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Amphiphilic-like carbon dots as antitumoral drug vehicles and phototherapeutical agents

Mariano Ortega-Muñoz a, Paula Vargas-Navarro a, Simona Plesselova b, M. Dolores Giron-Gonzalez b, Guillermo R. Iglesias c, Rafael Salto-Gonzalez b, Fernando Hernandez-Mateo a, Angel V. Delgado c, F. Javier Lopez-Jaramillo *a and Francisco Santoyo-Gonzalez *a
aDepartment of Organic Chemistry, Biotechnology Institute, Faculty of Sciences, University of Granada, Campus Fuentenueva s/n, 18071-Granada, Spain. E-mail: fjljara@ugr.es; fsantoyo@ugr.es
bDepartment of Biochemistry and Molecular Biology II, Faculty of Pharmacy, University of Granada, Campus Cartuja s/n, 18071-Granada, Spain
cDepartment of Applied Physics, Faculty of Sciences, University of Granada, Campus Fuentenueva s/n, 18071-Granada, Spain

Received 10th June 2021 , Accepted 4th October 2021

First published on 5th October 2021


Abstract

Water-insoluble carbon dots are recognized as promising materials, although their applications in nanomedicine are rarely explored, despite their lipophilic character and foreseen compatibility with biological membranes. In this article, we exploit the anhydride functionalization of carbon dots obtained by thermolysis of citric acid to synthesize amphiphilic-like carbon dots (LCDs) by reaction with alkyl amines. A differential feature of this approach is that the hydrophobicity of LCDs is a balance between the ionization of the carboxylic groups resulting from the reaction and the hydrophobicity from the grafted amines. The alkyl chains allow LCDs to entrap hydrophobic molecules and the ionization of the carboxylic groups increases the hydrosolubility, permitting the transfer between organic and aqueous phases. The biomedical interest of these features is illustrated by analyzing the application of LCDs as carriers of the drug campothecin and their evaluation on a battery of cancer cell lines, as well as the transformation of LCDs into a phototherapeutic agent by the formation of a complex with IR780 dye. Results demonstrate that LCDs behave as nanocarriers in a manner that resembles other supramolecular hosts with two differential features: (i) the length of the alkyl chains determines the size of the hosted guest, and (ii) the hydrosolubility of the complex can be modulated by pH.


Introduction

Carbon dots (CDs) are nanosized carbon particles that, since their discovery in 2004, have attracted the attention of researchers from different fields for their potential applications due to their high photostability, tunable excitation and emission, low toxicity and high biocompatibility.1–4 The synthesis of CDs is well established. The preparation has been approached by bottom-up and top-down strategies using different sources of carbons, including biomass.5 CDs have been functionalized6 and doped with heteroatoms7 and metal ions to tune their properties and widen their applications.8 However, most CDs are hydrophilic and incompatible with organic solvents, limiting their application in organic-based electronic and energy storage devices or in synthesis and catalysis in organic solvents.

Reports on CDs that are soluble in non-aqueous solutions, termed hydrophobic CDs (hCDs), are still scarce. In general, the synthesis involves either the use of a water-insoluble binary mixture of a carbon source and a capping agent9–14 or the specific post-synthesis functionalization of hydrophilic CDs,15,16 although polysaccharides17 and microwave assisted synthesis18 have also been reported. hCDs bearing an aliphatic chain are an emerging subgroup that has focused the interest of researchers. Among the alkyl chains, 1-hexadecylamine is frequently used either as both carbon source and alkyl chain12 or in combination with citric acid (CA)19,20 or ascorbic acid21 as source of carbon.

Although the applications of hCDs are rarely detailed, they are recognized as promising materials and explored as sensors,22 fluorescent inks,23 nanoadditive for lubricants,24 or in light-emitting diodes.20 The compatibility of hCDs with biological membranes facilitates their traversing.14,25,26 This feature is attractive for biomedical applications, in particular in cancer, where drug resistance and low specificity urge the development of new drugs whose fate may be compromised by solubility, stability and clearance rate, as illustrated by the paradigmatic case of campothecin.27 Additionally, the side effects of anticancer agents are a challenge that demands new therapeutic approaches, among them the use of nanoparticles for photothermal therapy.28 In this context, heptamethyne dyes such as IR780 are interesting molecules not only for bioimaging and theranostics but as photothermal agents that yield a temperature increase and production of ROS upon illumination with near-infrared (NIR) light.29 However, poor solubility in biological fluids, toxicity and fast clearance are major limitations29 that have been partially overcome by encapsulating IR780 in diverse materials30–35 or the production of CDs from IR780 and PEG by a solvothermal method.36

In this context, we describe in this work the thermolysis of CA in DMSO to obtain CDs functionalized with acid anhydride groups which, upon reaction with alkyl amines, are transformed into CDs (LCDs) presenting features that resemble those of amphibious17 and amphiplic15,24,26 CDs. LCDs bear both hydrophobic alkyl chains and carboxylic groups, the former making them suitable for hosting hydrophobic guests and the latter allowing the modulation of their hydrosolubility. As proof of concept of the biomedical applications of LCDs as carriers, the highly insoluble drug camptothecin and the photothermal and photodynamic therapeutic agent IR780 are examined as guests.

Results and discussion

Design of the synthesis of LCDs

hCDs are promising nanoparticles that are synthesized by the use of water-insoluble binary mixtures of a carbon source and a capping agent9–14 or by specific post-synthesis functionalization of hydrophilic CDs.15,17 We envisioned a two-step synthesis consisting of a first step of thermolysis of CA, to yield CDs functionalized with acid anhydride groups (AA-CDs),37 and a second step of reaction with alkyl amines to yield the grafting of the hydrophobic alkyl moiety via an amide linkage, with the concomitant formation of a carboxylic group. A differential feature of this approach is that the hydrophobicity of the resulting material is a balance between the ionization of the carboxylic groups and the hydrophobicity of the grafted amines.

The solvent free thermolysis of CA yields AA-CDs as a solid material stuck to the flask that forces the use of a solvent for the reaction with the alkyl amine. To avoid this manipulation we hypothesized that if the solvent, in addition to the inertness toward the anhydride groups and the good miscibility/solubility with the hydrophobic amine, presents thermal stability, the two-step synthesis can be conducted in the same pot. DMSO, with a boiling point of 189 °C at 1 atm and vapor pressure of 0.6 mm at 25 °C was the preferred solvent. This choice is further supported because DMSO is a green solvent,38,39 well ranked in different selection guides40,41 and it has been already used in the synthesis of CDs.42,43

Thermolysis of CA in DMSO

The appropriateness of the proposed design was evaluated by heating CA at 180 °C for two hours using DMSO as a solvent. The FTIR spectrum of the resulting liquid sample, named CD-1, (Fig. 1A) showed that the signals of the O–H stretching of the CA at 3500 and 3285 cm−1 vanished and those corresponding to the C[double bond, length as m-dash]C stretching (1650 cm−1) and bending (880–1014 cm−1) appeared, in full agreement with the transformation of CA into CDs. The analysis also revealed a double signal at 1844 and 1766 cm−1 that is the characteristic spectral signature of the asymmetric and symmetric C[double bond, length as m-dash]O stretching of acid anhydrides, supporting the use of DMSO as a solvent to yield AA-CDs. CD-1, was treated with a NaOH solution to hydrolyze the anhydride groups, dialyzed against water and lyophilized to yield CD-1Na. The FTIR spectrum of CD-1Na (Fig. 1A) did not show the double signal at 1844 and 1766 cm−1 but those of the O–H stretching and the typical symmetric stretching vibration signature of carboxylic acid salts separated by 150 cm−1 and peaks at 1550 cm−1 and 1400 cm−1, further confirming that the thermolysis of CA in DMSO yields acid anhydride coated CDs.44
image file: d1qm00855b-f1.tif
Fig. 1 (A) FTIR spectrum of CA (blue), of the solution resulting from the thermolysis of CA in DMSO (red), and after treatment with a NaOH, dialysis and lyophilization (black). (B) S 2p high resolution XPS spectrum of CD-1Na. Experimental data are shown in light blue, envelope in black and residuals on top in brown. Inset, table showing the main features of the peaks resulting from the peak fitting.

The surface chemistry of CD-1Na was characterized by XPS. The full scan XPS spectrum (Fig. S1A, ESI) showed peaks at ca. 285 eV, 532 eV, 1071 eV and 164 eV, indicating that the sample contains C, O, Na and sulfur. The content of sulfur was estimated to be 0.3% (Table S1, ESI) and it was initially assigned to residual DMSO. The high resolution C 1s spectrum was fitted with three peaks centred at 248.4 eV, 286.2 eV and 288.1 eV which are assigned to graphitic carbon, C–O and C[double bond, length as m-dash]O, respectively (Fig. S1B, ESI).45 The O 1s spectrum (Fig. S1C, ESI), besides the peaks centred at 530.9 eV and 531.3 eV corresponding to O[double bond, length as m-dash]C and O–C, consisted of a third peak at 535.4 eV attributed to Na KLL Auger emission.46 The analysis of the high resolution S 2p spectrum(Fig. 1B) was fitted with three peaks centred at 163.3 eV, 164.5 and 165.9 eV, the latter being the only coincident with the features of the S 2p spectrum of DMSO.47

The position of the two former peaks, the spacing of 1.18 eV and the intensity ratio of 0.48 agree with the 2p3/2 and 2p1/2 spin–orbit splitting of the –C–S– covalent bond of the thiophene-S.48–51 This result discards a contamination with DMSO and demonstrates that the thermolysis of CA in DMSO yields the incorporation of sulfur to the CDs.

Sulfur is an interesting dopant because it shares with carbon similar electronegativity (2.55 for carbon and 2.58 for sulfur) but different size (empirical atomic radius of 70 pm for carbon and 100 pm for sulfur), features that make feasible the incorporation of sulfur to aromatic rings and conjugation to planar ring carbon frameworks.52 Indeed, sulfur doping has been reported to improve quantum yield and shift the wavelength the maximum emission peak.53–55 Hence, morphology, size and photoluminiscence of CD-1Na were investigated. High-resolution transmission electron microscopy (HR-TEM) revealed spherical particles with an average diameter of 2.2 nm and selected area electron diffraction pattern supported the crystalline nature of CD-1Na with an interplanar spacing of 0.275 nm (Fig. S2A, ESI). The emission spectrum of CD-1Na was very similar to that for the CDots obtained by solvent free thermolysis of CA37 sharing the excitation at 326 nm and emission at 454 nm peaks (Fig. S2B, ESI), and a quantum yield of 4% (Table S2, ESI). A closer analysis of the emission spectrum of CD-1Na (Fig. S2B, ESI) revealed a shoulder at 435 nm that can be rationalized considering that the thermolysis of CA is a complex process that involves the formation of several intermediates to yield a combination of CDs with different emission peaks. In particular, the intermediates trans-aconitic acid and itaconic acid have been reported to yield fluorescent CDs that emit at lower wave-lengths and that the relative abundance of the different intermediates is influenced by reaction conditions.56

Functionalization of CD-1 with alkyl chains

The presence of acid anhydride groups in CD-1 makes them reactive and functionalizable without any previous step of activation.37 Our attention was focused on exploiting this feature to attach alkyl chains as hydrophobic moiety. Hexane-1-amine and octadecan-1-amine were selected on the basis that they share reactivity toward CD-1 but differ in their contribution to hydrophobicity, the octanol water partition coefficient in terms of logP being estimated as 1.63 and 5.37 respectively.57

Thus, the thermolysis of CA in DMSO and, without purification, later reaction with hexane-1-amine or octadecan-1-amine yielded products LCD-1 and LCD-2, respectively. LCDs were purified by dilution of the crude reaction mixture with toluene-diethyl ether and washing with 5% HCl to isolate the LCDs from the organic phase. XPS analysis found 0.8% and 1.1% of N for LCD-1 and LCD-2 (Table S1, ESI), confirming the alkylation of CD-1. The deconvolution of the N 1s peak revealed the expected signal at 399.8 eV for the amide-type nitrogen and a second signal at 401.6 eV that was assigned to amine-type nitrogen (Fig. 2A and B).58 However, the ratio between both peaks was close to 1, pointing to the presence of alkyl amine in spite of the extraction with 5% HCl.


image file: d1qm00855b-f2.tif
Fig. 2 N 1s high resolution XPS spectra of LCD-1 (A) LCD-2 (B) LCD-1Na (C) and LCD-2Na (D) experimental data are shown in light blue, envelope in black and residuals on top in brown. Inset, table showing the main features of the peaks resulting from the peak fitting.

In order to assess the elimination the alkyl amine, the organic phases containing LCDs were further purified by washing with a solution of sodium bicarbonate. The luminescence was observed to migrate to the aqueous phase due to the deprotonation of the carboxylic groups to form the sodium salts LCD-1Na and LCD-2Na. After exhaustive dialysis against water followed by lyophilization, LCD-1Na and LCD-2Na were characterized by XPS and HRTEM. The deconvolution of the N 1s peak showed that the signal assigned to unreacted alkyl amine persisted and the amide:amine ratio remained close to 1 for LCD-2Na (Fig. 2D) but increased to 6 for LCD-1Na (Fig. 2C). These results suggest that the reaction of CD-1 with the alkyl amines yields the grafting of the alkyl chain by both covalent bonds (i.e. amide-type) and non-covalent interactions, the latter being dependent on the length of the alkyl chain. Thus, whereas for short chain alkyl amines the non-covalent interactions are mainly ionic and disrupted by pH, for long alkyl amines they are mainly hydrophobic, due to interactions among the alkyl chains, and insensitive to pH. At this point it is important to highlight that the unreacted amines present in LCD-2 and LCD-2Na are part of the CDs and do not exchange with the solvent. HRTEM analysis revealed that LCDs are spherical nanoparticles with an average diameter of 2.5 nm, with 0.14 as the coefficient of variation (Fig. 3A). As expected, they are fluorescent and their spectra show a 20 nm blue shift of the emission peak relative to CD-1Na (Fig. 3B). The quantum yield of LCD-1Na is similar to that of CDN-1, but larger than that of LCD-2Na (Table S2, ESI), pointing to a lower fluorescent mass:overall mass ratio, in agreement with the longer alkyl chains appended to LCD-2Na.


image file: d1qm00855b-f3.tif
Fig. 3 (A) HRTEM image of LCND-2Na showing the size distribution (inset). (B) UV-Vis absorption (black line) and photoluminescence emission (excitation at 326 nm) spectra of LCD-1Na (green), LCD-2Na (blue) and CD-1Na (red).

The fact that LCDs can be transferred from the organic phase to the aqueous phase and vice versa resembles amphibious17 or amphiphilic15,24,26 CDs. In order to gain additional insight into the features of LCDs, the Z-potential (Table S3, ESI) and the octanol water partition coefficient (log[thin space (1/6-em)]P) (Table 1) were estimated. The values of log[thin space (1/6-em)]P are within the −0.5 < log[thin space (1/6-em)]P < 5 range predicted by the Lipinski rule of five for compounds with suitable cell permeability. Salt forms are highly hydrosoluble, LCD-2Na being the least hydrosoluble, and the lipophilicity can be modulated by the protonation/deprotonation of the carboxylate groups. As expected from previous studies that have demonstrated that sulfur increases the hydrophobicity of nanoscale zero-valent iron, the incorporation of sulfur shifts the log[thin space (1/6-em)]P from 0.09 for AA-CDs obtained by solvent free thermolysis of CA to 0.79 for CD-1.59 When the C18 alkyl chains are grafted, the log[thin space (1/6-em)]P increases to 1.03, which is slightly above the threshold value (log[thin space (1/6-em)]P[thin space (1/6-em)][thin space (1/6-em)]1) to distinguish membrane permeant from impermeant compounds.60 These values support the amphiphilic nature of LCDs and their ability to transverse membranes.

Table 1 Octanol–water partition coefficient of both the sodium salt and the acidic form of CDs obtained by solvent free thermolysis (AA-CDNa and AA-CD), in DMSO (CD-1Na, CD-1,LCD-1Na, LCD-1, LCD-2Na and LCD-2)
Sample Log[thin space (1/6-em)]P Sample Log[thin space (1/6-em)]P
a Particles remain in the aqueous phase.
AA-CDNa a AA-CD 0.09
CD-1Na a CD-1 0.79
LCD-1Na a LCD-1 1.03
LCD-2Na −1.05 LCD-2 0.89


Zeta potential of the CDs

The effect of the coating structure of the CDs and of pH on the zeta potential of the carbon dots is a significant feature of these nanoparticles, considering their potential application as drug vehicles to be injected in the body and subjected to environments of either physiological (7.4) or tumoral (6.5) pH values. The pertinent data are presented in Table S3 (ESI), and they show that the modification of pH in the interval mentioned does not affect beyond experimental uncertainty the zeta potential.

Application of LCDs

Since LCDs consist of a carbon core bearing ionizable carboxylic groups and hydrophobic flexible alkyl chains that can establish hydrophobic interactions, we hypothesize that LCDs can act as supramolecular hosts of hydrophobic guest molecules. With this feature LCDs can behave as nanocarriers in a manner that resembles other supramolecular hosts, but with additional advantages since the size of the hosted guest can be modulated by the length of the alkyl chains and the solubility of the complex by pH. Additionally, the cytotoxicity assay of LCDs against the cell line HEK 239 revealed that they are well tolerated (Fig. S3, ESI), anticipating their potential in biomedical applications, as their hydrosoluble counterparts.61

The hypothesis was put to test with the hydrophobic drug camptothecin (CPT) and with the NIR fluorescent hydrophobic dye IR780. The former is a potent chemotherapeutic agent27 and the latter, besides the emission in the 807–823 nm wavelength range that makes it suitable for bioimaging, shows an absorption peak at 792 nm that yields a temperature increase and a production of ROS upon illumination with NIR light, enabling its use in photothermal and photodynamic therapies.29 However, the clinical implementation of both molecules is limited by their poor solubility, the improvement of which being a challenging task.

LCDs as antitumor drug vehicles

From a structural point of view the planar structure of CPT is expected to favour the intercalation in the alkyl chains. The formation of the LCD@CPT inclusion complexes was approached by combining an aqueous solution of the sodium salt of LCDs in water and CPT in the organic phase and either removing the organic phase to force the formation of inclusion complexes or shaking overnight. Regardless the procedure, LCD-1Na did not form inclusion complexes with CPT. This result was not unexpected considering that the shorter length of the alkyl chain of the hexane-1-amine compared to the size of CPT may be insufficient to form stable inclusion complexes (Fig. S4, ESI). LCD-2Na forms stable complexes by both approaches, but the load of CPT was 3-fold higher when the formation of the inclusion complexes proceeded by shaking overnight (253 ± 13 μg mg−1vs. 85 ± 25 μg mg−1). When LCD-2Na is loaded with CPT to yield LCD-2Na@CPT the effect on the viability of the HEK 239 is in the range and even slightly better than an equivalent amount of free fresh CPT (Fig. S5, ESI). This result is encouraging when recalling that CPT from LCD-2Na@CPT underwent a processing incompatible with the stability of free CPT. Additionally, it confirms that the interaction between LCD-2Na and CPT is reversible and that the released drug is functional. In order to further evaluate the application of LCD-2Na as carrier of CPT, the cytotoxicity of LCD-2Na@CPT was assessed against a battery of cell lines and compared with an equivalent amount of free fresh CPT (Fig. 4). As depicted in Table 2 the IC50 of free CPT is cell line dependent and when compared to LCD-2Na@CPT it is in the same range for N2a, CT26wt and SKBR3. This result is remarkable when considering that it is assumed for the comparison that the full load of CTP is active and released from LCD-2Na@CPT. For the cell lines G361 and HeLa the IC50 of LCD-2Na@CPT is two- and four-fold higher than that for free CPT, suggesting an influence of the carrier. Flow cytometry analysis on the cell line G361 confirmed the result (Fig. S6, ESI). Overall, these data support the potential of LCD-2Na as a drug carrier.
image file: d1qm00855b-f4.tif
Fig. 4 Comparison of the cytotoxicity of LCD-2Na@CPT (green) and free CPT (red) on different cancer cell lines at different equivalent concentrations of CPT. Cell lines were incubated for 24 h with suitable amounts of either free CPT or LCD-2Na@CPT and cytotoxicity was assayed by the MTT method. Results are means ±1 standard deviation.
Table 2 IC50 values (in μM) of free CPT and LCD-2Na@CPT against a panel of cancer cell lines
Cell line Free CPT LCD-2Na@CPT
a Highest concentration assayed due to solubility limitations.
HeLa 46 189
G361 58 114
SKBR3 115 139
N2a 170 160
CT26wt 213 215
MDA-MB-231 264 >575a


LCDs in photothermal therapy

The formation of the inclusion complexes with IR780 is more challenging since the molecule is not planar. Based on the structure of IR780 and the length of the alkyl chains of LCDs (Fig. S4, ESI) LCD-1(Na) were discarded and the formation of inclusion complexes with LCD-2(Na) were approached by two strategies: (i) combination of the hydrosoluble form of LCD (i.e.LCD-2Na) in water and IR780 in the organic phase, or alternatively (ii) both, LCD-2 and IR780 in the organic phase. Since CDs absorb in the UV-region and IR780 shows a characteristic peak at 792 nm, the absorption spectra allow the estimation of the IR780 load. Data reveal that the latter strategy was the most successful in the formation of the inclusion complexes (Fig. S7, ESI).

As a proof of concept to evaluate use of LCD-2Na@IR780 in photothermal therapy, the thermal behaviour of a solution of the latter containing 72 μM of IR780 was compared with a 133 μM solution of the closely related hydrosoluble hepatamethyne IR783. As shown in Fig. 5A, upon irradiation with a 808 nm laser (1.4 W cm−2) for 5 minutes, both solutions showed similar behaviour during the first 66 seconds, with a heating rate of 0.3 °C per second. However, whereas the temperature of the LCD-2Na@IR780 solution continued increasing to rise up to 50 °C after 135 seconds and maintained the temperature for about 1 min, the temperature of the solution with IR783 declined abruptly after reaching 44.6 °C. To gain additional insight into this differential behaviour, drops containing a diluted solution of IR783 (i.e. 13 nM) were illuminated with the laser for 30 seconds. Thermal images showed that within this short period of time the drop behaved as the 72 μM solution, with an increase of temperature for the first seconds and then cooling down (Fig. S8, ESI). Visual inspection of the drop showed that its colour changed from the characteristic blue to yellowish and the absorption spectrum revealed that the peak at 780 nm vanished. These observations have been ascribed by other authors to the generation of singlet oxygen and degradation of IR780 into dioxetanes and carbonyl compounds.30,62


image file: d1qm00855b-f5.tif
Fig. 5 Temperature increase as a function of time of 200 μL of a water solutions containing 133 μM IR783 (red), 72 μM LCD-2Na@IR780 (blue) and 285 μM LCD-2Na@IR780 (magenta) irradiated with a 808 nm NIR laser at a power of 1.2 W cm−2 for 5 min (A) or 10 min (B). Inset B: Thermal image of the epperdorf containing the LCD-2Na@IR780 solution and the sample holder during the illumination. The temperature was recorded in real time with a high-resolution infrared camera.

The above results suggest that the thermal profile is dependent on the concentration of NIR dye and that the formation of a complex with LCD-2 spans its life. This hypothesis was confirmed when the thermal profiles of two solutions of LCD-2Na@IR780 containing 72 μM and 258 μM of IR780 were compared. As shown in Fig. 5B, the 72 μM solution behaved as expected from the previous experiment, reaching a maximum temperature after 3 min and then cooling down due to the destruction of the dye. However the 258 μM solution withstood 10 min of irradiation with the laser and the temperature reached 68.5 °C, with a slope of 19 °C in the first 30 seconds that flattened to 2 °C in the last 5 min of irradiation, and the temperature did not drop until the laser was turned off. These results lead to conclude that the irradiation with the laser yields the formation of oxygen singlet with the concomitant destruction of IR780 and that the concentration determines not only the maximum temperature reached but also the time that the laser is effective. At this point, it is important to recall that temperatures above 48 °C for minutes provoke irreversible injury that is enhanced by the reactive species produced during the destruction of IR780 by the laser.29

Experimental

Thermolysis of CA

Thermolysis of CA was carried out by modification of the protocol previously reported for AA-CDs.37 Briefly, an amount of 10 g of CA was placed in an open-round bottom flask and heated in an oil bath at 180 °C for 2 h in 10 mL of anhydrous DMSO to yield CD-1.

Synthesis of LCD(Na)

In the same open-round bottom flask where CD-1 were obtained by thermolysis at 180 °C of 10 g of CA in 10 mL of anhydrous DMSO, 1 mL of the solution was reacted overnight at room temperature with 0. 5 mmol of, either hexane-1-amine (70 μL) or octadecan-1-amine (140 mg) in the presence of 0.5 mmol of triethylamine (70 μL) to yield LCD-1 and LCD-2 respectively. For the isolation, a volume of 20 mL of ether[thin space (1/6-em)]:[thin space (1/6-em)]toluene (1[thin space (1/6-em)]:[thin space (1/6-em)]1) was added and then washed with 5% HCl (20 mL). The organic phase was collected, treated with anhydrous Na2SO4 and the solvent eliminated with a rotary evaporator to yield CDs decorated with hexane-1-amine (LCD-1, 0.859 g) or with octadecan-1-amine (LCD-2, 0.441 g). Sodium salts (LCD-1Na and LCD-2Na) were obtained by extraction of LCDs with a saturated solution of HCO3Na, exhaustive dialysis (MWCO =14[thin space (1/6-em)]000 Da) against deionized water and then lyophilization.

Preparation of LCD-2Na@CPT for biological assays

A volume of 14 mL of a 0.5 mg mL−1 solution of LCD-2Na in water was combined with 14 mL of 0.5 mg mL−1 solution of CPT in Cl3CH. The mixture was shaken at room temperature and protected from light for 24 h and phase separation was allowed to proceed for 48 hours. The organic R3 phase was discarded and the concentration of CPT in the aqueous phase was estimated from the remaining fluorescence in the discarded organic phase.

Preparation of LCD-2@IR780 for photothermal assay

A volume of 6 mL of a 0.5 mg mL−1 solution of IR780 in Cl3CH was combined with 6 mL of LCD-2 in Cl3CH (0.5 mg mL−1). After sonication for 2 min, it was shaken overnight at room temperature protected from light. The sample was extracted with 50 mM carbonate-bicarbonate buffer pH 9 (3 × 4 mL). The concentration was estimated from the interpolation in the suitable calibration curves of absorbance at 326 nm and fluorescence at 454 nm (Ex 326 nm) for LCDs and of absorbance at 792 nm for IR780.

Cytotoxicity of LCD-2Na@CPT

Cell lines were incubated for 24 h with suitable amounts of either free CPT or LCD-2Na@CPT to yield final CPT concentrations up to 200 μg mL−1. Cytotoxicity was assayed by determining the percentage of cell viability (with respect to unexposed cells) using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-2H-tetrazolium bromide (MTT) method. Results are reported as % viability based on the untreated control cells at 24 h normalized to 100% viable. ED50plus v1.0 software was used to calculate IC50.

Photothermal measurements

Water solution samples of 200 μL contained in 1.5 mL Eppendorf tubes were irradiated with a near-infrared continuous laser at a wavelength of 808 nm for 10 min. The laser power was calibrated at 360 mW, corresponding to a power density of 1.2 W cm−2. The distance between the sample and the laser was 6 cm, and the laser spot in the sample was 0.3 cm2. The temperature profile as a function of time was recorded in real time with a high-resolution infrared camera FLIR E60 with 320 × 240 pixels IR resolution and thermal sensitivity better than 0.05 °C (FLIR Systems Inc., USA). Data was processed with FLIR RESEARCHIR MAX 4 thermal analysis software. (provided by the manufacturer).

Conclusions

The one-pot thermolysis of CA in DMSO and further reaction with alkyl amines is a suitable approach to obtain amphiphilic-like CDs bearing hydrophobic alkyl chains and carboxylic groups. The alkyl chains allow the formation of inclusion complexes with hydrophobic guest whereas the ionization of the carboxylic groups can be modulated by pH, determining the hydrosolubility of the complexes. LCDs are well tolerated by cells and, using a suitable length of the alkyl chains, they form inclusion complexes with hydrophobic guests of complementary size. The values of log[thin space (1/6-em)]P and the results obtained from the model drug CPT support the biotechnological potential of LCDs as drug carriers that overcome solubility problems and protect from degradation. The IC50 of LCD-2Na@CPT is in the same range as that of free IC50 for the cancer cell lines N 2a (neuroblastoma), CT26wt (colon carcinoma), SKBR3 (Her2+ breast cancer), twofold higher for G361 (malignant melanoma) and fourfold higher for HeLa (cervical carcinoma). The performance of LCD-2Na complexes with IR780 dye, yielding a significant sustained increase of temperature of up to 68.5 °C, also supports their application in photothermal therapy.

Author contributions

Conceptualization, M. O.-M., G. R. I., R. S. G., F. J. L.-J., F. S.-G.; formal analysis, F. J. L.-J., M. O.-M; funding acquisition, M. D. G.-G., A. V. D., F. S. G.; investigation, M. O.-M., P. V.-N., S. P., M. D. G.-G., G. R. I., F. J. L.-J.; methodology, M. O.-M, G. R. I., F. J. L.-J.; M. D. G.-G.; supervision, R. S.-G., A. V. D., F. S.-G.; validation, G. R. I., F. J. L-J., visualization, G. R. I., M. D. G.-G., F. H. M., F. J. L.-J; writing – original draft, F. J. L.-J.; writing – review & editing: G. R. I., M. D. G.-D., R. S.-G., F. H.-M., A. V., F. J. L.-J., F. S.-G. All authors have read and agreed to the published version of the manuscript.

Conflicts of interest

There are no conflicts to declare.

Acknowledgements

The work was financially supported by the Spanish institutions Ministerio de Ciencia, Innovación y Universidades (PGC2018-098770-B-I00 and CTQ2017-86125-P) and Junta de Andalucía (ProgramaOperativo FEDER 2014-2020, grants B-FQM-141-UGR18, A1-FQM-341-UGR-18, C-FQM-497-UGR18).

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Footnote

Electronic supplementary information (ESI) available. See DOI: 10.1039/d1qm00855b

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