to their small size, high surface area, and easily oxidizing ability. Their catalytic activity can also be tuned under various stimuli conditions.56 These conditions affect the swelling and deswelling behavior of the hybrid microgels. In the swelling state, reactant molecules can easily reach the surfaces of the nanoparticles, which are the actual catalytic materials in the hybrid microgels. Therefore, reduction or degradation or transformation reactions occur rapidly. Conversely, the reactant diffusion rate decreases in the deswelling state, and therefore less reactant molecules reach the surface of nanoparticles, which is why the reaction rate decreases. The factors that can tune this catalytic performance are the temperature,62 pH,63 and ionic strength.64

These hybrid systems are also used as adsorbent for pollutants.65–67 The adsorption capacity of these hybrid systems depends on the nature of the polymer components. Specifically, the nature of the monomers and comonomers determines their selectivity for the adsorption of pollutants. This selectivity can be tuned by the pH of the medium for acidic and basic hybrid microgels. In a low pH medium, acidic hybrid microgels are present in protonated forms and are deprotonated at high pH values. In the deprotonated form, negative charge is present in the structure of the hybrid microgels. Therefore, hybrid microgels can attract positively charged pollutants but remove anionic pollutants via electron static interactions and repulsions, respectively. Similarly, basic hybrid microgels can also be produced selectivity for the adsorption of pollutants by varying the pH value of the medium.

Hybrid microgels are also used for drug delivery.47 This behavior also depends on the swelling and deswelling behavior of the crosslinked networks of microgels.21 Typically, the drug is loaded into the hybrid microgels in their swelling state and released by transforming them into their deswelling state. During this conversion, the loaded drug comes out along with water molecules. This conversion is done on the basis of the stimuli conditions. Au-based hybrid microgels are the best in this regard due to the ability of Au nanoparticles to convert light into heat. This property facilitates the release of the loaded drug from hybrid systems.68 For Au-based hybrid microgels, an anticancer drug could be loaded into the system and injected into the body. When the drug-loaded hybrid microgels reach the target place, then laser light is applied to this drug-loaded hybrid system. The Au nanoparticles absorb the laser light and convert it into heat. Due to this conversion, the temperature of the medium rises and the hybrid microgels transform from the swelling state to the deswelling state and release the loaded drug. In this way, no surgery is required for the patent and the maximum release of the loaded drug occurs at the target place only. Au-based hybrid microgels are mostly the ones used for anticancer treatment.

Typically, such hybrid systems also have efficient antibacterial activity.69,70 Therefore, these hybrid systems are used for different biological fields. This property generally depends on the nature of the metal nanoparticles. These nanoparticles can kill bacteria to control certain diseases. The efficiency of such hybrid systems can be controlled by controlling the release or approach of bacteria to the surface of the noble metal nanoparticles.

These hybrid microgels can also be used as sensors for the identification of different pollutants in water.71–73 During the sensing process, the oxidation state of the metal nanoparticles varies, or complexation takes place with the crosslinked network of the hybrid microgels. For example, Au-based hybrid microgels have been used for sensing albumin, mercuric ions, glucose levels, and some others. Similarly, other noble metal nanoparticles-based hybrid microgels can also be used for sensing different types of pollutants.

Noble metal nanoparticles-based hybrid systems are the most effective systems compared to the others due to their high performance and high stability. However, one limitation may be the cost effect of noble metal nanoparticles-based hybrid microgels. This issue can be resolved by using bimetallic nanoparticles-based hybrid systems. In these systems, cheaper metal nanoparticles are mixed with noble metal nanoparticles to reduce the cost. Another limitation is that the identification of noble metal nanoparticles (except Ag and Au) in microgels cannot be done with simple characterization techniques, such as FTIR, UV-Visible spectrophotometry, and their confirmation instead requires more costly instruments and techniques, such as TEM and HR-TEM. This issue can also be resolved by using bimetallic systems, in which Au or Ag nanoparticles are just one component. These systems have been reported for the transformation of some reactants, while others can also be converted into other suitable molecules by these hybrid systems. There are very limited adsorption studies on these systems reported in the literature, and more research work will be needed on these systems in the near future.

2.1.2. Non-noble metal nanoparticles integrated into microgels. Besides noble metals, there are other transition metal nanoparticles-based hybrid microgels, which are called non-noble metal nanoparticles. These types of hybrids contain cheaper metal nanoparticles, where the price of these metals is very low. However, the stability of these metal nanoparticles is also typically very low. There is less research work on non-noble metal nanoparticles-based hybrid microgels than noble metal nanoparticles due to their poor performance and low stability.74,75 The most study has been done on Fe and Cu nanoparticles-based hybrid microgels compared to other non-noble metals.

These metal nanoparticles do not show λSPR values in UV-Visible spectrophotometry because they do not have surface plasmon resonance frequency. Therefore, the presence of these metal nanoparticles cannot be confirmed by simple instruments.

Also, while these systems show good catalytic performance, their efficiency is low compared to noble metal nanoparticles due to their high surface area, low oxidizing property, and large particles sizes.43,50 Further, the catalytic performance of these hybrid microgels can also be tuned under different stimuli conditions similar to noble metal nanoparticles-based hybrid microgels. However, their catalytic performance rapidly decreases with increasing the storage time of hybrid microgels after synthesis, but can be increased from days to weeks with the help of the crosslinked networks of microgels, though even then their stability is still less than that of noble metal nanoparticles-based hybrid microgels. Further, coagulation can occur in metal nanoparticles, which decreases the surface area of the metal nanoparticles of hybrid microgels.

These hybrid microgels can be used for the adsorption of pollutants, but their adsorption capacity is less than that of microgels.76,77 Basically, the adsorption capacity depends on the empty space present in the crosslinked network of the microgels. This space decreases after the incorporation of metal nanoparticles, and therefore, the adsorption capacity decreases.

Non-noble metal nanoparticles do not have the ability to convert light into heat, as Au nanoparticles have. Therefore, they are less applicable for drug delivery, but their tuning behavior still makes these hybrid microgels suitable for certain drug delivery.78 The coagulation of metal nanoparticles is the main drawback for this application due to it reducing the empty space. These hybrid microgels can also be used for antibacterial activity. This property of these hybrid microgels is helpful for treatment against different diseases.

Less research work has been done on these hybrid microgels with respect to drug delivery, antibacterial applications, and the adsorption of pollutants. Therefore, more research work is needed to gain more information on these, such as research work on the stability of these metal nanoparticles. This further work could help to overcome their current drawbacks. Also, as their performance can be controlled by controlling the size of the particles, if such conditions could be obtained, then these systems may be a superior option to noble metal nanoparticles-based hybrid systems due to their lower cost and higher surface area. Further, their performance can be enhanced by using bimetallic nanoparticles-based hybrid microgels, as reported in our previous review article.79

2.2. Morphology-based classifications of hybrid microgels

Various designs of hybrid microgels have been reported in the literature, and hybrid microgels can be classified into various classes based on their morphology, as given below.
2.2.1. Core–shell hybrid microgels. Much current research is focused on core–shell hybrid microgels. These can be further categorized into sub-classes based on the species and their positions within the structure of the hybrid microgels.
2.2.1.1. Metal nanoparticles encapsulated by polymer microgels. In such categories, metal nanoparticles (MNPs) are present at the center (core), surrounded by polymer microgels (shell), as shown in Fig. 1(a). These core–shell hybrid microgels (HMGs) typically exhibit low catalytic activity. The diffusion rate of the reactant molecules from the outer region to the surface of MNPs through the crosslinked polymeric network is notably slow due to the long distance between them. Therefore, the approach of reactant molecules takes more time.75,80 Consequently, the catalytic efficiency of these HMGs is very low compared to other classes of HMGs. However, the stability of MNPs is greater in these systems, and the leaching of metal nanoparticles is not possible in these systems during their recovery by centrifugation after their catalytic application. Such systems can also be used for drug delivery due to the polymeric network. Polymeric networks have polar functional groups in their structure, and these polar components interact with the water molecules as well as the drug. If the interaction between the drug and the HMG is strong, then more drug can be loaded in these systems. Conversely, these systems are highly advantageous for drug-delivery purposes due to their high drug-loading capacity. Similarly, these systems show adsorption properties for various pollutants due to interactions between the crosslinked network and certain pollutants. They can be further categorized into two classes based on the use of (i) monometallic nanoparticles81 or (ii) bimetallic nanoparticles.82 Bimetallic nanoparticles-based HMGs show greater performance than monometallic systems due to the synergistic effects the bimetallic components.
image file: d4ra04128c-f1.tif
Fig. 1 Morphological classifications of hybrid microgels (metal nanoparticles are represented by red color; inorganic materials by black color; and organic polymers by green, blue and yellow colors). (a) Metal nanoparticle-encapsulated polymer microgels, (b) organic polymer-encapsulated MNPs decorated with crosslinked polymers, (c) inorganic-encapsulated MNPs decorated with polymer microgels, (d) organic polymer-encapsulated bimetallic NPs decorated with polymer microgels, (e) MNP-decorated organic polymer encapsulated in another organic polymer, (f) organic polymer-encapsulated MNP layer encapsulated in another organic polymer, (g) organic polymer-encapsulated metal nanoparticles, (h) MNPs in hollow microspheres and (i) homogenous hybrid microgels.

Only gold (Au)44,83 and silver (Ag)84 nanoparticles encapsulated in microgels have been reported for monometallic nanoparticles encapsulated within microgels. Additionally, Au,80 Ag,75 and Co/Ni85 have also been reported as bimetallic nanoparticles within microgels, exhibiting identical morphologies. To date, both variants of these categories have been utilized solely for their catalytic activity, and their potential for applications in drug delivery and other biological aspects have not yet been reported in the literature. Moreover, they can be utilized as adsorbents for various pollutants found in water and the environment. These classes and potential application represent viable opportunities for further research on these types of hybrids.


2.2.1.2. Organic polymer-encapsulated MNPs decorated by crosslinked polymers. In these categories, an organic core is encased within another crosslinked polymer shell and the metal nanoparticles are located in the shell region of the core–shell microgels, as shown in Fig. 1(b). Organic polymer-encapsulated MNPs decorated by crosslinked polymer systems have greater significance than MNPs-encapsulated microgel systems due to their superior catalytic activity86,87 and greater density of HMGs. Actually, the distance between the reactant molecules and the surface of metal nanoparticles is minimized in the former scenario compared to in the lateral HMGs. However, the lateral systems tend to exhibit a higher drug-loading capacity than the former systems due to the occupation of the space by the metal nanoparticles, resulting in a low empty space for drugs in the former HMG systems. The catalytic efficiency and drug-loading capacity of both types of systems can be enhanced by altering the environment of the medium. The crosslinked network of HMGs can transform from a deswelling state to a swelling state with the aid of stimuli. Additionally, the easy recyclability (due to greater density) of these systems is another advantage. These systems can be further classified into two categories based on the incorporation of (i) monometallic nanoparticles88 or (ii) bimetallic nanoparticles89 in the core–shell microgels, as shown in Fig. 1(e). Bimetallic systems yield superior results for catalysis and surface-enhanced Raman scattering due to synergistic effects of the bimetallic components.

Monometallic (Au,43 Cu,50 Pd,86 Ni,90 Ag,91 and Pt92) nanoparticles-based core–shell hybrid microgels have been documented in the literature. Similarly, the incorporation of bimetallic nanoparticles (Pt,89 Au,93 Ag,94 and Pd95) within core–shell microgel systems has also been documented in the literature. Only Cu-based monometallic nanoparticles-based hybrid microgels of this class have been reported to date, while bimetallic systems of non-noble metal nanoparticles-based HMGs have not been reported yet. This thus represents an available space for further research work. These systems are commonly employed as catalysts, but their potential as adsorbents for various pollutants or in biological applications has not yet been reported. Additionally, the influence of the core on the leaching of metal nanoparticles in these hybrid systems has not been studied yet, presenting another area for further research.


2.2.1.3. Inorganic-encapsulated MNPs decorated by polymer microgels. In these classes, the core is composed of inorganic materials, like Fe2O3, SiO2, or Fe3O4, which is encapsulated with a metal nanoparticles-containing microgel shell, as shown in Fig. 1(c). These hybrid microgels in which a paramagnetic inorganic core is surrounded by metal nanoparticles within microgels have significant importance due to their enhanced recyclability compared to other systems. These HMGs can be efficiently recycled using magnetic fields96 or centrifugation processes.97 During this recycling (e.g., recycling by a magnetic field), the issue of the leaching of metal nanoparticles from the crosslinked network can be solved by these hybrid microgels. Additionally, they can serve as catalysts for various catalytic reactions. However, the stimuli-responsive behavior of such systems slightly is diminished compared to that of pure microgel systems due to the presence of solid inorganic species; whereby these solid species decrease the effects of pH, temperature, and ionic strength on these hybrid microgels due to the formation of an interface between the solid inorganic core and the crosslinked organic polymer microgels.9 Despite their significance, such systems have not been frequently documented in the literature. However, they can be used for drug delivery and the adsorption of pollutants, where their easy recyclable property makes these HMGs suitable for these applications. They can also be applicable for antibacterial applications. Further, these types of HMGs can be divided into a further two classes: (i) mono-inorganic material-encapsulated MNPs decorated by crosslinked polymers30 and (ii) bi-inorganic material-encapsulated MNPs decorated by crosslinked polymers.98 Bi-inorganic materials containing core–shell hybrid microgels are better than monometallic ones due to their high density, easy recyclable property, and the synergistic effect of the bi-inorganic components.

Mono-inorganic material-encapsulated MNPs-decorated crosslinked polymer systems have been reported with different noble metal nanoparticles-based hybrid systems, such as Au,96 Ni,30 Ag,97 and Pd,99 but not reported for non-metal nanoparticles-based hybrid microgels, while bi-inorganic material-encapsulated MNPs-decorated crosslinked polymer systems have been reported with monometallic Co100 nanoparticles only. Controlling the size of the core is the main issue in these types of hybrids. This issue can be controlled by adding a stabilizer along with the formation of crosslinked polymers. Hybrid microgels of these types are mostly applied for catalytic reactions, while the other environmental and biological fields seem to have no research performed yet. Furthermore, these hybrid microgels have not been synthesized with bimetallic nanoparticles, and so this may be a good option for further research. Further research efforts could thus be directed toward exploring and developing these types of hybrid microgels.


2.2.1.4. MNPs-decorated organic polymer encapsulated by another organic polymer. In systems of MNPs-decorated organic polymers encapsulated by another organic polymer, both the core and shell systems of the hybrid microgels consist of crosslinked organic polymers, and metal nanoparticles are present in the core region of these hybrid core–shell systems, as shown in Fig. 1(e). These types of HMGs are very effective for controlling the leaching of metal nanoparticles during the centrifugation recycling process. These hybrid microgels can be used for catalytic reactions, but their catalytic activity is lower than other classes. However, their catalytic efficiency can be tuned with the help of external stimuli conditions.13,101 These conditions control the swelling and deswelling behavior of the shell region, which can permit the entrance of reactant molecules. These reactant molecules reach the metal nanoparticles through the shell region. Therefore, their swelling behavior is very important for the catalytic efficiency of these types of core–shell systems. The shell region can also be used for the adsorption of other pollutants. In this way, these types of HMGs are excellent candidates for both adsorption as well as catalysis. They can also be employed for drug delivery and the loading and release of a drug can be controlled by the stimuli-responsive shell region. Also, if the nanoparticles are based on Au nanoparticles, then it is an excellent drug carrier system, because Au nanoparticles can control the deswelling behavior of the shell region by converting applied light into heat. Also, during this conversion, the shell region or core region transforms from a swelling to deswelling state. If the drug is loaded in the core region, then the deswelling of the shell region controls the release of the drug, and if the drug is present in the shell region, then it comes out along with the water molecules during this transformation. The antibacterial activity of these hybrid microgels is lower than in previous classes due to their low diffusion rate and possible leaching of metal nanoparticles.

Systems of MNPs-decorated polymers encapsulated by another organic polymer have been documented with only Pd13 and Au102 nanoparticles, and bimetallic nanoparticle-based hybrid systems of this class have not been reported yet. Furthermore, these hybrid microgels along with non-metal nanoparticles have also not been reported in the literature yet. Hence, there is a need for further research in these categories, as they are excellent candidates with cores for controlling the drug loading/release, catalytic reactions, and adsorption of pollutants. Additionally, there is available research space for exploring the synthesis of these kinds of hybrid microgels with other noble and non-noble metals with monometallic and bimetallic systems.


2.2.1.5. Organic polymer-encapsulated MNPs layer encapsulated by another organic polymer. In systems with an organic polymer-encapsulated MNPs layer encapsulated by another organic polymer, a core–layer–shell system of hybrid microgels are formed in which both the core and shell regions contain organic polymers and metal nanoparticles are present in-between these core and shell regions in the form of a layer, as shown in Fig. 1(f). This class of hybrid microgels has greater catalytic efficiency than MNPs-encapsulated crosslinked polymer systems and MNPs-decorated organic polymers encapsulated by another crosslinked organic polymer systems, but less than other classes of hybrid microgels due to the approaches of the reactant molecules to the MNPs' surface. Their catalytic activity can also be tuned by the stimuli conditions. The leaking capacity of MNPs in these hybrid microgels is minimum during recycling, which is performed by a centrifugation process. The adsorption capacity of these hybrid systems is high due to the direct contact of pollutants with the crosslinked networks. The adsorption capacity of these hybrid microgels depends on the nature of the adsorbate and the nature of monomers and comonomers in the structure of hybrid microgels, because the strength of interactions between pollutants and the hybrid microgels depends on the nature of both the pollutants and hybrid microgels. They are also applied for drug delivery, similar to the adsorption of pollutants. The loaded drug can be released during the conversion from the swelling state of the hybrid microgels to the deswelling state. This drug release can be controlled by altering the interaction strength between the drug and hybrid microgels via the stimuli conditions.103

Very limited research work has been done on systems involving an organic polymer-encapsulated MNPs layer encapsulated by another organic polymer. Only Au nanoparticles-based hybrid microgels are detailed in the literature.104 There is thus an opportunity for further research to explore the synthesis of these types of hybrid systems with both types of metal (noble and non-noble) nanoparticles. Thus investigation into the adsorption, drug loading/release, and catalytic activity of these hybrid systems offers new ground for research.


2.2.1.6. Organic polymer-encapsulated metal nanoparticles. In organic polymer-encapsulated metal nanoparticles, the crosslinked network of the organic polymer is surrounded by metal nanoparticles, as shown in Fig. 1(g). These types of hybrid microgels are synthesized through electrostatic interactions between the microgel and metal nanoparticles.71,105 The degree of coverage of the microgel surface with the metal nanoparticles depends on various factors, such as the charge density of the microgels, the crosslinking density, the polarity of the structure, and the porosity of the microgels. Modulating the concentration of ionic radical initiators or content of crosslinkers or content of charged comonomers during the polymerization process can facilitate the design of microgels with a high adsorption capacity of metal nanoparticles at their surface. Organic polymer-encapsulated metal nanoparticles exhibit the highest efficiency in catalytic reactions than other hybrid microgels due to the easy access of the reactant molecules to the metal nanoparticle surface. However, their catalytic efficiency rapidly diminishes during the recycling process, due to the detachment of metal nanoparticles from the surface of the microgels. After recycling, the content of metal nanoparticles on the surface of microgels decreases. Therefore, their catalytic activity decreases sharply after recycling. Moreover, these types of hybrids are not ideally suited to drug delivery due to the decrease in drug loading caused by the coverage of metal nanoparticles. Nonetheless, a few studies on drug delivery using such systems have been published.106 Karg et al.107 reported a coating of P(NIPAM) microgels with gold nanorods. The resulting core–shell hybrid systems were obtained through electrostatic interactions between the gold nanorods and the microgels. Surface modification of both the gold nanorods and the microgels was necessary to induce these interactions, which could be conveniently achieved by increasing the concentration of free radical initiators or incorporating charged comonomers. Similarly, the gold nanorods needed to carry an opposite charge to the surface functionalities of the microgels. This was accomplished through the introduction of a polyelectrolyte bilayer to enhance the colloidal stability and create a positive charge on their surface. Mixing positively charged gold nanoparticles with negatively charged microgels resulted in the formation of core–shell hybrid microgels. Wong et al.108 reported the synthesis of P(NIPAM) microgels modified with magnetic nanoparticles. These were obtained by surface modification of the microgels to enable the adsorption of magnetic nanoparticles via electrostatic interaction. In a study by Karg et al.,109 it was demonstrated that copolymer microgels with charged surfaces could be efficiently coated with gold nanorods, leading to significant surface coverage. These charged microgels consisted of the poly(N-isopropyl acrylamide-allyl acetic acid) (P(NIPAM-AAAc)) system. A negative charge was created on the surface of these microgels at specific pH levels (in basic medium) due to the conversion of COOH groups into COO ions. This creation of charge established a strong electrostatic interaction between the surface-modified gold nanorods and anionic microgel surface. These hybrid microgels exhibited remarkable optical properties that were also responsive to external stimuli. The antibacterial activity of these hybrid microgels was also high due to the direct contact of bacteria with the metal nanoparticles.

Organic polymer-encapsulated monometallic (Pd,71 Cu,110 Au,111 and Ag105) nanoparticles and bimetallic (Au,112 and Pd95) systems have been documented in the literature. However, few articles are available on systems involving organic polymers encapsulated with bimetallic nanoparticles. The catalytic efficiency of organic polymer-encapsulated bimetallic nanoparticles is the highest among all other systems of hybrid microgels. After these systems, organic polymer-encapsulated monometallic nanoparticles are ranked in second place with respect to their catalytic performance. The catalytic activity and recycling properties of such systems thus warrant further investigation in the near future. The leakage and coagulation of metal nanoparticles is the main issue of these hybrid microgels. More study is needed on controlling the size of the metal nanoparticles as well as their application in adsorption and drug delivery.

2.2.2. MNPs in hollow microspheres. In systems comprising MNPs in hollow microspheres, the hollow microsphere is made with an organic crosslinked polymer and metal nanoparticles are present in these hollow microgels, as shown in Fig. 1(h). The hollow microsphere is formed by removing the core from core–shell polymer microgel systems. MNPs are then introduced into these hollow microspheres to form hollow microsphere hybrid systems.113 The catalytic activity of these hybrid systems is greater than that of the previously discussed hybrid microgels. In these hybrid systems, pollutants can easily diffuse into the hybrid systems from both the interior and exterior sides. Therefore, there is a rapid diffusion rate. Consequently, the pollutants can rapidly reach the surface of the MNPs. The leaching of metal nanoparticles is the main issue with these types of hybrids. This issue can be resolved by using some paramagnetic nanoparticles along with MNPs in the hybrid systems. After the introduction of these (paramagnetic) nanoparticles, the MNPs in hollow microsphere can easily be recycled by using a magnetic field. These types of hybrids have high efficiency for the adsorption of pollutants. Therefore, MNPs in hollow microspheres are excellent for the adsorption of pollutants. Moreover, the hollow sphere hybrid microgels exhibit superior swelling/deswelling capacities compared to other core–shell hybrid microgels, making them effective for the loading and release of drugs from both the outer surface and the inner sides. Li et al.114 described the synthesis of temperature-dependent hollow microspheres. They synthesized core–shell microgels with a poly(methylmethacrylic acid) (P(MMAAc)) core and a varying thickness shell based on P(NIPAM) at first. The P(MMAAc)-based core could be selectively removed from this core–shell system by a simple continuous stirring due to the high solubility of the core in the medium. He et al.113 prepared hollow hybrid gold-based nanospheres by synthesizing a silica core and then introducing a shell composed of poly(2-(1-methylimidazolium 3-ethyl)-ethylmethacrylate chloride) (P(MIEEMACh)) first, followed by the production of gold nanoparticles by an in situ reduction. After that, the silica core was removed from the hybrid core–shell system by treatment with hydrofluoric acid. The resulting hollow hybrid temperature-dependent microspheres exhibited efficient catalytic efficiency toward the reductive reaction of 4NiP.

Hollow hybrid microspheres have been documented only with Au-113 or Ag114-based hybrid microgels, and no work on non-noble metal nanoparticles in hollow microspheres has been reported in the literature. Therefore, further research could explore the utilization of other metal (both noble and non-noble) nanoparticles in these systems and their applications, such as in catalysis, drug delivery, and for the adsorption of various pollutants from water. Additionally, investigating the potential leaching of metal nanoparticles in such hybrid microgels is an area for future study. A comparison study of these hollow hybrid microgels would also be warranted comparing among themselves and with other core–shell hybrid systems.

2.2.3. Homogenous hybrid microgels. In homogenous hybrid microgels, metal nanoparticles are uniformly located within the meshes of the crosslinked polymer network of the microgels, as shown in Fig. 1(i). Homogenous hybrid microgels have been extensively documented in the literature.61,115–121 These hybrid systems can serve as catalysts for various catalytic reactions. The synthetic approach of these hybrid microgels is easy compared to other hybrid microgels, like hollow microspheres, microgel-encapsulated metal nanoparticles, and all types of core–shell hybrid microgels. Consequently, numerous studies have been reported on these classes of hybrid microgels. These hybrid microgels systems may also be applicable in drug delivery,47,120,122 water pollutant adsorption,123 sensing,33 and antibacterial applications.70,124,125 For instance, Zhang et al.126 synthesized Ag NPs decorated by poly(N-isopropylacrylamide-maleate carboxymethylchitosan) (P(NIPAM-MCMCS)) microgels, and reported achieving a uniform dispersion of Ag NPs in the microgels. They used these hybrid systems for the catalytic reduction of nitroarenes. Liu et al.127 synthesized a crosslinked structure of P(NIPAM) microgels by interpenetrating linear poly(acrylic acid) (P(AAc)) within them. The Ag nanoparticles were uniformly introduced into the crosslinked microgel network via an in situ reduction method. Additionally, Zhou et al.128 reported the synthesis of Au-based hybrid microgel systems. They synthesized different samples with varying sizes of gold nanoparticles within the microgels by employing different concentrations of gold salts. These hybrid systems were then applied for the catalytic reduction of nitroarenes in aqueous media, with the reduction process observed to follow a pseudo-first-order kinetics.

Monometallic hybrid systems based on Au,57 Co,129 Pt,130 Ni,131 Ag,59 Cu,132 Rh,133 Pd,121 Fe,134 and Ru135 have been documented in the literature. Additionally, bimetallic systems incorporating Ag,74 Fe,136 Au,137 Ni,138 Pd,13 Cu,139 Pt,140 and Co141 nanoparticles have also been reported. These systems find extensive applications in catalysis, drug delivery, cancer treatment, adsorption, and antibacterial applications. Typically, the monomers and comonomers used in these hybrid systems are non-biodegradable. Hence, researchers can now focus on the further exploration of these systems by incorporating biodegradable monomers. Addressing the leaching of metal nanoparticles from these hybrid microgels is also an important area of research.

3. Synthesis

Several methods have been documented in the literature for the preparation of metal nanoparticles in microgels.32,96,142–144 Specific synthetic methods may be applied based on the desired particular architecture, design, and morphology of the hybrid microgels. These synthetic approaches are outlined in Fig. 2(A)–(C).
image file: d4ra04128c-f2.tif
Fig. 2 Synthesis of hybrid microgels. (A) Synthesis of metal nanoparticles in a microgel dispersion, (B) synthesis of microgels in a solution of metal nanoparticles, and (C) hybrid microgel formation by simultaneously mixing microgels and metal nanoparticles.

3.1. Synthesis of metal nanoparticles in a microgel dispersion

A method commonly employed to synthesize metal nanoparticles in microgels is via the insertion of metal ions into the crosslinked network of microgels, followed by an in situ reduction these ions into their atomic forms, as shown in Fig. 2(A).56,124,145–151 These atoms then start to coagulate up to the nano-range. The coagulation of metal atoms is controlled by the crosslinked network of the microgels. Control of the size distribution and dimensions of the metal nanoparticles can be achieved by adjusting the uniformity and pore size of the polymer network, whereby the size of the particles is controlled by the crosslinking density. If the crosslinking density of microgels is high, then small-sized metal nanoparticles are formed due to the low available space. While if the crosslinking density is low, then large sized particles are formed due to large available spaces in the structure of the microgels. In this approach, the structure of the microgels acts as a micro-reactor for nanoparticle synthesis. Whereby, the synthesized hybrid microgels can obtain a uniform distribution of metal nanoparticles throughout the structure. The content of monomers and comonomers are also controlled the size of MNPs. In this way, the composition of the microgels controls the incorporation of the metal content within their pores.

Shah et al.152 applied this methodology to produce Au nanoparticles within poly(N-isopropyl acrylamide-acrylic acid) P(NIPAM-AAc) microgels. The size and size distribution of the Au NPs were influenced by the ratio of AAc to NIPAM in the P(NIPAM-AAc) microgel composition. Additionally, they observed that the size of the Au nanoparticles could be manipulated by varying the stimuli conditions during synthesis. Furthermore, another study98 reported on the synthesis of silver nanoparticles within poly(N-isopropylacrylamide-arylamide-methacrylic acid) P(NIPAM-AAm-MAAc) microgels. The synthesis involved two steps. In the first step, P(NIPAM-AAm-MAAc) microgels were synthesized by a free radical precipitation polymerization method. In this step, NIPAM (monomer), AAm (comonmer), MAAc (comonmer), N,N-methylenebis(acrylamide) (NMBA) (crosslinker), and sodium dodecyl sulfate (SDS) (stabilizer) were mixed and heated at 70 °C under nitrogen with vigorous stirring. After 30 min, ammonium persulfate (APS) (free radical initiator) solution was added and the reaction was continued for another 5 h under similar conditions. Silver salt solution was poured into the dispersion medium of P(NIPAM-AAm-MAAc). In the second step, these incorporated silver ions were subsequently transformed into silver nanoparticles via an in situ reduction method utilizing NaBH4 as the reductant.

This method is simple and easy. It can be used for the synthesis of uniformly distributed MNPs in microgels. The size and distribution of the MNPs can be perfectly controlled by this method. Both monometallic (such as Au,43 Ni,153 Pt,130 Co,123 Ag,119 Cu,154 Pd,155 Rh,133 Fe,156 Ru135) and bimetallic (including Pd,139 Ni,76 Pt,89 Co,157 Ag,94 Cu,158 Au82) hybrid microgels have been synthesized using similar approaches, as documented in the literature. The drawback of this approach is that core–shell hybrid microgels are not prepared.

3.2. Synthesis of microgels in a solution of metal nanoparticles

In this synthetic approach, a core–shell hybrid microgel system is formed, in which the core consists of metal nanoparticles and the shell of crosslinked organic polymers. This synthesis also proceeds via two steps. In the first step, metal nanoparticles are synthesized and stabilized using a stabilizer. In the second step, these synthesized metal nanoparticles are then used as seeds for the synthesis of the microgels, as shown in Fig. 2(B).159–162 The surface of the metal nanoparticles can also be modified to produce polarity on the surface of the metal nanoparticles. This modified surface facilitates size control of the MNPs and the formation of microgels around these nanoparticles. The polymerization process occurs within a dispersion of metal nanoparticles, utilizing appropriate monomers, surfactants, initiators, comonomers, and crosslinkers under specific conditions. Li et al.82 developed core–shell hybrid microgels with a bimetallic core and a shell based on N-isopropylacrylamide (NIPAM) using a slightly modified seed emulsion polymerization method. They applied silver nanoparticles stabilized with sodium citrate as seeds. The surface of the synthesized Ag nanoparticles was modified with NIPAM. Subsequently, Ag@poly(N-isopropylacrylamide-3-methacryloxypropyltrimethoxysilane) (Ag@P(NIPAM-MAPTMSi)) hybrid microgels were obtained by adding an aqueous solution of ammonium persulfate and 3-methacryloxypropyltrimethoxysilane. Furthermore, Ag-Au@P(NIPr-MAPTMSi) hybrid microgels were synthesized through a galvanic reaction (GRe) by utilizing the Ag-based hybrid system as a sacrificial template in an aqueous medium in the presence of aqueous ammonia. The by-product (AgCl) was removed from the reaction mixture using ammonia. Similarly, Bandyopadhyay et al.144 employed a comparable approach to fabricate Au@P(NIPAM-AAc) hybrid microgels with a core–shell morphology, in which the core was composed of Au and the shell was made of P(NIPAM-AAc). They used polyethylene glycol P(EGl) to modify different morphologies of Au nanoparticles, which served as core particles for the copolymerization of NIPAM and acrylic acid (AAc), resulting in the formation of hybrid microgels.

This system is applicable for the synthesis of core–shell hybrid microgels only but not for homogenous hybrid microgels. More control of the performance and time are required in this method. This synthetic approach also has a drawback related to the size control of the metal nanoparticles, which is critical as the size of MNPs is the most important parameter for many their applications. Therefore, this method is less commonly used than the previously discussed methods. Monometallic (such as Au,144 Ag100) hybrid microgels and bimetallic (Ag, Co, Ni, and Au27) hybrid systems are synthesized using similar approaches. Other hybrid systems based on metal nanoparticles (both monometallic and bimetallic) can be synthesized using this method.

3.3. Hybrid microgel formation by simultaneously mixing microgels and metal nanoparticles

In the third method, both microgels and metal nanoparticles are synthesized separately and are later combined to generate hybrid microgels, as shown in Fig. 2(C). Before the formation of hybrid microgels, the surface of MNPs must be modified to create polarity. These hybrid microgels are then synthesized through electrostatic interactions. The hydrophilic components of the microgels interact electrostatically with the metal nanoparticles.33,163–168 This interaction facilitates the fabrication of the microgels system with the metal nanoparticles. During this fabrication, MNPs come into or onto the crosslinked network of the microgels. If the size of metal nanoparticles is greater than the sieves of the microgels, then they attach on the surface of the microgels to form hybrid systems; whereas if the size of the MNPs is slammer than the sieve area, then they fall into the crosslinked network. Liu et al.96 described the formation of gold nanoparticles-based core–shell hybrid microgels through simultaneously mixing their solutions. They synthesized core–shell microgels with a core of Fe3O4 and a shell of a crosslinked network of P(NIPAM-DMAEMA). First, gold nanoparticles were synthesized, stabilized, and functionalized with trisodium citrate. Next, the separately synthesized and functionalized gold nanoparticles were loaded into the shell region of the core–shell system through the aid of the electrostatic attractions between the functionalized Au nanoparticles and the polar network of the microgels. Similarly, Gu et al.165 achieved a hybrid system by mixing a dispersion of microgels with gold nanoparticles. Mutharani et al.71 reported a similar method for synthesizing hybrid systems consisting of microgels covered with palladium nanoparticles. The P(NIPAM)-CS microgel system was synthesized first. For this, a solution of CS along with a small amount of acetic acid and deionized water (DW) was prepared in a beaker and stirred for 24 h. The mixture was then transferred to a flask and stirred (25 min) under N2. The mixture was further stirred for 30 min in the presence of NIPAM at room temperature (26 °C) and then the temperature was raised to 70 °C. A small amount of APS solution was added to the reaction mixture for polymerization. Meanwhile, the Pd nanoparticles were synthesized in a separate beaker. Here, PdCl2, trisodium citrate, and DW were added to a beaker and stirred. After 30 min, NaBH4 solution was added to the beaker to reduce the Pd2+ ions.

This approach, however, is also not ideal for controlling the size of the nanoparticles and results in a wastage of nanoparticles in the medium. This method is applicable for core–shell (in which microgels are present as the core and metal nanoparticles as the shell) and homogenous hybrid microgels. Core–shell hybrid systems in which metal nanoparticles are present as the core and microgels as the shell cannot be synthesized by this method. Monometallic (Ag,169 Cu,164 Pd,71 Au96)-based hybrid systems have been synthesized using this method. Bimetallic (Pd,167 Ag,112 and Au170) nanoparticles-based hybrid microgels have also been reported using this approach. This method can also be used to synthesize bimetallic and other metal nanoparticle-based hybrid microgels.

4. Characterization techniques

Various techniques can be utilized to examine the size, structure, composition, behavior, and appearance of metal nanoparticle-based hybrid microgels, as well as to distinguish them from their corresponding smart microgels, as shown in Fig. 3(A)–(F). These techniques include scanning electron microscopy (SEM), wide-angle X-ray scattering (WAXS), polarizing optical microscopy (POM), energy-dispersive X-ray spectroscopy (EDX), dynamic light scattering (DLS), attenuated total reflectance spectroscopy (ATR), 1H-nuclear magnetic resonance spectroscopy (NMR), laser light-scattering spectrometry (LLS), photoluminescence spectroscopy (PL), Raman spectroscopy (RS), UV-Visible spectrometry (UV-Vis), inductively coupled plasma mass spectrometry (ICP-MS), transmission electron microscopy (TEM), photo correlation spectroscopy (PSC), Fourier-transform infrared spectroscopy (FTIR), differential mechanical analysis (DMA), atomic force microscopy (AFM), inductively coupled plasma-optical emission spectrometry (ICP-OES), inductively coupled plasma atomic emission spectroscopy (ICP-AES), differential scanning calorimetry (DSC), and Brunauer–Emmett–Teller (BET) measurements.171 Each characterization technique can provide specific information about both hybrid microgels and their corresponding microgels.
image file: d4ra04128c-f3.tif
Fig. 3 Characterization techniques (A) FTIR, (B) DLS (reproduced from ref. 15 with permission from Elsevier, copyright 2023),15, (C) TEM (reproduced from ref. 91 with permission from Elsevier, copyright 2019),91, (D) XRD, (E) TGA (reproduced from ref. 151 with permission from Elsevier, copyright 2019),151 and (F) EDX (reproduced from ref. 15 with permission from Elsevier, copyright 2023).15

Advanced microscopic techniques, like AFM, TEM, FE-SEM,158 and SEM, can be employed to analyze microgel particles and their hybrids as well as their physical appearances. TEM can be used to investigate the size distribution, morphology, and size of both hybrid microgels and pure microgels, as shown in Fig. 3(C). It can provide information about the size and shape of polymer microgels and metal nanoparticles within the crosslinked polymer networks. SEM and AFM can be utilized to study the surface morphology of both metal nanoparticles and organic polymers.

FTIR (as shown in Fig. 3(A)), NMR,172 and RS techniques are widely employed to investigate the functionalities of the resultant organic polymers and to identify interactions within the polymeric networks of microgels and metal nanoparticles in the form of hybrid microgels. EDX and XRD techniques can be used to verify the presence and properties of the metal nanoparticles in the crosslinked networks. XRD can also be used to determine the crystalline nature of both systems, as shown in Fig. 3(D). WAXS,173 particle size analysis, and DLS (as shown in Fig. 3(B)) can be utilized to measure the diameter, size distribution, and size of particles. UV/Vis/NIR spectroscopy can be used to determine the volume phase transition temperature (VPTT) of both microgels and hybrid systems by measuring their turbidity. It can also be employed to confirm the stabilization and formation of plasmonic metal nanoparticles loaded in microgels. EDS can be used to find the elemental composites of the systems, as shown in Fig. 3(F).

TGA, DMA, and DSC174 techniques can be employed to examine the thermal stability and decomposition of both microgels and hybrid systems. TGA can also be utilized to determine the content of metal nanoparticles in microgels, as shown in Fig. 3(E).146 DLS/Photon correlation spectroscopy (PCS) can be applied to assess the size distribution and hydrodynamic sizes of microgels and hybrid microgels. WAXS can be employed to characterize the structure and consistency of the synthesized hydrogels, providing insights into the network topology, and ensuring reproducibility of the structures. Rheological measurements can be conducted to understand the viscoelastic properties of hydrogels.

Drug-release studies include evaluating the cytotoxicity of microgel and hybrid microgel systems using MTTS assays and quantifying the drug-release amount using the HP-LC31 technique. Confocal laser scanning microscopy (CLSM)175 can be utilized to monitor drug loading and release. ICP-OES,176 ICP-MS, and ICP-AES130 can be employed to determine the content of noble metal nanoparticles decorated by the microgels. Table 1 provides a summary of some microgels with metal nanoparticles, the characterization techniques used on them, and their applications.

Table 1 Hybrid microgels and their monomers, comonomers, metals, applications, and characterization techniques
System Metal nanoparticles Monomers Applications Characterization techniques References
Ag-P(MAc), Co-P(MAc) Ag, Co MAc Catalysis FTIR, TEM, XRD, TGA, UV-Vis, EDX 146
Au-P(NIPr-AAc) Au NIPr, AAc Colorimetric imaging DLS, XPS, SEM, UV-Vis 174
Ag-P(NIPr-AAc-HEAc) Ag HEAc, NIPr, AAc Drug delivery and biosensing TEM, UV-Vis, XRD 177
Au/Cu-P(AN) Au + Cu AN Catalysis UV-Vis, TGA, FTIR, XPS, FE-SEM, EDX 158
Cu-P(AAc) Cu AAc Catalysis UV-Vis, TEM, WAXD, IR 173
Cu-P(AMPSAc), Co-P(AMPSAc), Ni-P(AMPSAc) Cu, Co, Ni AMPSAc SEM, TEM, XRD, TGA, EDX 141
Pt-P(NIPr) Pt NIPr Catalysis TEM, ICP-AES, EDX, UV-Vis, DLS 130
Cu@Pd-P(NIPr-AAc) Cu + Pd AAc, NIPr Catalysis SEM, UV-Vis, XPS, XRD, FTIR, TEM, TGA 139
Cu-P(AAm-AAc) Cu AAm, AAc Antibacterial FTIR, UV-Vis, PS, SEM, XRD, DLS 178
Ag/Co-P(NIPMe) Co + Ag NIPMe Catalysis FTIR, XRD, UV-Vis, STEM, TGA 32
Ni-P(AAm-AAc) Ni AAm, AAc Catalysis XPS, FTIR, TGA, XRD, TEM 179
Mg/Pt-P(NIPr) Pt + Mg NIPr Drug delivery EDX, SEM, PL, CLSM 175
Ni-P(AAMPSA) Ni AAMPSA Catalysis TEM, ICP-AES, TGA 180
Au-P(NIPr-DMAEMA) Au DMAEMA, NIPr Sensing DLS, TEM, TGA, UV-Vis 72
Co-P(NipaM)/P(HemA) Co NIPAM, HEMA Catalysis TEM, 1H NMR, FTIR, SEM, EDS, UV-Vis 172
Co-P(EI) poly(ethylene imine) P(EI) Co EI Catalysis FTIR, SEM, DLS, TGA, zeta potential 181
Ni/Ag-P(NIPMe-MAAc) Ni + Ag NIPMe, MAAc Catalysis FTIR, EDX, TGA, DLS, STEM, UV-Vis 61
Fe@Pd-P(NIPr-MMAc) Fe + Pd NIPr, MMAc Catalysis EDXS, ED-XRD, ICP-OES, DLS, SEM, FIB-SEM 176
Rh-P(NIPMe-AAc) Rh NIPMe, AAc Catalysis UV-Vis, XRD, FTIR 133
Pd-P(NIA-AA) Pd NIA, AA Catalysis FTIR, FE-SSEM, XRD, AFM, ICP-AES 182
Fe/Pd-P(AAc) Fe + Pd AAc Catalysis BET, ATR-FTIR, FE-SEM, XPS, ICP-AES, EDS 171
Ag/Pt-P(VA), Pt/In-P(VA), Pd/Fe-P(VA), Cu/Pd-P(VA), Pt/Fe-P(VA), Pt/Pd-P(VA) Ag + Pt, Pt + In, Pd + Fe, Cu + Pd, Pt + Fe, Pt + Pd VA TEM, FTIR, SEM, UV-Vis, digital camera photography 140
sPd-P(NIA-MeAA) Pd NiA, MeAA Catalysis HP-LC, PCS, NMR, LC-MS 31


5. Sensitivity properties

Microgels with and without metal nanoparticles both can show prompt responses to alterations in certain stimuli conditions, including pH,183 ionic strength of a medium,184 temperature,185 and glucose level,84 as shown in Fig. 4(a)–(f). These stimuli trigger abrupt changes in the hydrodynamic radius of the systems. The physical chemistry of this responsive behavior of these hybrid systems is explored in the following sections.
image file: d4ra04128c-f4.tif
Fig. 4 Stimuli-responsive behaviors of hybrid microgels upon change in the (a) temperature, (b) pH of acidic hybrid microgels, (c) pH of basic hybrid microgels, (d) ionic strength of the medium, (e) laser light, and (f) glucose levels.

5.1. Temperature sensitivity

The change in hydrodynamic radius (HDR) of both microgels and hybrid microgels under different conditions of temperature is known as “temperature sensitivity”. The temperature sensitivity of both systems can be assessed by monitoring the HDR relative to temperature changes, as shown in Fig. 4(a). The value of HDR can either decrease or increase with rising temperature, depending on the specific temperature-sensitive components in the microgel structure. Based on the temperature-sensitive components in hybrid microgel systems, their sensitivity can be classified as positive or negative temperature sensitivity.

Hybrid systems that swell at low temperatures and shrink at high temperatures are called negative-temperature-sensitive hybrid systems.172,182,186–189 The temperature at which a sudden change occurs in the HDR of both microgels and hybrid microgels is known as the “Volume Phase Transition Temperature (VPTT)”. Above this VPTT, the polymeric network is hydrophobic in nature. Therefore, water molecules can come into the crosslinked networks and expulsion takes place in these systems. The VPTT value can vary with alteration of the composition of the crosslinked polymer systems. This value is slightly higher in hybrid microgels than pure microgels, due to the occupation of some space by the metal nanoparticles in hybrid microgels, which slightly decreases the temperature sensitivity.44

The presence of MNPs makes it more challenging to heat these structures effectively, requiring a slightly higher temperature to remove water molecules from the polymer structure. Manikas et al.190 reported that the VPTT of Au-P(NIPAM) hybrid microgels was higher than that of P(NIPAM) microgels. The temperature versus HDR curve shape for the hybrid systems closely resembled that of the original microgels, with a slight increase in the VPTT. Park et al.174 studied the temperature-sensitive behavior of a core–shell system composed of gold nanoparticles as the core and poly(N-isopropylacrylamide-acrylic acid) P(NIPAM-AAc) as the shell. They showed that the VPTT could be adjusted by varying the acrylic acid (AAc) content. This adjustment was made to match with normal body temperature to aid drug delivery. Fernández-López et al.188 described the development of Au-based hybrid microgels with longitudinal surface plasmon resonance in the near-infrared region. They achieved this by integrating Au nanorods into P(NIPAM) microgels, resulting in a photothermal effect triggered by the absorption of radiation in the water window region.

The positive temperature sensitivity of microgels and hybrid systems refers to their swelling behavior with the temperature increasing. In these systems, the moieties of the hybrid microgels/microgels are hydrophobic at low temperatures and hydrophilic at high temperatures. Consequently, the value of the HDR increases with increasing temperature.139,191–193 Acrylamide-based systems typically exhibit a positive temperature sensitivity. These hybrid microgels also have an upper critical solution temperature (UCST), which is seldom reported in the literature. For example, Zhang et al.192 synthesized Au nanorods loaded in hydrogels. These hybrid systems contained a triblock copolymer micelle with a poly(acrylamide-co-acrylonitrile) core and a poly(dimethylacrylamide) corona (water-soluble) at temperatures below the UCST. Upon exposure to near-infrared radiation, the gold nanorods absorbed light and converted it into heat. Therefore, the temperature of the medium would rise. This rise in temperature caused a transition in the solution by dissolving the micelles. Such a system shows potential as a light-triggered protein-delivery system.

Like temperature, laser light can also affect the swelling and deswelling behavior of hybrid microgels, as shown in Fig. 4(e). Such a swelling and deswelling behavior under laser light is more useful for drug delivery than others, and has been mostly used to date for drug delivery in cancer treatment.

5.2. pH sensitivity

Hybrid systems are pH-sensitive because of the presence of acidic or basic components within the structures of the crosslinked polymers. These components can undergo protonation or deprotonation by changing the pH of the medium. Due to the presence of acidic and basic components in the structure, hybrid systems can be categorized into three classes: (i) acidic hybrid microgels,194 (ii) basic hybrid microgels,195 and (ii) hybrid microgels with both acidic and basic natures.196

Hybrid systems that have acidic groups, such as –COOH46,197,198 or –SO3H,63 in their structures are classified as acidic hybrid microgels. In these hybrid microgels, the HDR increases as the pH of the medium rises, as shown in Fig. 4(b). This behavior arises because these functional groups shift from an uncharged state to an anionic form as the pH of the medium increases (at pH ≥ pKa). In the uncharged state, hydrogen bonding occurs due to the hydrogen being attached directly to a more electronegative atom (O). However, when protons are removed from these groups to form anionic species (–COO, –SO3), electrostatic repulsion occurs between the anionic components due to their like charges. This conversion occurs when the pH of the solution exceeds the pKa value. As a result of the increased hydrophilicity (electrostatic repulsion), water molecules diffuse rapidly into the crosslinked network. Conversely, these groups exist in the protonated (neutral) form (–COOH, –SO3H) when the pH of the medium decreases (at pH ≤ pKa).74 In this condition, hydrophilicity (electrostatic repulsion) dominates. Thus, the HDR decreases with decreasing the pH of the medium and increases with increasing the pH of the medium. For example, Shah et al.152 reported the pH responsiveness of gold nanoparticles in P(NIPAM-MAAc) microgels at room temperature in an aqueous medium. They observed that the HDR of the hybrid microgels increased with increasing the pH (pH = 2–6) due to the deprotonation of the –COOH groups of MAAc.

Hybrid microgels containing basic components, such as amino (–NH2) groups, within their structure are called basic hybrid microgels. The amino groups are present in a neutral (deprotonated (–NH2)) form at a high pH of the medium (pKa ≥ pH), as shown in Fig. 4(c). In this scenario, amino groups form hydrogen bonding with other amino groups and with water molecules. However, at low pH (pKa ≤ pH), the neutral amino groups are protonated into ammonium (cationic (–NH3+)) ions, leading to electrostatic repulsion between the ammonium ions and causing the hybrid microgels to swell.98,132,199–203 Hydrogen bonding is present between the ammonium ions and water molecules, but electrostatic repulsion occurs between the ammonium ions themselves due to their like charges. Consequently, more water molecules can enter into the pores of the microgels in the cationic structure (protonated form, swelling state) compared to the neutral structure (deprotonated form, deswelling state). Tang et al.72 conducted a study on the pH-sensitive properties of gold nanoparticles loaded in poly(N-isopropylacrylamide-2-(dimethylamino)ethylmethacrylate) P(NIPAM-DMAEMA) hybrid microgel systems at room temperature (25 °C) in an aqueous medium. They measured the HDR when varying the pH within the range of 3–9 and observed a gradual decrease in the values with increasing the pH from 3 to 9. This decrease was attributed to the amino groups shifting from a protonated form to a deprotonated form in the structure of the microgels. The presence of both DMAEMA and NIPAM functionalities within a single system made the system responsive to both pH and temperature variations.

Hybrid microgels that have both acidic (–COOH or –SO3H) and basic (–NH2) groups within their structures are called acidic/basic hybrid microgels.71,204 Acidic/basic hybrid microgels exhibit swelling behavior upon decreasing or increasing the pH of the medium from the zero-charge-point (ZCP). The ZPC is the pH at which both acidic (–COOH or –SO3H) and basic (–NH2) groups have zero net charge. When the pH is reduced below the ZCP, the basic (–NH2) groups become protonated, leading to repulsion among the components of the structures of hybrid systems, causing them to swell. While if the pH is greater than the ZCP, the acidic groups (–COOH or –SO3H) undergo deprotonation, leading to electrostatic repulsion among the groups. In both these conditions, swelling occurs due to electrostatic repulsion and the HDR increases. While, at pH = ZCP, both the acidic and basic groups have zero net charge, and there is no electrostatic repulsion among the groups. There is thus no electrostatic repulsion, although hydrogen bonding is present. Therefore, the HDR decreases in this case compared to at other pH conditions. A pH-sensitive acidic/basic hybrid microgel system was reported by Zheng et al.205 They studied the pH effect on the HDR of hybrid microgels at pH levels from 3 to 12. The maximum HDR value was observed at pH 8, attributed to electrostatic repulsion resulting from the negatively charged components. The HDR value reached a minimum at pH = 7, but started to increase once more as the pH was decreased further from 7 to 3, which could be attributed to protonation of the basic (–NH2) groups. The pKa and VPTT of some monomers and comonomers are given in Table 2.

Table 2 VPTT and pKa values of different monomers and comonomers of hybrid microgels
Stimuli-responsive monomers/comonomers Values of VPTT Values of pKa References
NIPAM 32   190
NIPMAM 45   133
AAc   4.5 174
MAAc   5.5 152
AAMPSAc   2.3 63


5.3. Glucose sensitivity

Hybrid microgels that have phenyl-boronic acid in their structures and exhibit a swelling/deswelling behavior in the presence of glucose are called glucose-sensitive hybrid microgels, and their swelling and deswelling behavior is shown in Fig. 4(f). They are very important materials for the detection and quantification of glucose levels in blood samples.206–208 During the detection, the –OH of boronic acid forms covalent bonds with the OH of glucose, leading to the reversible formation of ether. In the absence of glucose, the phenyl-boronic acid of the hybrid microgels exist in a dynamic equilibrium between the charged and uncharged forms in aqueous medium, as shown in Fig. 5. However, the presence of glucose shifts this equilibrium toward the formation of a complex between the charged hybrid microgels and the components of the phenyl-boronic acid. Consequently, the charged content increases with a rising glucose concentration. Sensing using hybrid microgels has recently gained significant interest for optical glucose sensing. Zhang et al.206 developed a Ag-based glucose-sensitive core–shell hybrid system, in which Ag nanoparticles served as the core and poly(3-acrylamidophenyl boronic acid-acrylic acid) P(AAPBAc-AAc) was the shell. When glucose interacts with AAPBAc, it increases the negative-charge density within the structure of the hybrid microgel. This leads to repulsive forces between the negatively charged functional groups, causing them to expand. In the absence of glucose, the size of the Ag-P(AAPBAc-AAc) hybrid microgels was reported to be 38 nm. However, as the concentration of glucose was increased from 0 mM to 30 mM, the size of the hybrid systems expanded from 38 nm to 53 nm. However, further increasing the glucose concentration did not result in a further size increase, as the hybrid microgels reached their maximum swelling limit. In this scenario, all the active sites (phenyl-boronic acids) of the hybrid microgels were bound with glucose. Ye et al.84 developed glucose-sensitive Ag@poly(3-vinylaminophenylboronic acid-diethylaminoethyl acrylate) Ag@P(VAPBAc-DEAEAc) core–shell hybrid microgels, comprising silver nanoparticles at the core, with varying contents of DEAEAc (0.000501–0.0522 mol), which were used to explore the effect of the DEAEAc content on the glucose-sensitive behavior. At functional pH 7.4, the introduction of glucose to the hybrid microgels containing a high proportion of DEAEAc generated negatively charged boronated groups. These groups then formed bonds with the positively charged nitrogen of DEAEAc through electrostatic interactions, leading to a decrease in the HDR. A small quantity of DEAEAc could create negative charge upon exposure to glucose by its swelling behavior. While the pure microgels were not fluorescent, the hybrid microgels were so, even with the incorporation of a small number of nanoparticles. Basically, the physicochemical microenvironments around the Ag nanoparticles changes during the swelling/deswelling behavior. In other words, the refractive index of these hybrid microgels alters during their swelling/deswelling. Therefore, the optical property of Ag nanoparticles affected these hybrid microgels, but such optical property was not present in the pure microgels. Therefore, a change in photoluminescence (PL) intensity occurred when different concentrations of glucose were added during the investigation of glucose sensitivity due to the transformation from the swelling state to the deswelling state. The adsorption of glucose increased with increasing the content of DEAEAc, which decreased the PL intensity and vice versa. Zhang et al.209 reported the glucose-sensitive behavior of Au-poly(N-isoproylacrylamide-3-acrylamidophenylboronic acid) Au-P(NIPAM-AAPBAc) hybrid microgels. They examined the swelling behavior of both the pure microgels and hybrid systems by varying the concentrations of glucose in the range of 0–30 mM. They observed a linear increase in the size of both systems with the increase in the concentration of glucose from 0 to 10 mM. However, no further increase in the size was observed upon further increasing the concentration of glucose from 10 to 30 mM, due to the unavailability of active sites (boronic acid groups) in the structures. These results suggested that boronic acid was an essential constituent of the structure for the detection and sensing of glucose.
image file: d4ra04128c-f5.tif
Fig. 5 Mechanism of glucose sensitivity.

5.4. Sensitivity to ionic strength

Hybrid microgels that show a swelling and deswelling behavior under various contents of ionic salts (metal salts) in a medium are called ionic strength-sensitive hybrid microgels, as shown in Fig. 4(d). The concentration of ionic salts affects the swelling and deswelling behavior of hybrid microgels.170,210–213 When salts dissolve in a dispersion of hybrid microgels, they ionize due to the presence of water molecules. The structure of the hybrid microgels contains polar or ionic groups that interact with the produced ions. As a result, these ions penetrate the pores of hybrid microgels and decrease the diffusion rate of water molecules. This swelling/deswelling behavior depends on the nature of both the hybrid microgels and the salts. Das et al.214 investigated the ionic-strength sensitivity of amphoteric silver-poly(N-isopropylacrylamide-N,N-dimethyl-N-(3-methacrylamidopropyl)-N-(3-sulfopropyl) ammonium betaine) Ag-P(NIPAM-DMSABe) hybrid microgels. These hybrid systems showed a responsive behavior when a salt such as KCl or CdCl2 was added to a dispersion of hybrid microgels. It was observed that the VPTT shifted to lower values as the salt concentration or oxidation state of the metal ions increased.

6. Applications

Hybrid microgels have potential and are already used in various applications in different fields, as shown in Fig. 6. A discussion about these applications is given below.
image file: d4ra04128c-f6.tif
Fig. 6 Applications of hybrid microgels in different fields.

6.1. As an adsorbent

Microgels have polar components in their structures, which can interact with metal cations. Therefore, ions can penetrate into the crosslinked networks of microgels, where these ions are reduce into their corresponding atoms. However, these atoms are unstable, and thus they start to coagulate to obtain stability due to the atomic bonds. This coagulation is controlled by the crosslinked network as well as by stabilization of the particles.126,215–217 In the presence of these metal nanoparticles, the structure of hybrid microgels also has an affinity to interact with other materials. In this way, the crosslinked network of hybrid microgels are responsible for this adsorption. Therefore, the adsorption of pollutants depends on the nature of the hybrid microgels (nature of the monomers, comonomers) and the nature of the adsorbents. More content will be absorbed if opposite charges are present on both the adsorbate and adsorbent.66,76,77,138,218–223

In this way selectivity can also be created in the hybrid microgel systems for the adsorption of specific pollutants, because the hybrid microgels will repel pollutants if the same charge is present on both. Mostly, the adsorption of pollutants by hybrid microgels is monitored by UV-Visible spectrophotometry (for all types of pollutants) or atomic adsorption spectrophotometry (only for metal ions). The adsorption of pollutants can be performed by mixing both the pollutants and hybrid microgels in an aqueous medium and stirring for some time. After that, the pollutant-loaded hybrid microgels are separated from the mixture by centrifugation or magnetic field (for magneto-sensitive hybrid microgels) and analyzed.224

The sample pollutant solution before adding the hybrid microgel and after removing the hybrid microgels will be placed in a UV-Visible spectrophotometer or atomic adsorption spectrophotometer for analysis. The difference in the initial and final values indicates the removal percentage of pollutants. For example, Mizuno et al.66 studied the adsorption of 4NiP by palladium nanoparticles-based hybrid microgels. The polar (–OH) functional groups in the hybrid microgels formed hydrogen bonds with the polar 4NiP. Therefore, 4NiP could be easily extracted by the crosslinked network of the hybrid microgels. Wang et al.65 also used microgel systems to sorb palladium ions and simultaneously catalyze the reduction of 3NiP. The sorption of palladium ions occurred through ion–dipole interactions, followed by their reduction to palladium nanoparticles for the catalytic reduction of 3NiP. In this way, the metallic ion pollutants could be converted into metal nanoparticles, which are powerful catalysts for the reduction/degradation of pollutants.

6.2. Catalysis

The most important property of hybrid microgels is their catalytic behavior. They can be applied as catalysts for transformation/reduction/degradation reactions.167,225–230 Hybrid microgels have several advantages over conventional catalytic systems, including:

(1) Nanoparticles have high stability within microgels due to the strong donor–acceptor interactions that are present between these nanoparticles and various functionalities of the microgels. These interactions can effectively prevent the leaching of MNPs from microgels during catalysis.231,232

(2) The porosity of hybrid microgels facilitates the approach of reactant molecules to the surface of MNPs.233

(3) The catalytic efficiency of hybrid microgels can be tuned by external stimuli, such as temperature,185 ionic strength,234 and pH.183

(4) The nanoparticles can be easily separated from the reaction product after completion of the reaction by centrifugation32,51 or by applying a magnetic field.96

(5) The chemically inert nature of microgels ensures that they do not actively participate in the catalytic process.43

(6) In some instances, the polymeric network in hybrid microgels establishes a supportive environment that promotes the diffusion of reactant molecules from the bulk to the surface of metal nanoparticles, thereby enhancing the rate of the chemical reaction.

Various catalytic reactions can be done with hybrid microgels, with some common catalytic organic reactant conversions described below.

Hybrid microgels are frequently utilized as catalysts for the reduction of nitroarenes in aqueous media along with reducing agents like NaBH4.93,146,229,235–238 Four steps are involved in the catalytic reduction of nitroarenes, which can occur via either route I or route II as shown in Fig. 7. Route II is preferred when the reaction proceeds rapidly, while route I is favored for slower reactions. In route I, H2 gas is produced, which is highly stable and consequently less reactive; while nascent hydrogen is generated in route II that is extremely unstable and had high reactivity. As a result, the nascent hydrogen rapidly reacts with other molecules, leading to a faster product conversion, as depicted in route II.43


image file: d4ra04128c-f7.tif
Fig. 7 Mechanism for the reduction of nitroarenes by hybrid microgels and NaBH4.

The catalytic reduction of 4NiP to 4-aminophenol (4AmP) is commonly employed as a model reaction to assess the catalytic efficiency of hybrid systems. This reaction was often selected due to the detoxification of 4NiP into the less toxic 4AmP, which can further be converted into various organic compounds. Another reason is the easy monitoring of the 4NiP reduction process. The progression of the reduction reaction can be monitored using a UV/Vis spectrophotometer, where a decrease in the absorbance at 400 nm and the appearance of a new peak around 300 nm indicate the conversion of 4NiP to 4AmP. Similar trends in absorbance have been reported by Aldabergenov et al.,239 Ulker et al.,240 and Tatykhanova et al.241

Numerous factors influence the catalytic efficiency of hybrid systems during the reductive reduction of nitroarenes, as shown in Fig. 8(A)–(C). The quantity of metal nanoparticles present in the hybrid microgels is a key factor determining the reduction rate,63,82 whereby increasing their content in hybrid systems enhances the reduction rate of nitroarenes. Gancheva and Virgilio241 synthesized both porous and non-porous microgels loaded with different amounts of Au nanoparticles. The catalytic activity of the porous hybrid systems with a greater content of Au NPs (2.7 wt%) surpassed that of the non-porous systems. Similarly, Zhou et al.128 investigated the effect of the content of MNPs on the catalytic reductive reactions and reported similar catalytic trends.


image file: d4ra04128c-f8.tif
Fig. 8 Catalytic reduction of nitroarenes by hybrid microgels under different (A) temperatures, (B) pH levels of the medium, and (C) contents of metal nanoparticles in the microgels.

The catalytic efficiency can be tuned by varying the temperature, as shown in Fig. 8(A). The temperature dependence deviates from t normal Arrhenius behavior in the case of temperature-sensitive hybrid microgels. The HDR of hybrid microgels decreases as the temperature of the medium rises. The HDR exhibits its maximum derivative at the VPTT. Below the VPTT, the hydrogels are present in a swelling state, allowing reactant molecules to easily access the MNPs surface; therefore facilitating a rapid conversion of the reactants to products. Conversely, the catalytic reductive reaction rate decreases at temperatures above the VPTT due to the shrinkage and the resulting decrease in the HDR. This shrinkage makes it more challenging for reactants to reach the catalyst surface.57,74,75,242 The use of the Arrhenius equation provides a quantitative method to analyze the temperature impact on the reaction rate catalyzed by hybrid systems. The relationship between the natural logarithm of the reaction rate constant (ln[thin space (1/6-em)]kapp) and the reciprocal of temperature (1/T) within the temperature range encompassing the VPTT has been observed to be non-linear. Further, it has been found that the kapp value increases with temperature, reaches a minimum at the VPTT, and then starts to rise again. The temperature effect on the kapp value for the catalytic reductive reaction of 4NiP in the presence of hybrid microgels and NaBH4 was investigated by Hussain et al.243 and Rehman et al.152

The catalytic efficiency of hybrid microgels can readily be controlled by adjusting the pH of the medium during the catalytic reductive reactions, as shown in Fig. 8(B). This pH sensitivity is present if the structures of the hybrid microgels have basic (–NH2)244 or acidic (–COOH,46,245, –SO3H63) groups. The pH effect on these acidic (–COOH, –SO3H) and basic (–NH2) groups is opposite in nature, as one group (–NH2) is basic in nature while the other (–COOH, or –SO3H) is acidic. Acidic hybrid microgels have –COOH or –SO3H groups in their structure. These groups exhibit a swelling behavior when the pH of the medium increases above the pKa value. Once the pH exceeds the pKa value of the ionic portion, all the acidic (–SO3H or –COOH) groups will convert into anions (–SO3 or –COO). These negatively charged groups repel each other electrostatically, leading to an increase in the HDR. In this swollen state, a greater number of reactant species can easily access the MNPs surface, resulting in a higher conversion of reactants into products, together with an increased apparent rate constant. In contrast, at pH values ≤ pKa, the hybrid microgels undergo deswelling, limiting the number of reactants that cab reach the MNPs surface and consequently yielding a smaller amount of product. Shah et al.152 investigated the impact of pH on the catalytic efficiency. They noted that at pH 2.78, the kapp value was 0.196 min−1, which increased to 0.321 min−1 at pH 8.36. Additionally, they observed that higher concentrations of monomers containing acidic groups resulted in an improved catalytic performance, likely due to the greater swelling.

The catalytic performance can be impacted by the presence of basic (–NH2) groups in the hybrid microgel structure, which can be regulated by adjusting the pH of the medium, as shown in Fig. 8(B). At low pH values, the basic (–NH2) groups exist in a protonated (–NH3+) form, leading to electrostatic repulsion caused by the cationic functionalities within the structure. As a result, the HDR value is lowered at high pH and increases with decreasing the pH value. Tan et al.93 studied the catalytic activity for the reduction of 4NiP over a pH range of 3 to 11. They observed that the value of kapp was highest at pH 3 and gradually declined as the pH increased. For example, at room temperature, the kapp value was 7.3 × 10−3 s−1 at pH 3 and 7.4 × 10−4 s−1 at pH 7.

The catalytic efficiency of bimetallic nanoparticles-containing hybrid systems exceeds that of monometallic nanoparticles systems for the reduction of nitroarenes.94,146,163 The addition of metallic nanoparticles to systems containing other metallic nanoparticles can enhance each other's performance due to a synergistic effect. The interface formed between one type of MNPs and another type of MNPs in the hybrid microgels enhances the catalytic performance. The work function values of both types of MNPs play a role in creating a depletion region, causing electron transfer from the lower work function side to the higher work function side. This interaction between electron-deficient reactants (nitroarenes) and electron-rich nanoparticles allows a greater number of reactant molecules to reach the nanoparticles' surface, resulting in a faster reduction reaction.246 Li et al.82 reported the synthesis of bimetallic (Ag + Au) hybrid microgels. They loaded gold NPs with varying concentrations in Ag-based hybrid microgels and observed that the kapp value for the catalytic reductive reaction of 4NiP in the presence of each hybrid system increased with increasing the amount of Au NPs. Similarly, Tan et al.93 investigated the catalytic activity of a bimetallic (Au + Ag) hybrid system in which Ag nanoparticles were loaded into Au-based hybrid microgels.

The content of the reductant (NaBH4) and the content of metal nanoparticles in the microgels (as shown in Fig. 8(C)) also impacted the catalytic efficiency;43,61,115 whereby a higher reductant concentration increased the kapp value, leading to a faster completion of the reaction. Essentially, the higher reductant content resulted in more of the compound being adsorbed onto the catalyst surface, leading to increased hydrogen release, which in turn affected the rate of product formation. Hussain et al.243 studied the catalytic performance of Ag nanoparticle-encapsulated core–shell microgel systems under various NaBH4 concentrations and noted that the reaction rate increased with higher NaBH4 concentrations.

The number of nitro groups in nitroarenes also influences the catalytic performance of hybrid microgels. Therefore, the kapp value for the reduction of tri-nitroarenes is smaller than that for mono-nitroarenes under similar conditions. Mono-nitroarenes can thus be reduced more rapidly compared to di- and tri-nitroarenes. Melinte et al.247 investigated the catalytic reduction of 2,6-dinitrophenol (di-nitroarene), 4NPh (mono-nitroarene), and picric acid (tri-nitroarene) under similar conditions and calculated the kapp values for each reductive reaction as 16.52 × 10−3, 34.35 × 10−3, and 12.31 × 10−3 min−1, respectively.

The rate of reduction can be significantly influenced by the presence of specific gases dissolved in the aqueous dispersion of the reaction mixture. The catalytic performance of hybrid microgels is different in N2 and CO2 gaseous environments. CO2 gas purging in hybrid microgel dispersions leads to the transformation of carboxylic (–COOH) groups, which thus alters the interfacial interactions between the functionalities of the microgels and MNPs. Thus, the catalytic activity can be significantly affected by purging with CO2. In one study,44 the impact of introducing N2 and CO2 gases into the reaction mixture was examined in relation to the catalytic efficiency of Au-P(NIPAM-MAAc) for 4NiP reduction. It was found that the kapp values were 2.1 × 103 and 3.2 × 103 min−1 for N2 and CO2 gas purging, respectively, at T ≤ 29 °C. At T ≥ 35 °C, the kapp values were 1.3 × 104 and 1.4 × 1012 min−1 for N2 and CO2 purging, respectively.

The reduction rate of nitroarenes also depends on the substituent and position of the attached substituent on the nitro-benzene ring.43,58,151,248 If the substituent is an electron-donating species, then the reduction rate is low; while if an electron-withdrawing group is attached directly to the ring, then reduction can rapidly take place.43 Basically, nitro groups are electron deficient, and their deficiency can be reduced by electrons provided by the metal nanoparticles. If the electron-donating group is directly attached to the ring, it donates some electronic cloud to the nitro group. Therefore, the electron deficiency is minimized by electron-donating groups, and their capacity to obtain electrons from metal nanoparticles is also reduced, resulting in reduction rated. On the other hand, an electron-withdrawing group would further decrease the electronic cloud from the ring. Therefore, rings do not donate their electronic cloud to nitro groups. Therefore, they rapidly gain electrons from MNPs and reduce them rapidly.

Dyes are a major source of water pollution, and are used in textile industries on a large scale. These industries discharge these dyes as waste material. These dyes are very toxic to human health. Therefore, it is a very important task to remove these dyes from contaminated water. To address this problem, various catalytic systems are used to degrade or reduce the toxic dyes into harmless compounds. Hybrid microgels are considered the best materials for rapid catalytic reduction or degradation.14,67,139,215,216,249 Shah et al.250 investigated the catalytic performance of Au- or Ag-based hybrid microgels for the reduction of Congo red (CR), 4-nitrophenol (4NiP), and methylene blue (MB). They showed excellent results for industrial wastewater treatment. Their catalytic efficiency in wastewater was slightly lower than pure water, due to the presence of various metallic and nonmetallic ions in wastewater, which interact with the polar components of hybrid microgels and resist the approach of dyes to the surface of MNPs. Han et al.251 studied the catalytic performance of Au-based hybrid microgels for the reduction of MB, rhodamine B (RAB), and 4NiP. They observed that 4NiP and organic dyes were adsorbed onto the Au nanoparticle surface and then desorbed as products. The catalytic efficiency of the hybrid system followed the order: MB > RAB > 4NiP. Similarly, Cao et al.252 investigated the catalytic activity of gold nanoparticles encapsulated in core–shell hybrid systems for the reduction of 4NiP and RAB. They found there was no significant decrease in the catalytic performance of the hybrid systems after recycling.

Hybrid microgels show excellent catalytic performance for coupling reactions conducted under various conditions. Increasing the temperature can enhance the reaction rate, leading to the formation of more products in a shorter time. With higher temperature, a greater fraction of reactant molecules have kinetic energy (KE) equal to or greater than the activation energy (Ea), resulting in more collisions and a higher reaction rate. The choice of solvent also affects the catalytic efficiency of hybrid microgel systems in coupling reactions. Among the organic solvents, ethanol has been found to be the most effective. Eyimegwu et al.253 utilized hybrid microgels for various homocoupling reactions under different solvents in aerobic conditions. Albino et al.,254 Wang et al.,65 and Hong et al.255 investigated coupling reactions in the presence of Pd nanoparticle-decorated microgels. Pourjavadi et al.256 used core–shell hybrid microgels for the reduction of 4NiP and for Suzuki–Miyaura coupling reactions. They conducted coupling reactions between substituted iodo/bromobenzenes and phenyl-boronic acid under different solvents, temperatures, and bases, and found that a higher product yield was obtained in water compared to in other solvents under similar conditions. Additionally, they noted that the presence of an electron-withdrawing group attached to the iodo-/bromobenzene resulted in a higher yield, whereas the presence of an electron-donating group led to a lower yield.

6.3. Detection

Hybrid microgels show excellent performance for the detection (sensing) of various materials, like toxic metal ions in water.184,257–259 Tang et al.72 explored the sensing properties of gold nanoparticles incorporated into poly(N-isopropylacrylamide-2-(dimethylamino)ethylmetharylate) P(NIPAM-DMAEMA) for the detection of Hg2+ ions. They observed a linear relationship between the fluorescence intensity and the concentration of mercuric ions after adding a mercuric ions solution in to a dispersion of 1-pyrenebutyric acid (PBA) containing hybrid microgels. This behavior was attributed to replacing the PBAc with Hg2+ ions from the hybrid microgels. As the concentration of Hg2+ ions increased from 0.16 to 1.60 μM, there was an increase in the fluorescence intensity, which could be used to accurately quantify the Hg2+ ions in the samples. Similar experiments were conducted under similar conditions with other metal ions. The results showed that metals other than Hg2+ did not induce significant changes in the fluorescence intensity. This indicated that the hybrid microgels could be used selectively for sensing Hg2+ ions.

Hybrid microgels can also help in detecting thrombin, which is an enzyme responsible for converting fibrinogen into fibrin in the human body. Gui et al.73 devised an electro-chemiluminescent aptasensor by combining a ruthenium (Ru) complex with hybrid microgels to sense thrombin using an electro-generated chemiluminescence method. Upon adding thrombin to the hybrid microgels containing Ru, the peak intensity increased. This peak intensity exhibited a direct correlation with the concentration of thrombin, spanning from 1.0 fM to 10 pM, with a detection limit of 0.54 fM.

Different substances can also be detected by hybrid microgels. The sensing/detection abilities of the hybrid microgels are usually evaluated using cyclic voltammetry, which is a technique that tracks the oxidation and reduction positions of the sensor. The sensing ability is determined by observing any shift in the oxidation or reduction potential of the sensor in the presence of a specific substance, enabling the detection of even minute quantities of substances. Mutharani et al.71 investigated the detection of organophosphorus pesticide paraoxon-ethyl by using hybrid microgels at various concentrations (0.01 μM to 1.3 mM), and demonstrated remarkable results. Tang et al.260 studied the sensing ability of Pd-P(AAc) for H2O2. They observed a reduction peak at 0.1 V for H2O2. A similar reduction peak was obtained with Au/Pd2+-P(AAc), albeit with a significantly lower intensity. However, no such reduction peak was observed with Au/P(AAc) in the presence of H2O2.

6.4. Drug delivery

Smart microgels with metal nanoparticles have attracted significant attention as drug-delivery systems owing to their sensitivity under different pH, temperature, and electromagnetic radiation conditions.132,261–266 These hybrid systems can be used for the delivery of drugs into the body, as shown in Fig. 9. Upon reaching the target site, laser light (in the water window or near-infrared spectrum) is applied and directed toward the designated area. Au-based hybrid systems can absorb the light and convert it into heat energy, which increases the temperature. This temperature rise triggers a phase transition in the hybrid microgels, facilitating the release of the drug at the targeted location. Solorzano et al.266 conducted a study on a photo-responsive drug-delivery system utilizing hollow gold nanoparticles-incorporated P(NIPAM) systems. The hybrid microgels were loaded with bupivacaine hydrochloride monohydrate drug. The researchers investigated the drug-release kinetics under near-infrared irradiation, and demonstrated the potential of the Au-P(NIPAM) hybrid system as a promising photothermally triggered drug carrier.
image file: d4ra04128c-f9.tif
Fig. 9 Loading and release of a drug by hybrid microgels.

The loading and release of a drug may be studied in different pH conditions. Hybrid microgels show a swelling and deswelling behavior in different pH conditions and it is this swelling and deswelling behavior that control the loading and release of the drug. In this way, the pH of the medium is also an important parameter for drug-delivery systems. The controlled release behavior of hybrid microgels can be obtained by adjusting the content of monomers, comonomers, and crosslinkers during the formation of hybrid microgels. The naturalness of the monomers, comonomers, and crosslinkers is also an important aspect for drug delivery. They also have an effect on loading and release of the drug in the systems through variations in the polarity. Therefore, the interactions that occur between the drug and structure of the hybrid microgels during the loading and release of the drug depend on the nature of both the hybrid microgels and the drug.

6.5. Anticancer/antitumor treatment

Hybrid microgels can be used in tumor/cancer treatment.47,267–269 For these applications, both the MNPs and the organic components of hybrid systems play pivotal roles in cancer therapy. Specifically, Au nanoparticles possess the ability to absorb light within the wavelength range of 500–1200 nm and convert this absorbed light into thermal energy through a radiation-less relaxation process. Consequently, the temperature of the local environment increases when near-infrared light is applied at the target area of the body after the injection of hybrid microgels. This rise in temperature facilitates tumor treatment through a photothermal mechanism. Wang et al.270 developed Au-based gelatin for photothermal therapy. This hybrid system demonstrated notable characteristics, like excellent stability, a high content of Au NPs, and low degradability, making it suitable for effective photothermal therapy.

The combination of photothermal therapy and chemotherapy presents a favorable approach for cancer treatment with high potential efficiency. The temperature sensitivity of hybrid microgel systems plays a critical role in controlling the release of loaded anticancer drugs, as discussed earlier. Zhou et al.68 developed a hybrid microgels system and used this for the loading and release of the anti-inflammatory drug diclofenac sodium (DS) and the anticancer drug doxorubicin (DR). The gold nanoparticles in the hybrid microgel served several functions: they can absorb DR on their surface, which can then be replaced by glutathione (GT) present within tumor cells, and they have the ability to convert absorbed light into heat, triggering a volume phase transition in the microgels, resulting in the release of the DS.

6.6. Antibacterial activities

Hybrid microgels exhibit excellent antibacterial properties by releasing metal ions into an aqueous medium through a porous microgel system, surpassing the antibacterial efficiency of bulk metals. Unlike toxic agents, metal nanoparticles demonstrate antibacterial activity without releasing harmful substances.70,122,125,226,271,272 By penetrating bacterial membranes, Ag+ ions have the ability to replace various other metal cations, such as Ca2+, in biological systems.273 Additionally, they can attach to electron-donating groups, like carboxylate, phosphate, and thiol groups, present in DNA. They can interrupt normal cellular processes, leading to the death of bacterial cells.274 Consequently, they are effective at eradicating bacteria such as Staphylococcus epidermidis (S. epidermidis),214 Staphylococcus aureus (S. aureus),275–277 Pseudomonas aeruginosa (P. aeruginosa),276,278 and Escherichia coli (E. coli).70,122,271,279–281 For example, Hantzschel et al.276 examined the antibacterial activity of Ag-based hybrid microgels by observing the growth of bacterial colonies of S. aureus and P. aeruginosa over time with varying the content of Ag NPs in the hybrid microgels. They observed there was a notable reduction in bacterial growth, and the antibacterial activity was enhanced with increasing the Ag NPs content. Microgels containing 11.2% Ag nanoparticles exhibited more effective antibacterial properties against P. aeruginosa compared to S. aureus. This difference was attributed to the thinner murein layer of P. aeruginosa compared to S. aureus, allowing for a faster diffusion rate of the antibacterial agent into the bacterial cells, resulting in a quicker eradication. The researchers demonstrated that as the content of Ag nanoparticles increased, the antibacterial effectiveness of the hybrid microgels also increased. In a separate study, Thomas et al.282 investigated the antibacterial activity of hybrid systems against E. coli. They examined the effects of the hybrid microgel particle size, Ag NPs loading, and the content of AAc present in the hybrid systems on the antibacterial activities of the hybrid microgel. They found that hybrid systems with a size of 100 μm showed a superior inhibition of bacterial colony growth compared to those with a size of 200 μm in an aqueous medium due to the reduction in the surface area of larger particles. The antibacterial performance against E. coli increased with a higher content of Ag NPs within the microgels. The study highlighted that the feed composition of the microgels significantly influenced their antibacterial properties, with hybrid systems containing 5.55 mM of AAc demonstrating greater efficiency compared to those with no AAc content (0.00 mM AAc).

7. Conclusion and future directions

The integration of metal nanoparticles into smart microgels creates unique and intriguing hybrid systems. These hybrids exhibit responsive behaviors, leading to a diverse range of hybrid microgels with distinct shapes, compositions, and structures. These systems have demonstrated remarkable performance in catalytic reactions and their performance can be controlled by varying their size and morphology. Consequently, these systems are predominantly used in catalytic reactions over other applications. Their catalytic efficiency can be tuned with external stimuli conditions, like pH, temperature, solvent nature, and ionic strength of the medium. Moreover, the potential applications of hybrid microgels in various fields, such as drug delivery, adsorption, antibacterial, and anticancer, are influenced by their morphology, which can be customized to specific requirements using suitable synthetic techniques. The morphologies, functional hierarchy, and crystallinity of synthesized hybrid systems can be identified using diverse characterization techniques.

Some metal ions (like palladium ions) exhibit significant environmental toxicity, limiting their direct applicability. However, these ions can be converted into valuable substances, as demonstrated by their incorporation in nanocomposites such as palladium nanoparticle-based hybrid microgels. These composite materials with palladium nanoparticles present in the microgels have diverse applications across various fields. However, the toxicity of palladium metal hinders the use of palladium-based hybrid microgels in drug-delivery applications, highlighting a notable drawback of these hybrid microgels.

Another drawback observed in previously reported hybrid microgels is the use of non-biodegradable monomers during their synthesis. For instance, N-isopropylacrylamide has been widely utilized in the synthesis of hybrid systems, but leads to the formation of non-biodegradable microgels. This limitation could be addressed by employing biodegradable monomers, like N-vinyl caprolactam. Metal nanoparticle-decorated microgels have shown the best performance involving catalyst transformation for specific organic reactions, notably in the reduction of 4-nitrophenol. Thus, investigating the catalytic potential of hybrid microgels across a range of organic transformations could provide valuable insights for future research. Bimetallic nanoparticles-containing hybrid microgels have demonstrated significantly enhanced performance for many catalytic reduction and degradation reactions compared to monometallic hybrid systems. Therefore, a more comprehensive examination of bimetallic hybrid systems is warranted. Moreover, the high cost of noble metals, excluding palladium (which is toxic), presents a challenge that can be addressed by combining these metals with less expensive ones in bimetallic hybrid systems. Additionally, recycling hybrid systems after catalysis offers a potential solution to this challenge. Further research is needed to explore the leaching effect and catalytic performance of recycled hybrid microgels. Moreover, the factors directly influencing the catalytic efficiency of bimetallic hybrid microgels, such as temperature, solvent nature, pH levels, and ionic strength of the medium, require thorough exploration in future studies. Furthermore, forthcoming research should evaluate the compatibility of hybrid polymers with various substrates to assess their potential applications.

Metal nanoparticles have found expanded applications within microgels, which can contain both polar and non-polar components in their structure. Consequently, hybrid microgels present potential uses in catalysis (noble metal nanoparticles) as well as in adsorption processes (microgel component). Although only a few hybrid microgel systems have been employed in adsorption processes thus far, there is an opportunity to explore these as alternative systems for the removal of various water pollutants, including heavy metal ions and harmful organic dyes. These hybrid systems may prove to be the best option for the purification of industrial wastes through a combination of adsorption and catalytic reactions.

Abbreviations

AAcAcrylic acid
AAmAcrylamide
NIPMAMN-Isopropylmethacrylamide
NIPAMN-Isopropylacrylamide
NPsNanoparticles
SMGsSmart microgels
MAAcMethacrylic acid
MNPsMetal nanoparticles
MBMethylene blue
CRCongo red
4NiP4-Nitrophenol
4AmP4-Aminophenol
DMAEMA2-(Dimethylamino)ethylmethacrylate
VCLN-Vinylcaprolactam
AAEMAAcetoacetoxyethylmethacrylate
MCMCSMaleate carboxylmeth chitosan
EAEther amine
AAMPSAc2-Acrylamido-2-methylpropane sulfonic acid
DLSDynamic light scattering
SDSSodium dodecyl sulfate
MOMethyl orange
RABRhodamine B
PBAc1-Pyrenebutyric acid
DSDiclofenac sodium
DRCDoxorubicin
GTGlutathione
EDXEnergy-dispersive X-ray spectroscopy
FTIRFourier-transform infrared spectroscopy
HDRHydrodynamic radius
HRTEMHigh-resolution transmission electron microscopy
LCSTLower critical solution temperature
MIEEMACh2-(1-Methylimidazolium-3-ethyl)-ethyl methacrylate chloride
MMAAcMethylmethacrylic acid
MBAAmN,N′-Methylene-bisacrylamide
APSAmmonium persulfate
MAPTMSi3-Methacryloxypropyltrimethoxy silan
GRGalvanic reaction
HEA2-Hydroxyethyacrylate
VP4-Vinylpyridine
SEMScanning electron microscopy
SPRSurface plasmon resonance
TGAThermogravimetric analysis
DEAEAcDiethylaminoethylacrylate
UV-VisUV-Visible spectroscopy
VPTTVolume phase transition temperature
XPSX-ray photoelectron spectroscopy
XRDX-ray diffraction
P(EI)Poly(ethyleneimine)
AAPBAc3-Acrylamidophenyl boronic acid
VAVinyl alcohol
VAPBAc3-Vinylaminophenyl boronic acid
ICP-AESInductively coupled plasma atomic emission spectroscopy

Data availability

Data will be provided on request.

Conflicts of interest

There are no conflicts of interest to declare.

Acknowledgements

Muhammad Arif is thankful to University of Management and Technology, Lahore 54770, Pakistan.

References

  1. A. Ben Ali, R. Elaf, M. Saad, I. A. Hussein and B. Bai, Emergent Mater., 2023, 1–11 Search PubMed.
  2. M. Arif, A. Rauf and T. Akhter, Int. J. Biol. Macromol., 2024, 274, 133250 CrossRef CAS PubMed.
  3. M. Arif, Eur. Polym. J., 2024, 206, 112803 CrossRef CAS.
  4. N. Hazra, A. Ninarello, A. Scotti, J. E. Houston, P. Mota-Santiago, E. Zaccarelli and J. J. Crassous, Macromolecules, 2024, 57, 339–355 CrossRef.
  5. M. Arif, H. Raza, S. M. Haroon, S. Ben Moussa, F. Tahir and A. Y. A. Alzahrani, Int. J. Biol. Macromol., 2024, 270, 132331 CrossRef CAS PubMed.
  6. M. Arif, J. Mol. Liq., 2024, 403, 124869 CrossRef CAS.
  7. M. Arif, RSC Adv., 2024, 14, 9445–9471 RSC.
  8. G. Agrawal and R. Agrawal, Small, 2018, 14, 1801724 CrossRef PubMed.
  9. M. Arif, JOM, 2024, 76, 1203–1222 CrossRef CAS.
  10. M. Arif, Polymers, 2023, 15, 3600 CrossRef CAS PubMed.
  11. D. C. Leite, S. Kakorin, Y. Hertle, T. Hellweg and N. P. da Silveira, Langmuir, 2018, 34, 10943–10954 CrossRef CAS PubMed.
  12. M. Arif, A. Rauf, H. Raza, S. B. Moussa, S. M. Haroon, A. Y. A. Alzahrani and T. Akhter, Int. J. Biol. Macromol., 2024, 275, 133633 CrossRef CAS PubMed.
  13. V. Sabadasch, M. Dirksen, P. Fandrich and T. Hellweg, Front. Chem., 2022, 10, 889521 CrossRef CAS PubMed.
  14. M. Shahid, Z. H. Farooqi, R. Begum, M. Arif, W. Wu and A. Irfan, Crit. Rev. Anal. Chem., 2020, 50, 513–537 CrossRef CAS PubMed.
  15. M. Arif, H. Raza, S. M. Haroon, K. Naseem, H. Majeed, F. Tahir, U. Fatima, S. M. Ibrahim and S. Ul Mahmood, J. Mol. Liq., 2023, 392, 123541 CrossRef CAS.
  16. M. Shahid, Z. H. Farooqi, R. Begum, M. Arif, A. Irfan and M. Azam, Chem. Phys. Lett., 2020, 754, 137645 CrossRef CAS.
  17. M. Dirksen, T. A. Kinder, T. Brändel and T. Hellweg, Molecules, 2021, 26, 3181 CrossRef CAS PubMed.
  18. M. Dirksen, C. Dargel, L. Meier, T. Brändel and T. Hellweg, Colloid Polym. Sci., 2020, 298, 505–518 CrossRef CAS.
  19. X. Li, L. Hetjens, N. Wolter, H. Li, X. Shi and A. Pich, J. Adv. Res., 2023, 43, 87–96 CrossRef CAS PubMed.
  20. M. Marquis, D. Musino, V. Gemin, L. Kolypczuk, D. Passerini and I. Capron, Carbohydr. Polym. Technol. Appl., 2023, 6, 100405 CAS.
  21. L. Liu, Y. Liu, H. Zhong, X. Li, Y. Jun, Q. Wang, L. Ding, Z. Cheng and H. Qian, Colloids Surf., B, 2023, 229, 113432 CrossRef CAS PubMed.
  22. M. Arif, A. Rauf and T. Akhter, RSC Adv., 2024, 14, 19381–19399 RSC.
  23. M. Tang, Y. Sun, X. Feng, L. Ma, H. Dai, Y. Fu and Y. Zhang, Food Chem., 2023, 419, 136044 CrossRef CAS PubMed.
  24. X. Wan, Q. Kang, J. Li, M. Guo, P. Li, H. Shi, X. Zhang, Z. Liu and G. Xia, Food Chem., 2024, 433, 137395 CrossRef CAS PubMed.
  25. D. E. Demco and A. Pich, Macromol. Chem. Phys., 2023, 224, 2200410 CrossRef CAS.
  26. T. Nevolianis, A. Scotti, A. V. Petrunin, W. Richtering and K. Leonhard, Polym. Chem., 2023, 14, 1447–1455 RSC.
  27. M. Arif, Z. Phys. Chem., 2023, 237, 809–843 CrossRef CAS.
  28. S. K. Wypysek, S. P. Centeno, T. Gronemann, D. Wöll and W. Richtering, Macromol. Biosci., 2023, 23, 2200456 CrossRef CAS PubMed.
  29. H. P. Lim, S. S. D. Ng, D. B. Dasa, S. A. Adnan, B. T. Tey, E. S. Chan, K. W. Ho and C. W. Ooi, Int. J. Biol. Macromol., 2023, 232, 123461 CrossRef CAS PubMed.
  30. M. Arif, J. Environ. Chem. Eng., 2023, 11, 109270 CrossRef CAS.
  31. V. Sabadasch, S. Dachwitz, Y. Hannappel, T. Hellweg and N. Sewald, Synthesis, 2022, 54, 3180–3192 CrossRef CAS.
  32. M. Arif, F. Tahir, U. Fatima, R. Begum, Z. H. Farooqi, M. Shahid, T. Ahmad, M. Faizan, K. Naseem and Z. Ali, Mater. Today Commun., 2022, 33, 104700 CrossRef CAS.
  33. N. George, J. Joy, B. Mathew and E. P. Koshy, J. Sol–Gel Sci. Technol., 2023, 107, 685–696 CrossRef CAS.
  34. Z. H. Farooqi, G. T. Vladisavljević, N. Pamme, A. Fatima, R. Begum, A. Irfan and M. Chen, Crit. Rev. Anal. Chem., 2023, 1–15,  DOI:10.1080/10408347.2023.2177097.
  35. E. Jha, P. Patel, P. Kumari, K. K. Verma, P. K. Panda, P. S. Mohanty, S. Patro, R. S. Varma, Y. K. Mishra, N. K. Kaushik, M. Suar and S. K. Verma, J. Environ. Chem. Eng., 2023, 11, 111183 CrossRef CAS.
  36. A. Raza, S. Rauf Khan, S. Ali, S. Jamil and S. Bibi, Inorg. Chem. Commun., 2023, 153, 110851 CrossRef CAS.
  37. A. Biffis, N. Orlandi and B. Corain, Adv. Mater., 2003, 15, 1551–1555 CrossRef CAS.
  38. B. Devadas, M. Prokop, S. Duraisamy and K. Bouzek, Electrochim. Acta, 2023, 441, 141737 CrossRef CAS.
  39. X. Li, J. Iocozzia, Y. Chen, S. Zhao, X. Cui, W. Wang, H. Yu, S. Lin and Z. Lin, Angew. Chem., Int. Ed., 2018, 57, 2046–2070 CrossRef CAS PubMed.
  40. W. Zhan, Y. Shu, Y. Sheng, H. Zhu, Y. Guo, L. Wang, Y. Guo, J. Zhang, G. Lu and S. Dai, Angew. Chem., Int. Ed., 2017, 56, 4494–4498 CrossRef CAS PubMed.
  41. M. Arif, M. Shahid, A. Irfan, X. Wang, H. Noor, Z. H. Farooqi and R. Begum, Inorg. Chem. Commun., 2022, 144, 109870 CrossRef CAS.
  42. M. Arif, Mater. Today Commun., 2023, 36, 106580 CrossRef CAS.
  43. M. Arif, M. Shahid, A. Irfan, J. Nisar, W. Wu, Z. H. Farooqi and R. Begum, RSC Adv., 2022, 12, 5105–5117 RSC.
  44. Z. Zhai, Q. Wu, J. Li, B. Zhou, J. Shen, Z. H. Farooqi and W. Wu, J. Catal., 2019, 369, 462–468 CrossRef CAS.
  45. M. Arif, Z. H. Farooqi, A. Irfan and R. Begum, J. Mol. Liq., 2021, 336, 116270 CrossRef CAS.
  46. S. Ashraf, R. Begum, R. Rehan, W. Wu and Z. H. Farooqi, J. Inorg. Organomet. Polym. Mater., 2018, 28, 1872–1884 CrossRef CAS.
  47. R. Chen, J. Shi, C. Liu, J. Li and S. Cao, Adv. Compos. Hybrid Mater., 2022, 5, 2223–2234 CrossRef CAS.
  48. S. Wang, A. Wang, Y. Ma, Q. Han, Y. Chen, X. Li, S. Wu, J. Li, S. Bai and J. Yin, Biomater. Sci., 2021, 9, 774–779 RSC.
  49. F. Rastegar and M. Fallahi-Samberan, Mater. Chem. Phys., 2024, 316, 129042 CrossRef CAS.
  50. M. Arif, M. Shahid, A. Irfan, J. Nisar, X. Wang, N. Batool, M. Ali, Z. H. Farooqi and R. Begum, Z. Phys. Chem., 2022, 236, 1219–1241 CrossRef CAS.
  51. M. Shahid, Z. H. Farooqi, R. Begum, M. Arif, M. Azam, A. Irfan and U. Farooq, Z. Phys. Chem., 2022, 236, 87–105 CrossRef CAS.
  52. M. Arif, H. Raza and S. M. Haroon, JOM, 2023, 75, 5217–5234 CrossRef CAS.
  53. M. Arif, RSC Adv., 2022, 12, 15447–15460 RSC.
  54. K. Naseem, R. Begum and Z. H. Farooqi, Polym. Compos., 2018, 39, 2167–2180 CrossRef CAS.
  55. R. Begum, K. Naseem and Z. H. Farooqi, J. Sol–Gel Sci. Technol., 2016, 77, 497–515 CrossRef CAS.
  56. G. Mustafa, P. Ghosh Roy, S. Zhou, A. Irfan, A. R. Chaudhry, R. Begum and Z. H. Farooqi, J. Mol. Liq., 2023, 385, 122397 CrossRef CAS.
  57. K. Chang, Y. Yan, D. Zhang, Y. Xia, X. Chen, L. Lei and S. Shi, Langmuir, 2023, 39, 2408–2421 CrossRef CAS PubMed.
  58. K. Naseem, R. Begum, Z. H. Farooqi, W. Wu and A. Irfan, Appl. Organomet. Chem., 2020, 34, e5742 CrossRef CAS.
  59. A. Ahmad, P. G. Roy, S. Zhou, A. Irfan, F. Kanwal, R. Begum and Z. H. Farooqi, Int. J. Biol. Macromol., 2023, 240, 124401 CrossRef CAS PubMed.
  60. X. Wang, X. Guo, M. A. Cohen Stuart, J. Wang and P. Ding, Polymers, 2023, 15, 1935 CrossRef CAS PubMed.
  61. M. Arif, RSC Adv., 2023, 13, 3008–3019 RSC.
  62. X. Xu, R. M. Sarhan, S. Mei, Z. Kochovski, W. Koopman, R. D. Priestley and Y. Lu, ACS Appl. Mater. Interfaces, 2023, 15, 48623–48631 CrossRef CAS PubMed.
  63. A. Haleem, S. B. Syaal, M. Ajmal, J. Ambreen, S. Rauf, N. Ali, S. Muhammad, A. Shah, M. A. Zia and M. Siddiq, Korean J. Chem. Eng., 2020, 37, 614–622 CrossRef CAS.
  64. P. Agnihotri and A. Dan, ACS Appl. Nano Mater., 2022, 5, 10504–10515 CrossRef CAS.
  65. B. Wang, L. Dai, G. Yang, G. Bendrich, Y. Ni and G. Fang, Carbohydr. Polym., 2019, 226, 115289 CrossRef CAS PubMed.
  66. S. Mizuno, T.-A. Asoh, Y. Takashima, A. Harada and H. Uyama, Chem. Commun., 2020, 56, 14408–14411 RSC.
  67. A. M. Atta, A. K. Gafer, H. A. Al-Lohedan, M. M. S. Abdullah, A. M. Tawfeek and A. O. Ezzat, Molecules, 2019, 24, 3867 CrossRef CAS PubMed.
  68. X. Zhou, F. Chen, H. Lu, L. Kong, S. Zhang, W. Zhang, J. Nie, B. Du and X. Wang, Ind. Eng. Chem. Res., 2019, 58, 10922–10930 CrossRef CAS.
  69. T. Hou, S. S. Sana, D. V. Kumbhakar, H. Li, V. K. N. Boya, M. Aly Saad Aly, Z. Zhang and T. D. Pham, J. Drug Delivery Sci. Technol., 2023, 87, 104799 CrossRef CAS.
  70. K. Seku, G. Bhagavanth Reddy, S. S. Hussaini, B. Pejjai, M. Hussain, D. M. Reddy, M. A. K. Khazaleh and G. Mangatayaru, Int. J. Biol. Macromol., 2022, 209, 912–922 CrossRef CAS PubMed.
  71. B. Mutharani, P. Ranganathan, S.-M. Chen and C. Karuppiah, Microchim. Acta, 2019, 186, 167 CrossRef PubMed.
  72. Y. Tang, Y. Ding, T. Wu, L. Lv and Z. Yan, Sens. Actuators, B, 2016, 228, 767–773 CrossRef CAS.
  73. G.-F. Gui, Y. Zhuo, Y.-Q. Chai, Y. Xiang and R. Yuan, Biosens. Bioelectron., 2016, 77, 7–12 CrossRef CAS PubMed.
  74. P. Bhol and P. S. Mohanty, J. Phys.: Condens. Matter, 2020, 33, 084002 CrossRef PubMed.
  75. L. Tzounis, M. Doña, J. M. Lopez-Romero, A. Fery and R. Contreras-Caceres, ACS Appl. Mater. Interfaces, 2019, 11, 29360–29372 CrossRef CAS PubMed.
  76. M. Ajmal, M. Siddiq, N. Aktas and N. Sahiner, RSC Adv., 2015, 5, 43873–43884 RSC.
  77. F. Bibi, M. Ajmal, F. Naseer, Z. H. Farooqi and M. Siddiq, Int. J. Environ. Sci. Technol., 2017, 15, 863–874 CrossRef.
  78. H. Cai, X. Dai, X. Wang, P. Tan, L. Gu, Q. Luo, X. Zheng, Z. Li, H. Zhu, H. Zhang, Z. Gu, Q. Gong and K. Luo, Adv. Sci., 2020, 7, 1903243 CrossRef CAS.
  79. M. Arif, J. Mol. Liq., 2023, 375, 121346 CrossRef CAS.
  80. C. Alarcón-Fernández, M. Doña, A. Tapia-Fernández, G. Villaverde, M. R. Lopez-Ramirez, J. M. López-Romero and R. Contreras-Caceres, ACS Appl. Nano Mater., 2020, 3, 8247–8256 CrossRef.
  81. M. Wei and M. J. Serpe, Part. Part. Syst. Charact., 2019, 36, 1800326 CrossRef.
  82. L. Li, R. Niu and Y. Zhang, RSC Adv., 2018, 8, 12428–12438 RSC.
  83. B. Tadgell, E. Ponomareva, M. Karg and P. Mulvaney, J. Phys. Chem. C, 2022, 126, 15336–15347 CrossRef CAS.
  84. T. Ye, X. Jiang, W. Xu, M. Zhou, Y. Hu and W. Wu, Polym. Chem., 2014, 5, 2352–2362 RSC.
  85. K. Rajar and E. Alveroglu, J. Mol. Struct., 2017, 1146, 592–599 CrossRef CAS.
  86. M. Zhang and W. Zhang, J. Phys. Chem. C, 2008, 112, 6245–6252 CrossRef CAS.
  87. K. Naseem, Z. H. Farooqi, R. Begum, W. Wu, A. Irfan and A. G. Al-Sehemi, Macromol. Chem. Phys., 2018, 219, 1800211 CrossRef.
  88. I. Hussain, M. Shahid, F. Ali, A. Irfan, R. Begum and Z. H. Farooqi, Environ. Technol., 2023, 44, 1679–1689 CrossRef CAS.
  89. Y. Lu, J. Yuan, F. Polzer, M. Drechsler and J. Preussner, ACS Nano, 2010, 4, 7078–7086 CrossRef CAS.
  90. P. Boonying, S. Martwiset and S. Amnuaypanich, Appl. Nanosci., 2018, 8, 475–488 CrossRef CAS.
  91. K. Naseem, R. Begum, W. Wu, A. Irfan, A. G. Al-Sehemi and Z. H. Farooqi, J. Cleaner Prod., 2019, 211, 855–864 CrossRef CAS.
  92. Y. Lu, S. Proch, M. Schrinner, M. Drechsler, R. Kempe and M. Ballauff, J. Mater. Chem., 2009, 19, 3955–3961 RSC.
  93. N. Tan, C. Lee and P. Li, Polymers, 2016, 8, 105 CrossRef.
  94. T. Zhang, L. Li, Z. Ye, Q. Yang, Y. Tian and X. Guo, RSC Adv., 2018, 8, 18252–18259 RSC.
  95. B. Hu, T. Wu, K. Ding, X. Zhou, T. Jiang and B. Han, J. Phys. Chem. C, 2010, 114, 3396–3400 CrossRef CAS.
  96. G. Liu, D. Wang, F. Zhou and W. Liu, Small, 2015, 11, 2807–2816 CrossRef CAS.
  97. A. Mohan, J. Peter, L. Rout, A. M. Thomas, S. Nagappan, S. Parambadath, W. Zhang, M. Selvaraj and C.-S. Ha, Colloids Surf., A, 2021, 611, 125846 CrossRef CAS.
  98. M. R. Nabid, Y. Bide and M. Niknezhad, ChemCatChem, 2014, 6, 538–546 CrossRef CAS.
  99. J. Yang, D. Wang, W. Liu, X. Zhang, F. Bian and W. Yu, Green Chem., 2013, 15, 3429–3437 RSC.
  100. N. Sahiner and A. O. Yasar, Fuel Process. Technol., 2016, 144, 124–131 CrossRef CAS.
  101. Y. Mei, Y. Lu, F. Polzer, M. Ballauff and M. Drechsler, Chem. Mater., 2007, 19, 1062–1069 CrossRef CAS.
  102. R. J. Rauschendorfer, K. M. Whitham, S. Summer, S. A. Patrick, A. E. Pierce, H. Sefi-Cyr, S. Tadjiki, M. D. Kraft, S. R. Emory, D. A. Rider and M. D. Montaño, Front. Toxicol., 2021, 3, 1–14 Search PubMed.
  103. T. Kureha, Y. Nagase and D. Suzuki, ACS Omega, 2018, 3, 6158–6165 CrossRef CAS.
  104. D. Suzuki and H. Kawaguchi, Langmuir, 2005, 21, 12016–12024 CrossRef CAS.
  105. T. Curtis, A. K. Taylor, S. E. Alden, C. Swanson, J. Lo, L. Knight, A. Silva, B. D. Gates, S. R. Emory and D. A. Rider, ACS Omega, 2018, 3, 10572–10588 CrossRef CAS.
  106. M. Bradley and B. S. Garcia-Risueño, J. Colloid Interface Sci., 2011, 355, 321–327 CrossRef CAS.
  107. M. Karg, I. Pastoriza-Santos, J. Pérez-Juste, T. Hellweg and L. M. Liz-Marzán, Small, 2007, 3, 1222–1229 CrossRef CAS.
  108. J. E. Wong, A. K. Gaharwar, D. Müller-Schulte, D. Bahadur and W. Richtering, J. Colloid Interface Sci., 2008, 324, 47–54 CrossRef CAS.
  109. M. Karg, Y. Lu, E. Carbó-Argibay, I. Pastoriza-Santos, J. Pérez-Juste, L. M. Liz-Marzán and T. Hellweg, Langmuir, 2009, 25, 3163–3167 CrossRef CAS.
  110. S. Mohammed Safiullah, K. Abdul Wasi and K. Anver Basha, Appl. Surf. Sci., 2015, 357, 112–121 CrossRef CAS.
  111. J. Su, S. Wang, Z. Xu, G. Wu, L. Wang and X. Huang, Chem. Commun., 2019, 55, 10760–10763 RSC.
  112. A. C. Manikas, A. Papa, F. Causa, G. Romeo and P. A. Netti, RSC Adv., 2015, 5, 13507–13512 RSC.
  113. X. He, Z. Liu, F. Fan, S. Qiang, L. Cheng and W. Yang, J. Nanopart. Res., 2015, 17, 74 CrossRef.
  114. G. Li, X. Yang, B. Wang, J. Wang and X. Yang, Polymer, 2008, 49, 3436–3443 CrossRef CAS.
  115. R. Begum, K. Naseem, E. Ahmed, A. Sharif and Z. H. Farooqi, Colloids Surf., A, 2016, 511, 17–26 CrossRef CAS.
  116. S. Iqbal, N. Iqbal, S. Musaddiq, Z. H. Farooqi, M. A. Habila, S. M. Wabaidur and A. Iqbal, Heliyon, 2024, 10, E25385 CrossRef CAS.
  117. M. Riaz, M. Ajmal, A. Naseem, N. Jabeen, Z. H. Farooqi, K. Mahmood, A. Ali, L. Rasheed and A. N. S. Saqib, Z. Phys. Chem., 2022, 236, 1441–1460 CrossRef CAS.
  118. Z. H. Farooqi, H. Sultana, R. Begum, M. Usman, M. Ajmal, J. Nisar, A. Irfan and M. Azam, Int. J. Environ. Anal. Chem., 2022, 102, 4104–4120 CrossRef CAS.
  119. J. Ambreen, F. F. Al-Harbi, H. Sakhawat, M. Ajmal, H. Naeem, Z. H. Farooqi, N. Batool and M. Siddiq, J. Mol. Liq., 2022, 355, 118931 CrossRef CAS.
  120. A. Yoshida, Y. Kitayama, K. Kiguchi, T. Yamada, H. Akasaka, R. Sasaki and T. Takeuchi, ACS Appl. Bio Mater., 2019, 2, 1177–1183 CrossRef CAS.
  121. A. Contin, A. Biffis, S. Sterchele, K. Dörmbach, S. Schipmann and A. Pich, J. Colloid Interface Sci., 2014, 414, 41–45 CrossRef CAS.
  122. S. Li, X. Wang, J. Chen, J. Guo, M. Yuan, G. Wan, C. Yan, W. Li, H.-G. Machens, Y. Rinkevich, X. Yang, H. Song and Z. Chen, Int. J. Biol. Macromol., 2022, 202, 657–670 CrossRef CAS.
  123. T. M. Ansari, M. Ajmal, S. Saeed, H. Naeem, H. B. Ahmad, K. Mahmood and Z. H. Farooqi, J. Iran. Chem. Soc., 2019, 16, 2765–2776 CrossRef CAS.
  124. S. Rahman, F. F. Al-Harbi, M. Ajmal, A. Naseem, Z. H. Farooqi and M. Siddiq, J. Mater. Sci., 2022, 57, 6763–6779 CrossRef CAS.
  125. A. M. Al-Enizi, T. Ahamad, A. B. Al-hajji, J. Ahmed, A. A. Chaudhary and S. M. Alshehri, Int. J. Biol. Macromol., 2018, 109, 803–809 CrossRef CAS.
  126. J. T. Zhang, G. Wei, T. F. Keller, H. Gallagher, C. Stötzel, F. A. Müller, M. Gottschaldt, U. S. Schubert and K. D. Jandt, Macromol. Mater. Eng., 2010, 295, 1049–1057 CrossRef CAS.
  127. X. Liu, C. Zhang, J. Yang, D. Lin, L. Zhang, X. Chen and L. Zha, RSC Adv., 2013, 3, 3384–3390 RSC.
  128. X.-J. Zhou, H.-P. Lu, L.-L. Kong, D. Zhang, W. Zhang, J.-J. Nie, J.-Y. Yuan, B.-Y. Du and X.-P. Wang, Chin. J. Polym. Sci., 2019, 37, 235–242 CrossRef CAS.
  129. F. Naseer, M. Ajmal, F. Bibi, Z. H. Farooqi and M. Siddiq, Polym. Compos., 2018, 39, 3187–3198 CrossRef CAS.
  130. T. Nakao, D. Nagao, H. Ishii and M. Konno, Colloids Surf., A, 2014, 446, 134–138 CrossRef CAS.
  131. Z. Shafiq, M. Ajmal, S. Kiran, S. Zulfiqar, G. Yasmeen, M. Iqbal, Z. H. Farooqi, Z. Ahmad, N. Sahiner, K. Mahmood, H. B. Ahmad and A. Al-Harrasi, Pure Appl. Chem., 2019, 91, 1567–1582 CrossRef CAS.
  132. S. Sharma, Deepak, A. Kumar, S. Afgan and R. Kumar, ChemistrySelect, 2017, 2, 11281–11287 CrossRef CAS.
  133. S. Iqbal, S. Musaddiq, R. Begum, A. Irfan, Z. Ahmad, M. Azam, J. Nisar and Z. H. Farooqi, Z. Phys. Chem., 2021, 235, 1701–1719 CrossRef CAS.
  134. S. ur Rehman, M. Siddiq, H. Al-Lohedan and N. Sahiner, Chem. Eng. J., 2015, 265, 201–209 CrossRef CAS.
  135. B. Mutharani, T.-W. Chen, S.-M. Chen and X. Liu, Sens. Actuators, B, 2020, 316, 128103 CrossRef CAS.
  136. K. Wiemer, K. Dörmbach, I. Slabu, G. Agrawal, F. Schrader, T. Caumanns, S. D. M. Bourone, J. Mayer, J. Steitz, U. Simon and A. Pich, J. Mater. Chem. B, 2017, 5, 1284–1292 RSC.
  137. N. A. Nemygina, L. Z. Nikoshvili, I. Y. Tiamina, A. V. Bykov, I. S. Smirnov, T. Lagrange, Z. Kaszkur, V. G. Matveeva, E. M. Sulman and L. Kiwi-Minsker, Org. Process Res. Dev., 2018, 22, 1606–1613 CrossRef CAS.
  138. S. Afridi, L. A. Shah, M. Khan, S. A. Khan and D. Ye, Polym. Bull., 2023, 80, 8259–8281 CrossRef CAS.
  139. M. U. Kakar, K. Khan, M. Akram, R. Sami, E. Khojah, I. Iqbal, M. Helal, A. Hakeem, Y. Deng and R. Dai, Sci. Rep., 2021, 11, 14759 CrossRef CAS.
  140. M. N. Nadagouda and R. S. Varma, Macromol. Rapid Commun., 2007, 28, 465–472 CrossRef CAS.
  141. N. Sahiner, Colloid Polym. Sci., 2006, 285, 283–292 CrossRef CAS.
  142. A. Basu, I. Tolbatov, A. Marrone, A. Vaskevich and L. Chuntonov, J. Phys. Chem. C, 2024, 128, 3438–3448 CrossRef CAS.
  143. M. Chen, G. Bolognesi, R. Begum, Z. H. Farooqi and G. T. Vladisavljević, Emergent Mater., 2024, 1–13 Search PubMed.
  144. S. Bandyopadhyay, A. Sharma and W. Glomm, Gels, 2017, 3, 42 CrossRef.
  145. S. Zahid, A. K. Alzahrani, N. Kizilbash, J. Ambreen, M. Ajmal, Z. H. Farooqi and M. Siddiq, RSC Adv., 2022, 12, 33215–33228 RSC.
  146. H. Naeem, M. Ajmal, S. Z. Khan, M. N. Ashiq and M. Siddiq, Soft Mater., 2021, 19, 480–494 CrossRef CAS.
  147. N. Jabeen, Z. H. Farooqi, A. Shah, A. Ali, M. Khurram, K. Mahmood, N. Sahiner and M. Ajmal, J. Porous Mater., 2021, 1, 1–14 Search PubMed.
  148. Z. H. Farooqi, S. Iqbal, S. R. Khan, F. Kanwal and R. Begum, e-Polymers, 2014, 14, 313–321 CAS.
  149. R. Begum, Z. H. Farooqi, J. Xiao, E. Ahmed, A. Sharif and A. Irfan, J. Mol. Liq., 2021, 338, 116780 CrossRef CAS.
  150. M. Tercan, S. De Mirci, O. Dayan and N. Sahiner, New J. Chem., 2020, 44, 4417–4425 RSC.
  151. R. Begum, Z. H. Farooqi, A. H. Aboo, E. Ahmed, A. Sharif and J. Xiao, J. Hazard. Mater., 2019, 377, 399–408 CrossRef CAS.
  152. L. A. Shah, M. Sayed and M. Siddiq, Mater. Sci.–Pol., 2017, 35, 651–659 CrossRef CAS.
  153. G. Youzhi, H. Yang, Z. Yiping, C. Li and Y. Fanyong, J. Mater. Sci., 2016, 51, 3200–3210 CrossRef CAS.
  154. M. Ajmal, S. Demirci, M. Siddiq, N. Aktas and N. Sahiner, New J. Chem., 2016, 40, 1485–1496 RSC.
  155. T. Chen, Q. Fang, L. Zhou, Z. Xu, J. Qiu, M. Wang and J. Wang, React. Funct. Polym., 2019, 142, 104–111 CrossRef CAS.
  156. M. Ajmal, M. Siddiq, H. Al-Lohedan and N. Sahiner, RSC Adv., 2014, 4, 59562–59570 RSC.
  157. Y. Meng, J. Yin, T. Jiao, J. Bai, L. Zhang, J. Su, S. Liu, Z. Bai, M. Cao and Q. Peng, J. Mol. Liq., 2020, 298, 112010 CrossRef CAS.
  158. O. Ramírez, S. Bonardd, C. Saldías, Y. Zambrano, D. D. Díaz and A. Leiva, Carbohydr. Polym., 2022, 297, 120021 CrossRef.
  159. R. Contreras-Caceres, P. Alonso-Cristobal, D. Mendez-Gonzalez, M. Laurenti, A. Maldonado-Valdivia, F. Garcia-Blanco, E. López Cabarcos, A. Fernandez-Barbero, J. M. Lopez-Romero and J. Rubio-Retama, Langmuir, 2014, 30, 15560–15567 CrossRef CAS.
  160. M. E. Villanueva, A. M. D. R. Diez, J. A. González, C. J. Pérez, M. Orrego, L. Piehl, S. Teves and G. J. Copello, ACS Appl. Mater. Interfaces, 2016, 8, 16280–16288 CrossRef CAS.
  161. M. Wei and M. J. Serpe, Part. Part. Syst. Charact., 2019, 36, 1800326 CrossRef.
  162. K. Virk, K. Sharma, S. Kapil, V. Kumar, V. Sharma, S. Pandey and V. Kumar, J. Polym. Res., 2022, 29, 1–15 CrossRef.
  163. E. M. Bakhsh, M. S. J. Khan, K. Akhtar, S. B. Khan and A. M. Asiri, Appl. Organomet. Chem., 2022, 36, e6741 CrossRef CAS.
  164. J. Ding, Q. Li, X. Xu, X. Zhang, Y. Su, Q. Yue and B. Gao, Carbohydr. Polym., 2018, 190, 12–22 CrossRef CAS.
  165. P. Gu, J. Wang, P. Müller-Buschbaum, D. Qi and Q. Zhong, ACS Appl. Mater. Interfaces, 2020, 12, 34180–34189 CrossRef CAS.
  166. Z. Chen, L. Hu and M. J. Serpe, J. Mater. Chem., 2012, 22, 20998–21002 RSC.
  167. W. Liu, H. Cai, P. Lu, Q. Xu, Y. Zhongfu and J. Dong, Int. J. Hydrogen Energy, 2013, 38, 9206–9216 CrossRef CAS.
  168. A. Gibb, A. Vorobjovs, Z. Jagoda, J. Winiarski and A. Stankiewicz, Trans. IMF, 2020, 98, 15–20 CrossRef CAS.
  169. Z. H. Farooqi and M. Siddiq, J. Dispersion Sci. Technol., 2015, 36, 423–429 CrossRef CAS.
  170. X. Dong, S. Chen, J. Zhou, L. Wang and L. Zha, Mater. Des., 2016, 104, 303–311 CrossRef CAS.
  171. B. Li, X. Chen, K. Li, C. Zhang, Y. He, R. Du, J. Wang and L. Chen, J. Ind. Eng. Chem., 2019, 78, 198–209 CrossRef CAS.
  172. N. Sahiner and S. Yildiz, Fuel Process. Technol., 2014, 126, 324–331 CrossRef CAS.
  173. Y. Gotoh, R. Igarashi, Y. Ohkoshi, M. Nagura, K. Akamatsu and S. Deki, J. Mater. Chem., 2000, 10, 2548–2552 RSC.
  174. H. Park, L. Srisombat, A. Jamison, T. Liu, M. Marquez, H. Park, S. Lee, T.-C. Lee and T. Lee, Gels, 2018, 4, 28 CrossRef.
  175. F. Mou, C. Chen, Q. Zhong, Y. Yin, H. Ma and J. Guan, ACS Appl. Mater. Interfaces, 2014, 6, 9897–9903 CrossRef CAS.
  176. A. Saad, R. Mills, H. Wan, L. Ormsbee and D. Bhattacharyya, Ind. Eng. Chem. Res., 2020, 59, 16614–16625 CrossRef CAS.
  177. E. Menard, K. J. Lee, D. Khang, R. G. Nuzzo, J. A. Rogers, A. Rogers, Z. Bao, K. Baldwin, A. Dodabalapur, B. Crone, V. R. Raju, V. Kuck, H. Katz, K. Amundson, J. Ewing, P. Drzaic, G. Kane, J. Campi, M. S. Hammond, F. P. Cuomo, B. Greening, C. D. Sheraw, J. A. Nichols, D. J. Gundlach, J. R. Huang, C. C. Kuo, L. Jia, H. Klauk, T. N. Jackson, E. Burns, C. Kuhn, K. Jacobs, J. D. Mackenzie, C. Ramsdale, A. C. Arias, J. Watts, M. Etchells, K. Chalmers, P. Devine, N. Murton, S. Norval, J. King, J. Mills, H. Sirringhaus, R. H. Friend, J. Soc Inf, B. Jiguang Zhang, S. Xu, E. Kumacheva, E. Kumacheva, J. Zhang and S. Xu, Adv. Mater., 2005, 17, 2336–2340 CrossRef.
  178. S. Pourbeyram and S. Mohammadi, J. Non-Cryst. Solids, 2014, 402, 58–63 CrossRef CAS.
  179. M. Ajmal, F. Aftab, I. Bibi, M. Iqbal, J. Ambreen, H. B. Ahmad, N. Akhtar, A. Haleem and M. Siddiq, J. Porous Mater., 2019, 26, 281–290 CrossRef CAS.
  180. O. Ozay, N. Aktas, E. Inger and N. Sahiner, Int. J. Hydrogen Energy, 2011, 36, 1998–2006 CrossRef CAS.
  181. N. Sahiner, Colloids Surf., A, 2013, 433, 212–218 CrossRef CAS.
  182. B. Li, X. Chen, Y. Ma, J. Wang, X. Zhai, Y. He, Y. Li, R. Ma and W. Zhang, J. Environ. Chem. Eng., 2021, 9, 104757 CrossRef CAS.
  183. Y. Tang, T. Wu, B. Hu, Q. Yang, L. Liu, B. Yu, Y. Ding and S. Ye, Mater. Chem. Phys., 2015, 149–150, 460–466 CrossRef CAS.
  184. L. Y. Chen, C. M. Ou, W. Y. Chen, C. C. Huang and H. T. Chang, ACS Appl. Mater. Interfaces, 2013, 5, 4383–4388 CrossRef CAS.
  185. Y.-Y. Liu, X.-Y. Liu, J.-M. Yang, D.-L. Lin, X. Chen and L.-S. Zha, Colloids Surf., A, 2012, 393, 105–110 CrossRef CAS.
  186. A. Sánchez-Iglesias, M. Grzelczak, B. Rodríguez-González, P. Guardia-Girós, I. Pastoriza-Santos, J. Pérez-Juste, M. Prato and L. M. Liz-Marzán, ACS Nano, 2009, 3, 3184–3190 CrossRef.
  187. K. Khan, A. J. Shaikh, M. Siddiq, T. A. Sherazi and M. Nawaz, J. Polym. Eng., 2016, 36, 287–292 CrossRef CAS.
  188. C. Fernández-López, L. Polavarapu, D. M. Solís, J. M. Taboada, F. Obelleiro, R. Contreras-Cáceres, I. Pastoriza-Santos and J. Pérez-Juste, ACS Appl. Mater. Interfaces, 2015, 7, 12530–12538 CrossRef.
  189. V. Sabadasch, L. Wiehemeier, T. Kottke and T. Hellweg, Soft Matter, 2020, 16, 5422–5430 RSC.
  190. A. C. Manikas, A. Aliberti, F. Causa, E. Battista and P. A. Netti, J. Mater. Chem. B, 2015, 3, 53–58 RSC.
  191. V. K. Saruchi, J. K. Dhami, V. Rehani and M. Singh, J. Polym. Res., 2022, 29, 1–14 CrossRef.
  192. H. Zhang, S. Guo, S. Fu and Y. Zhao, Polymers, 2017, 9, 238 CrossRef.
  193. J. Liu, J. Wang, Y. Wang, C. Liu, M. Jin, Y. Xu, L. Li, X. Guo, A. Hu, T. Liu, S. F. Lincoln and R. K. Prud'homme, Colloids Interface Sci. Commun., 2015, 4, 1–4 CrossRef.
  194. J. Machotová, J. Šňupárek, L. Prokůpek, T. Rychlý and P. Vlasák, Prog. Org. Coat., 2008, 63, 175–181 CrossRef.
  195. Q. Chen, K. Xu, W. Zhang, C. Song and P. Wang, Colloid Polym. Sci., 2009, 287, 1339–1346 CrossRef CAS.
  196. O. Güven, S. Demirci, S. D. Sütekin, B. Ari and N. Sahiner, Radiat. Phys. Chem., 2022, 198, 110217 CrossRef.
  197. Z. H. Farooqi, Z. Butt, R. Begum, S. R. Khan, A. Sharif and E. Ahmed, Mater. Sci.–Pol., 2015, 33, 627–634 CrossRef.
  198. Y. Dong, Y. Jin, J. Wang, J. Shu and M. Zhang, Chem. Eng. J., 2017, 324, 303–312 CrossRef CAS.
  199. N. Sahiner and A. O. Yasar, Int. J. Hydrogen Energy, 2013, 38, 6736–6743 CrossRef CAS.
  200. R. Vescovo, M. Becker, M. M. Natile, P. Canton, C. Evangelisti and A. Biffis, ACS Appl. Nano Mater., 2021, 4, 8343–8351 CrossRef CAS.
  201. S. Wang, Y. Mo, T. Vincent, J. C. Roux, E. Rodríguez-Castellón, C. Faur and E. Guibal, J. Mater. Sci., 2020, 55, 2032–2051 CrossRef CAS.
  202. M. R. Nabid, Y. Bide, E. Aghaghafari and S. J. T. Rezaei, Catal. Lett., 2014, 144, 355–363 CrossRef CAS.
  203. N. S. Reddy, S. Eswaramma, I. Chung, K. S. V. K. Rao, P. Ramesh and A. Chandra Sekhar, Int. J. Polym. Mater. Polym. Biomater., 2019, 68, 870–880 CrossRef CAS.
  204. J. Cao, J. Li, Y. Chen, L. Zhang and J. Zhou, Adv. Funct. Mater., 2018, 28, 1800739 CrossRef.
  205. Y. Zheng, F. Cheng and W. He, Colloids Surf., A, 2019, 575, 94–101 CrossRef CAS.
  206. J. Zhang, N. Ma, F. Tang, Q. Cui, F. He and L. Li, ACS Appl. Mater. Interfaces, 2012, 4, 1747–1751 CrossRef CAS.
  207. W. Wu, J. Shen, Y. Li, H. Zhu, P. Banerjee and S. Zhou, Biomaterials, 2012, 33, 7115–7125 CrossRef CAS.
  208. W. Wu, N. Mitra, E. C. Y. Yan and S. Zhou, ACS Nano, 2010, 4, 4831–4839 CrossRef CAS.
  209. Y. Zhang, Y. Zhang, K. Liu and Y. Guan, RSC Adv., 2012, 2, 4768–4776 RSC.
  210. Y. Zuo, J. Zhao, Y. Gao and Y. Zhang, J. Mater. Sci., 2017, 52, 9584–9601 CrossRef CAS.
  211. M. S. Strozyk, M. Chanana, I. Pastoriza-Santos, J. Pérez-Juste and L. M. Liz-Marzán, Adv. Funct. Mater., 2012, 22, 1436–1444 CrossRef CAS.
  212. R. Javed, L. A. Shah, M. Sayed and M. S. Khan, RSC Adv., 2018, 8, 14787–14797 RSC.
  213. M. Ajmal, S. Demirci, M. Siddiq, N. Aktas and N. Sahiner, Colloids Surf., A, 2015, 486, 29–37 CrossRef CAS.
  214. M. Das, N. Sanson and E. Kumacheva, Chem. Mater., 2008, 20, 7157–7163 CrossRef CAS.
  215. S. R. Khan, S. Ali, B. Ullah, S. Jamil and T. Zanib, J. Nanopart. Res., 2020, 22, 1–12 CrossRef.
  216. S. Iqbal, C. Zahoor, S. Musaddiq, M. Hussain, R. Begum, A. Irfan, M. Azam and Z. H. Farooqi, Ecotoxicol. Environ. Saf., 2020, 202, 110924 CrossRef CAS.
  217. P. Bhol, M. Mohanty and P. S. Mohanty, J. Mol. Liq., 2021, 325, 115135 CrossRef CAS.
  218. X. Chen, Y. An, D. Zhao, Z. He, Y. Zhang, J. Cheng and L. Shi, Langmuir, 2008, 24, 8198–8204 CrossRef CAS.
  219. M. Bradley and B. Vincent, Langmuir, 2008, 24, 2421–2425 CrossRef CAS.
  220. Y. M. Liu, X. J. Ju, Y. Xin, W. C. Zheng, W. Wang, J. Wei, R. Xie, Z. Liu and L. Y. Chu, ACS Appl. Mater. Interfaces, 2014, 6, 9530–9542 CrossRef CAS.
  221. Y. Wang, N. Lin, Y. Gong, R. Wang and X. Zhang, Chemosphere, 2021, 280, 130663 CrossRef CAS.
  222. A. Wang, Z. Liu, S. Li, Y. Liu, H. Zhao, Y. Liu, T. Ye, Y. Niu and W. Li, J. Mol. Liq., 2021, 342, 117572 CrossRef CAS.
  223. J. Paul Guin, Y. K. Bhardwaj and L. Varshney, J. Appl. Polym. Sci., 2018, 135, 46200 CrossRef.
  224. Q. Zhou, M. Lei, Y. Wu, S. Li, Y. Tong, Z. Li, M. Liu, L. Guo and C. Chen, Chemosphere, 2021, 279, 130584 CrossRef CAS.
  225. S. Demirci, K. Sel and N. Sahiner, Sep. Purif. Technol., 2015, 155, 66–74 CrossRef CAS.
  226. S. Dhanavel, N. Manivannan, N. Mathivanan, V. K. Gupta, V. Narayanan and A. Stephen, J. Mol. Liq., 2018, 257, 32–41 CrossRef CAS.
  227. Z. Wang, X. Chen, K. Li, S. Bi, C. Wu and L. Chen, J. Membr. Sci., 2015, 496, 95–107 CrossRef CAS.
  228. N. Sahiner, S. Yildiz, M. Sahiner, Z. A. Issa and H. Al-Lohedan, Appl. Surf. Sci., 2015, 354, 388–396 CrossRef CAS.
  229. L. Zhao, Q. Li, Y. Su, Q. Yue and B. Gao, Int. J. Hydrogen Energy, 2017, 42, 6746–6756 CrossRef CAS.
  230. K. Naseem, A. Aziz, M. H. Tahir, A. Ameen, A. Ahmad, K. Ahmad, M. Arif, W. Hassan, J. Najeeb and E. Rao, Int. J. Environ. Sci. Technol., 2024, 21, 2163–2194 CrossRef CAS.
  231. T. Brändel, V. Sabadasch, Y. Hannappel and T. Hellweg, ACS Omega, 2019, 4, 4636–4649 CrossRef.
  232. Y. Dong, Y. Ma, T. Zhai, F. Shen, Y. Zeng, H. Fu and J. Yao, Macromol. Rapid Commun., 2007, 28, 2339–2345 CrossRef CAS.
  233. E. Wi, S. Go, S. Y. Shin, H. J. Cheon, G. Jeong, H. Cheon, J. Kim, H. R. Jung, H. Kim and M. Chang, Chem. Eng. J., 2023, 454, 140309 CrossRef CAS.
  234. C. Xiao, Q. Wu, A. Chang, Y. Peng, W. Xu and W. Wu, J. Mater. Chem. A, 2014, 2, 9514–9523 RSC.
  235. G. Kocak, J. Appl. Polym. Sci., 2020, 137, 48360 CrossRef CAS.
  236. N. Sahiner, O. Ozay, N. Aktas, E. Inger and J. He, Int. J. Hydrogen Energy, 2011, 36, 15250–15258 CrossRef CAS.
  237. H. Ozay, P. Ilgin and O. Ozay, Int. J. Hydrogen Energy, 2020, 45, 17613–17624 CrossRef CAS.
  238. H. Gholami Derami, P. Gupta, R. Gupta, P. Rathi, J. J. Morrissey and S. Singamaneni, ACS Appl. Nano Mater., 2020, 3, 5437–5448 CrossRef CAS.
  239. G. S. Tatykhanova, A. N. Klivenko, G. M. Kudaibergenova and S. E. Kudaibergenov, Macromol. Symp., 2016, 363, 49–56 CrossRef CAS.
  240. D. Ulker, C. Tuncer, S. B. Sezgin, Y. Toptas, A. Cabuk and V. Bütün, J. Polym. Res., 2017, 24, 169 CrossRef.
  241. T. Gancheva and N. Virgilio, ACS Appl. Mater. Interfaces, 2018, 10, 21073–21078 CrossRef CAS.
  242. P. Pongsanon, Y. Oota, A. Kawamura, H. Kawasaki and T. Miyata, Macromolecules, 2023, 56, 9853–9865 CrossRef CAS.
  243. I. Hussain, Z. H. Farooqi, F. Ali, R. Begum, A. Irfan, W. Wu, X. Wang, M. Shahid and J. Nisar, J. Mol. Liq., 2021, 335, 116106 CrossRef CAS.
  244. X. Zhang, X. Lv, T. Xie, Y. Cheng, J. Zhang and X. Xu, Eur. Polym. J., 2023, 200, 112533 CrossRef CAS.
  245. Z. H. Farooqi, R. Begum, K. Naseem, U. Rubab, M. Usman, A. Khan and A. Ijaz, Russ. J. Phys. Chem. A, 2016, 90, 2600–2608 CrossRef CAS.
  246. N. P. B. Tan and C. H. Lee, in Green Chemical Processing and Synthesis, InTech, 2017 Search PubMed.
  247. V. Melinte, L. Stroea, T. Buruiana and A. L. Chibac, Eur. Polym. J., 2019, 121, 109289 CrossRef CAS.
  248. M. Hashaam, S. Ali, T. Khan, M. Salman, S. R. Khan, A. I. Aqib, T. Zaheer, S. Bibi, S. Jamil, M. S. Al-Sharif, S. F. Mahmoud and W. Yao, Catalysts, 2022, 12, 1172 CrossRef CAS.
  249. A. Raza, S. Rauf Khan, S. Ali, S. Jamil and S. Bibi, Inorg. Chem. Commun., 2023, 153, 110851 CrossRef CAS.
  250. L. A. Shah, A. Haleem, M. Sayed and M. Siddiq, J. Environ. Chem. Eng., 2016, 4, 3492–3497 CrossRef CAS.
  251. X. Han, X. Chen, M. Yan and H. Liu, Particuology, 2019, 44, 63–70 CrossRef CAS.
  252. J. Cao, S. Mei, H. Jia, A. Ott, M. Ballauff and Y. Lu, Langmuir, 2015, 31, 9483–9491 CrossRef CAS.
  253. P. N. Eyimegwu, J. A. Lartey and J.-H. Kim, ACS Appl. Nano Mater., 2019, 2, 6057–6066 CrossRef CAS.
  254. M. Albino, T. J. Burden, C. C. Piras, A. C. Whitwood, I. J. S. Fairlamb and D. K. Smith, ACS Sustain. Chem. Eng., 2023, 11, 1678–1689 CrossRef CAS.
  255. M. C. Hong, H. Ahn, M. C. Choi, Y. Lee, J. Kim and H. Rhee, Appl. Organomet. Chem., 2014, 28, 156–161 CrossRef CAS.
  256. P. A. Pourjavadi, N. Keshavarzi, F. M. Moghaddam and S. H. Hosseini, ChemistrySelect, 2018, 3, 2716–2722 CrossRef CAS.
  257. D. Zhang, H. Li, J. Li, Z. Xu, H. Liu, Y. Zhao, X. Feng and L. Chen, Appl. Surf. Sci., 2020, 512, 145668 CrossRef CAS.
  258. F. Tang, N. Ma, L. Tong, F. He and L. Li, Langmuir, 2012, 28, 883–888 CrossRef CAS.
  259. D. M. Han, Q. M. Zhang and M. J. Serpe, Nanoscale, 2015, 7, 2784–2789 RSC.
  260. Y. Tang, Y. Cao, S. Wang, G. Shen and R. Yu, Sens. Actuators, B, 2009, 137, 736–740 CrossRef CAS.
  261. I. Gholamali, M. Asnaashariisfahani and E. Alipour, Regener. Eng. Transl. Med., 2020, 6, 138–153 CrossRef CAS.
  262. S. Batool, Z. Hussain, M. B. K. Niazi, U. Liaqat and M. Afzal, J. Drug Delivery Sci. Technol., 2019, 52, 403–414 CrossRef CAS.
  263. W. Wu, J. Shen, P. Banerjee and S. Zhou, Biomaterials, 2010, 31, 7555–7566 CrossRef CAS.
  264. W. Wu, J. Shen, P. Banerjee and S. Zhou, Biomaterials, 2011, 32, 598–609 CrossRef CAS.
  265. S. Mane, S. Ponrathnam and N. Chavan, Int. J. Polym. Mater., 2016, 65, 285–293 CrossRef CAS.
  266. I. O. de Solorzano, M. Prieto, G. Mendoza, V. Sebastian and M. Arruebo, Nanomedicine, 2020, 15, 219–234 CrossRef.
  267. N. S. V. Capanema, I. C. Carvalho, A. A. P. Mansur, S. M. Carvalho, A. P. Lage and H. S. Mansur, ACS Appl. Nano Mater., 2019, 2, 7393–7408 CrossRef CAS.
  268. A. Seyfoori, S. A. Seyyed Ebrahimi, E. Samiei and M. Akbari, ACS Appl. Mater. Interfaces, 2019, 11, 24945–24958 CrossRef CAS.
  269. M. C. Galdioli Pellá, A. R. Simão, M. K. Lima-Tenório, E. Tenório-Neto, D. B. Scariot, C. V. Nakamura and A. F. Rubira, Carbohydr. Polym., 2020, 239, 116236 CrossRef.
  270. A. Wang, J. Li, Q. Dong, S. Wang, H. Jian, M. Wang, P. Ren and S. Bai, ACS Appl. Mater. Interfaces, 2019, 11, 4408–4415 CrossRef CAS.
  271. A. Haleem, S. Q. Chen, M. Ullah, M. Siddiq and W. D. He, J. Environ. Chem. Eng., 2021, 9, 106510 CrossRef CAS.
  272. G. M. Raghavendra, T. Jayaramudu, K. Varaprasad, G. S. Mohan Reddy and K. M. Raju, RSC Adv., 2015, 5, 14351–14358 RSC.
  273. C. Marambio-Jones and E. M. V. Hoek, J. Nanopart. Res., 2010, 12, 1531–1551 CrossRef CAS.
  274. J. R. Morones, J. L. Elechiguerra, A. Camacho, K. Holt, J. B. Kouri, J. T. Ramírez and M. J. Yacaman, Nanotechnology, 2005, 16, 2346–2353 CrossRef CAS.
  275. D. M. Suflet, I. Popescu, I. M. Pelin, D. L. Ichim, O. M. Daraba, M. Constantin and G. Fundueanu, Pharmaceutics, 2021, 13, 1461 CrossRef CAS.
  276. N. Häntzschel, R. D. Hund, H. Hund, M. Schrinner, C. Lück and A. Pich, Macromol. Biosci., 2009, 9, 444–449 CrossRef.
  277. M. Sabzi, M. J. Afshari, M. Babaahmadi and N. Shafagh, Colloids Surf., B, 2020, 188, 110757 CrossRef CAS.
  278. M. T. S. Alcântara, N. Lincopan, P. M. Santos, P. A. Ramirez, A. J. C. Brant, H. G. Riella and A. B. Lugão, Radiat. Phys. Chem., 2020, 169, 108777 CrossRef.
  279. M. R. El-Aassar, O. M. Ibrahim, M. M. G. Fouda, H. Fakhry, J. Ajarem, S. N. Maodaa, A. A. Allam and E. E. Hafez, Carbohydr. Polym., 2021, 255, 117484 CrossRef CAS.
  280. H. E. Salama, G. R. Saad and M. W. Sabaa, J. Biomater. Sci., Polym. Ed., 2016, 27, 1880–1898 CrossRef CAS.
  281. C. Ryan, E. Alcock, F. Buttimer, M. Schmidt, D. Clarke, M. Pemble and M. Bardosova, Sci. Technol. Adv. Mater., 2017, 18, 528–540 CrossRef CAS.
  282. V. Thomas, M. M. Yallapu, B. Sreedhar and S. K. Bajpai, J. Colloid Interface Sci., 2007, 315, 389–395 CrossRef CAS.

This journal is © The Royal Society of Chemistry 2024
Click here to see how this site uses Cookies. View our privacy policy here.