Mingyuan
Gao‡
a,
Yiping
Luo‡
bc,
Wen
Li
*a,
Longpo
Zheng
*bc and
Yanzhong
Pei
*a
aInterdisciplinary Materials Research Center, School of Materials Science and Engineering, Tongji Univ., 4800 Caoan Rd., Shanghai 201804, China. E-mail: liwen@tongji.edu.cn; yanzhong@tongji.edu.cn
bDepartment of Orthopedics, Shanghai Tenth People's Hospital, School of Medicine, Tongji Univ., 301 Yanchang Rd., Shanghai 200072, China. E-mail: dr.zheng@tongji.edu.cn
cOrthopedic Intelligent Minimally Invasive Diagnosis and Treatment Center, Shanghai Tenth People's Hospital, School of Medicine, Tongji Univ., 301 Yanchang Rd., Shanghai 200072, China
First published on 11th June 2024
The ability of thermoelectric materials to generate electricity in response to local temperature gradients makes them a potentially promising solution for the regulation of cellular functions and reconstruction of tissues. Biocompatibility of implants is a crucial attribute for the successful integration of thermoelectric techniques in biomedical applications. This work focuses on the in vitro and in vivo evaluation of biocompatibility for 12 typical chalcogenide thermoelectrics, which are composed of biocompatible elements. Ag2Se, SnSe, Bi2Se3, Bi2Te2.88Se0.12 and Bi2Te3, each with a released ion concentration lower than 10 ppm in extracts, exhibited favorable biocompatibility, including cell viability, adhesion, and hemocompatibility, as observed in initial in vitro assessments. Moreover, in vivo biocompatibility assessment, achieved by hematological and histopathological analyses in the rat subcutaneous model, further substantiated the biocompatibility of Ag2Se, Bi2Se3, and Bi2Te3, with each possessing superior thermoelectric performance at room temperature. This work offers robust evidence to promote Ag2Se, Bi2Se3, and Bi2Te3 as potential thermoelectric biomaterials, establishing a foundation for their future applications in biomedicine.
Materials with the capability to generate electricity have garnered considerable attention as potential candidates for biomedical applications. This is primarily owing to the unique interaction between the generated electricity and biological systems, which can profoundly influence cellular behavior,2 neural signal transmission,3 tissue regeneration processes,4 and so on. Piezoelectric materials, which can convert mechanical stress to electricity, have found diverse practical applications in biomedicine,5 such as ultra-sensitive biosensing technologies6 and bone tissue regeneration.2,7 Moreover, photoelectric materials, which are capable of transforming light energy to electrical energy, offer a reliable route for the precision control of cellular activities and neuronal discharges.8
Thermoelectric materials, leveraging their attribute of converting temperature differences into electric power, have potential in a wide spectrum of anticipated biomedical applications.9 Thermoelectric microdevices have been utilized for the real-time monitoring of body temperature,10 precise adjustment of local temperature,11 and as a power supply for medical devices.12 Similar to piezoelectric and photoelectric materials, the unique ability of thermoelectric materials to generate electricity from body-environment temperature differentials presents a potential possibility to modulate biological systems through direct electrical stimulation of cells and tissues. This could lead to groundbreaking therapeutic strategies for wound healing, neural stimulation, and cellular function regulation, marking a new frontier in medical innovation.
For ensuring the safe and effective application of thermoelectric materials in biomedicine, a profound understanding of their interaction with biological tissues is paramount.8b Biocompatibility represents a pivotal criterion in assessing the safety of materials for in vivo applications, and it holds special significance for thermoelectric materials. This encompasses not only the immediate cellular and tissue responses, but also long-term stability post-implantation, potential immune reactions, and interactions with bodily fluids.13 These facets collectively define the host response to foreign materials, which can impact a material's functional efficacy and patient safety. Thus, a comprehensive evaluation of the biocompatibility of thermoelectric materials is indispensable to guide their medical applications and ensure their harmonious integration within biological systems.
Chalcogenide compounds, especially selenides and tellurides,14 have been extensively demonstrated to be promising thermoelectric materials, with extraordinary performance able to be realized by applying band and defect engineering strategies.15 These strategies are always achieved by the manipulation of the chemical constituents.16 Thus, taking into account the elemental prevalence in biological systems and thermoelectric performance, chalcogenide thermoelectrics, such as SnSe, Ag2Se,17 Cu2Se,18 Bi2Se3,19 Te,20 GeTe,21 SnTe,22 MnTe,23 Bi2Te3,24 Bi2Te2.88Se0.12,24 Bi0.5Sb1.5Te3,25 Sb2Te3,25 have been comprehensively investigated to uncover their biocompatibility and its dependence on the composition.
In this work, the in vitro cell viability assay preliminarily indicated the considerable biocompatibility of SnSe, Ag2Se, Bi2Se3, Bi2Te3, and Bi2Te2.88Se0.12, which could reasonably be understood by a released ion concentration lower than 10 ppm in the extracts. Moreover, the viability and morphology of the seeded cells helped elucidate the chemical reaction between the cells and thermoelectric materials (Ag2Se, Bi2Se3, Bi2Te3, and Bi2Te2.88Se0.12) in terms of the spreading cell morphology and stress fiber formation. In vivo subcutaneous implantation in rats was conducted to further identify the biocompatibility of Ag2Se, Bi2Se3, and Bi2Te3, providing additional confirmation of the safety of these compounds for potential biomedical applications.
The seeded cells were incubated for 24 h, and then rinsed three times with phosphate buffer saline (PBS, pH 7.4). After fixing with 2.5% glutaraldehyde at 4 °C for 4 h, the samples underwent graded ethanol dehydration, freeze-drying, and gold sputter-coating. The adhering cells’ morphology was observed by SEM.
The animals were anesthetized using a combination of ketamine (120 mg kg−1 body weight) and xylazine (16 mg kg−1 body weight). The surgical area was shaved and disinfected. A skin incision was made on the rat's back to create a subcutaneous pocket, followed by implants insertion and suture closure. After suturing the incisions, the rats were placed in a recovery area with controlled warmth and provided with analgesics. The rats were humanely euthanized at predetermined time points of 3, 7, and 30 days post-implantation to facilitate the retrieval of the thermoelectric implants and collect the vital organs, i.e., the liver, brain, kidney, heart, spleen, and tissues near the implant sites, which were then all preserved in 10% formalin for histological analysis. The selection of these time points was strategically made to correspond with the key phases of the inflammatory response: acute inflammation, proliferation, and remodeling, respectively.
In vitro cytocompatibility assays can provide crucial insights into the biocompatibility of biomaterials and aid in shaping subsequent animal and clinical trial strategies. To preliminarily evaluate the in vitro cytocompatibility of the thermoelectric materials, the cytotoxicity to cells cultured by the extracts was evaluated using the CCK-8 assay. In addition to the biocompatible element, the stability of the materials, determining the released ion concentration, is also a crucial factor to elucidate the biocompatibility. The released ions can modulate a wide range of cellular functions and behaviors, from gene expression and metabolic activity to cell migration and differentiation.27 The concentration of released ions, released from the thermoelectric materials, in the extracts was quantified by ICP-MS and the corresponding results are displayed in Fig. 1.
The selenides of SnSe, Ag2Se, and Bi2Se3 showed ion concentrations lower than 1 ppm for each constitute element in the extracts. Therefore, the cell viability exceeding 80% for various cells (3T3, HUVEC, and BMSC) could be reasonably understood by the low concentration of ions released (Fig. 2). According to the ISO 10993-5 biocompatibility standard, the cytotoxicity of these materials could be classified as grade 0 or 1, suggesting their considerable compatibility and a tolerable concentration range of 0.1–1 ppm for Sn, Bi, and Se. Cu2Se was a notable exception, exhibiting diminished compatibility, associated with the substantial release of copper ions (>100 ppm). The elevated Cu ion levels were found to interfere with essential cellular processes, including mitochondrial function and signaling pathways, culminating in apoptosis or necrosis.28 Moreover, the Cu could catalyze the production of reactive oxygen species (ROS) through Fenton-like reactions,29 leading to oxidative stress,30 cellular damage, and a disruption of homeostasis.
The tellurides with the released Te ion concentration higher than 7.2 ppm in the extracts exhibited pronounced cytotoxic effects, illustrating the cytotoxicity of the 100% extracts of Te, GeTe, SnTe, MnTe, Bi0.5Sb1.5Te3, and Sb2Te3. The cytotoxicity for the majority of them reached grade 4. It is known that high Te concentrations would be accompanied with irreversible oxidative stress, which would then disrupt intracellular organization and the energy balance,31 which would be detrimental to cells. Bi2Te3 and Bi2Te2.88Se0.12 were found to be biocompatible with the cells of 3T3 and HUVEC, while a pronounced cytotoxicity toward BMSC was observed for these materials.
Fibroblasts are well known for their physiological roles in matrix remodeling and wound healing.32 NIH/3T3 cells, as fibroblast models, offer a valuable system to investigate the interaction between cells and thermoelectric materials, facilitating the assessment of a material's biocompatibility and its potential to enhance cellular functions critical for tissue repair.33 The viability and adhesion of NIH/3T3 cells directly seeded onto the surfaces of various materials were detected by live/dead cell staining technology. Titanium alloy (Ti-6Al-4V, TC4), recognized as a benchmark for its excellent biocompatibility in biomaterials, served as a control here. After 24 h incubation, the calcein AM/propidium iodide (PI) staining results, depicted in Fig. 3, delineated the proportions of live (green) and dead (red) cells. The cell growth trends were well consistent with the results from the CCK-8 assay (Fig. 2). In detail, the cell viabilities of Bi2Se3, SnSe, Ag2Se, Bi2Te2.88Se0.12, and Bi2Te3 were qualitatively comparable to those on titanium alloy. In stark contrast, a significant reduction in cell numbers and extensive cell detachment were observed for SnTe, MnTe, and Bi0.5Sb1.5Te3, hinting at a potential cytotoxicity. GeTe, Cu2Se, Te, and Sb2Te3 exhibited a significant lack of viable NIH/3T3 cells, strongly suggesting the pronounced cytotoxic attributes of these materials. The low concentration of cells in Cu2Se and GeTe could possibly be attributed to the dead cells being removed during the washing steps prior to staining, which could be confirmed by their poor adhesion (Fig. 4).
Fig. 3 Live/dead staining of NIH/3T3 cells cultured on titanium alloy (Ti) and thermoelectric materials for 24 h. Scale bar is 200 μm for all images. |
The morphologies of NIH/3T3 cells seeded on the thermoelectric materials after 24-h incubation were observed by SEM (Fig. 4). The NIH/3T3 cells seeded on the surfaces of Ag2Se, Bi2Se3, Bi2Te3, and Bi2Te2.88Se0.12 exhibited extensive spreading, characterized by a higher degree of elongation and a multitude of filopodia-like protrusions, indicative of a robust cellular engagement with the substrate. Notably, the alignment of cell adhesion morphology with the directional polishing marks on the material's surfaces suggests that microtopographical cues play a significant role in guiding cell behavior.34 On the SnSe and Bi0.5Sb1.5Te3 matrices, most the cells displayed effective spreading and stress fiber formation, but some presented a rounded, less adherent phenotype. In addition, the notable cellular detachment was observed on the surfaces of Cu2Se, Te, GeTe, SnTe, MnTe, and Sb2Te3, along with the remaining cells exhibiting cytoplasmic retraction and agglomeration. The observed morphological trends were consistent with the results of the cell viability. Additionally, corrosion products deposited in the form of hexagonal sheets were found on the MnTe and Cu2Se substrates, which aligned with their high ion release as quantified in the extracts.
In the physiological environment, the release of products from thermoelectric materials into the bloodstream is inevitable. Consequently, the hemocompatibility of the thermoelectric materials was evaluated through in vitro hemolysis experiments (Fig. S4, ESI†). The results indicate that, with the exception of Bi0.5Sb1.5Te3 and Sb2Te3, the hemolysis rates of the extracts from other thermoelectric materials were below 6% after incubation with rat whole blood, meeting the safety criteria as per ISO 10993-4 standards. This presumably originated from the existence of a high concentration of Sb in the extracts.
Based on the comprehensive consideration of the in vitro cytotoxicity studies and thermoelectric properties near room temperature, the in vivo biocompatibility of Ag2Se, Bi2Se3, and Bi2Te3 thermoelectric materials was studied in depth by subcutaneous implantation in SD rat models, monitored meticulously over intervals of 3, 7, and 30 days. Hematological analyses revealed a minimal impact on crucial blood parameters, including red blood cells (RBC), white blood cells (WBC), hemoglobin (HGB), hematocrit (HCT), mean corpuscular volume (MCV), mean corpuscular hemoglobin (MCH), mean corpuscular hemoglobin concentration (MCHC), neutrophils, lymphocytes with other immune cells and platelets (PLT), all of which remained within the normal range, as depicted by the blue shaded area in Fig. 5. Comparative analysis with a titanium alloy control showed no significant statistical differences (p > 0.05), affirming their biocompatibility. The transient fluctuations in immune cell counts, including in white blood cells, suggested an initial immune response, which normalized over time, indicative of an adaptation phase to the new materials. Notably, the significant decrease in white blood cell and immune cell counts for Ag2Se at 30 days may be related to the well-reported antibacterial properties of Ag.35
Furthermore, the impact of the thermoelectric materials on liver and kidney function was investigated. Comprehensive serum biochemical analyses revealed that key hepatic indicators, including albumin (ALB), alkaline phosphatase (ALP), gamma-glutamyl transferase (GGT), and total bilirubin (TBIL), remained within normal limits across all materials, as shown in Fig. 6. However, a marked deviation was observed in Ag2Se at the 30-day mark, where the levels of alanine aminotransferase (ALT) and aspartate aminotransferase (AST) exceeded the normal range, revealing its time-dependent liver function impairment. In contrast, Bi2Se3 and Bi2Te3 exhibited mild anomalies in some parameters, albeit to a lesser extent than those of Ag2Se, suggesting their relatively superior biocompatibility and lower chronic hepatic toxicity. Regarding renal function, all the evaluated parameters, including blood urea nitrogen (BUN) and creatinine (CREA), remained within normal ranges, signifying stable renal function without apparent renal damage throughout the study period. Additionally, the levels of blood glucose and lipids were maintained within normal ranges, indicating no adverse impact on the metabolic state of the rats.
The histological response of an organ is an important indicator to evaluate the impact of implanted materials on the whole body. Hematoxylin–eosin (H&E) staining was employed to meticulously evaluate the histological soundness of various organ systems, including the heart, liver, spleen, lungs, kidneys, and brain, at different time intervals in an SD rat model (Fig. 7 and Fig. S5, S6, ESI†). The histopathological analysis revealed the absence of significant pathological modifications in these organs. Specifically, the cardiac and spleen exhibited no discernible fibrotic/necrotic alterations and a normal distribution of white and red pulp without any abnormalities, respectively. The liver could maintain its structural integrity without any indications of hepatocellular damage or inflammation. The pulmonary showed well-preserved alveolar, peribronchial, and perivascular structures, with uniform alveoli and clear bronchioles. The renal analysis displayed healthy glomeruli and tubular structures, and the brain tissues retained normal neuronal architecture and density, with no evidence of neuronal injury or edema. All these results indicate the favorable in vivo biocompatibility of these materials.
H&E staining was performed on the subcutaneous local tissue surrounding the implanted thermoelectric materials, as illustrated in Fig. 8. The selected time points of 3, 7, and 30 days were strategically chosen and correspond to the acute inflammatory phase, the proliferative phase, and the remodeling phase, respectively, providing a comprehensive framework to assess the materials’ biocompatibility over time. All the experimental groups exhibited a consistent time-dependent increase in body weight, with no significant differences observed between groups (Fig. S7, ESI†). No macroscopic signs of rupture, infection, necrosis, or edema were observed at the implantation sites (Fig. S8, ESI†). As shown in Fig. 8, all the materials initially induced a marked acute inflammatory response at the implantation sites, characterized by an aggregation of fibroblasts and inflammatory cells, including macrophages, lymphocytes, and occasional giant cells. This typical response indicated the initiation of the natural healing process and the activation of the foreign body reaction, with angiogenesis or vascular expansion observed near Bi2Te3 implants suggesting an intensified inflammatory stage. Over time, this reaction subsides, demonstrating effective integration between the implants and host tissue. After implanting for 30 days, a significant diminution of inflammation, particularly in the Ag2Se group, was observed, possibly linked to the decrease in white blood cell count in the bloodstream. The formation of a thin fibrous capsule around all the materials attested to the minimal and controlled inflammatory response elicited by the materials. The variation in the thickness of the fibrous capsule (as shown in Fig. S9, ESI†) also mirrored the tissue's response and adaptation to the implanted materials, with minimal changes for Ag2Se and the Ti control group and more pronounced variations for Bi2Se3 and Bi2Te3, indicative of the dynamic process of tissue remodeling and healing in response to the implants.
Masson's trichrome staining, as shown in Fig. 9, was used to focus on collagen deposition at the implant site (indicated by the blue stained area), a key marker for assessing tissue remodeling and healing. As the implantation period progressed, the increase in the content of collagen and restoration of fibrous structures indicated the tissue's adaptation to the materials. Particularly by day 30, the orderly arrangement of collagen fibers illustrated mature and stable tissue remodeling. These findings not only demonstrate the good tissue adaptation to the implants but also reflect the materials’ biocompatibility with the surrounding biological tissues. This is strongly related to the material stability of the material implanted (Fig. S10–S13, ESI†). Overall, these comprehensive histological analyses highlight the excellent biocompatibility and tissue integration capabilities of the studied thermoelectric materials under subcutaneous implantation conditions, providing robust scientific evidence for the potential future applications of Ag2Se-, Bi2Se3-, and Bi2Te3-based thermoelectrics in the field of medical devices.
Footnotes |
† Electronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d4tb00973h |
‡ The authors equally contributed. |
This journal is © The Royal Society of Chemistry 2024 |