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Tunning self-assembled phases of bovine serum albumin via hydrothermal process to synthesize novel functional hydrogel for skin protection against UVB

  • Kanchan Yadav , Megha Das , Nitesh Kumar Mishra , Anuj Chhabra , Archana Mishra , Sunita Srivastava , Poonam Sharma EMAIL logo , Sanjeev Kumar Yadav and Avanish Singh Parmar EMAIL logo
Published/Copyright: April 18, 2022
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Nanotechnology Reviews
From the journal Nanotechnology Reviews Volume 11 Issue 1

Abstract

Ultraviolet rays – B (UVB) can be efficiently absorbed by the cellular molecules of skin inducing damage within skin cells and a major cause of melanoma cancer. In recent years, several studies have reported the adverse effects of traditionally used organic and inorganic material-based sunscreens and UVB blockers. In this study, bovine serum albumin (BSA) has been used as a precursor to synthesize temperature- and pressure-dependent phase transition from sol (globular aggregates) – gel (hydrogels) – sol (carbon quantum dots) using a single-step hydrothermal method with an objective to develop an efficient and effective UVB blocker. The synthesized hydrogels exhibit UV – attenuation, self-fluorescence, and high biocompatibility properties that make them a suitable candidate for UV-blocker or sunscreen material. The biological efficacy of the hydrogels was studied through cyto-toxicity studies. Also, UVB blocking efficiency of developed hydrogel in primary mice skin cell culture as well as in vivo in mice model was studied. In vivo study on mice further demonstrated prominent thickening of stratum corneum and epidermis with perivascular edema in the dermis after 5 days of UVB exposure. Hence, this suggesting that hydrogel could be a potential candidate for protecting the skin from UVB exposure and reducing the threat of skin cancer.

Graphical abstract

Keywords: hydrogel; self-assembly; skin protection; UVB

1 Introduction

Skin, the largest organ in the body, has a surface area of about 1.8 m2 and occupies 16% of the total body mass of an adult [1]. The primary and most important function of the skin in mammals is to provide a protective barrier against various infections caused by fungi, bacteria, UV radiation, and other environmental factors [2]. One of the major reasons for skin cancer is exposure to UV radiation (UV) which is classified as UVA (320–420 nm), UVB (290–320 nm), and UVC (200–290 nm). Almost all three, UVC and a part of UVB wavelength get absorbed by the ozone layer and limit their reach upto the earth’s surface [3,4]. UVA has a minor effect on the skin; however, UVB is the primary threat to human health and is responsible for skin cancer, photoaging, immune suppression, and sunburns [5,6].

Cancer is the most challenging disease to treat and the second most cause of mortality in the world. In recent years, there is a tremendous increase in skin cancer worldwide [7,8]. The major types of skin cancers are basal cell carcinoma, squamous cell carcinoma, Markel cell cancer, and melanoma in which melanoma is most dangerous because of its ability to spread faster to other organs if it is not diagnosed at an early stage and even becomes deadly [9,10]. Therefore, treating melanoma skin cancer is a big challenge, and emerging functional materials give a possible route to treat melanoma by enhancing drug uptake in cancer cells, minimizing toxicity, increasing the circulation time in tumor tissue, etc.

Avoiding excessive solar exposure and using sunscreens composed of nanoparticles such as zinc oxide NPs, are recommended to prevent exposure to UV radiation [11,12,13]. Currently, the most commonly used sunscreens are based on the nano-sized TiO2 and ZnO nanoparticles [14,15]. Skin exposure to the nano-sized particles containing sunscreens leads to the incorporation of inorganic material in the stratum corneum which can alter the attenuation properties due to particle-particle, particle-skin, and skin-particle-light physiochemical interactions [16,17]. Photocatalytic effects, nanoparticle stabilization after chronic exposure, and free radical production are some other major concerns to using these materials as sun blockers. The current scenario demands a new alternative material for skincare treatments, which can be more efficient, biocompatible, minimizing the side effects, and reducing the treatment cost significantly for the patients [18,19,20,21]. In this regard, functional biomaterials could be a good alternative to the nano-sized inorganic nanoparticle to prevent sunburns and skin cancer.

Proteins are biomolecules in nature; thus, they are safe and biocompatible. In recent studies, proteins have been extensively utilized by Materials scientists to design novel materials with unique functionality that further improves their practical applicability [22,23,24,25]. The complex structure of proteins is maintained due to the various interactions such as electrostatic, van der Waals, hydrophobic, and cation-pi. This gives tremendous opportunity to tune them into self-assembled hierarchal structures. Another fascinating aspect of self-assembled protein materials is the formation of hydrogel, which have multifunctional properties [26,27,28,29]. Protein-based hydrogels are a promising material for various biomedical applications because of their hydrophilic networks, controllable self-assembly, and biocompatibility. Bovine serum albumin (BSA) is a cost-effective, easily, and widely available protein. Its primary structure contains a single polypeptide chain of 583 amino acids with a molar mass of 66.4 kDa. BSA is a water-soluble protein with 76% sequence homology and identical pH-dependent conformation with human serum albumin [30,31]. Studies show that BSA has been conjugated with many organic and inorganic compounds for the synthesis of bio-nanoconjugates, monolayers, and nanoparticles, and holds promising applications in the biomedical field [32,33,34,35,36].

Thus, BSA has been used as a precursor to synthesize different self-assembled morphologies using a single-step hydrothermal thermal method with an objective to develop an efficient and effective UV-B blocker. By varying the hydrothermal temperature from 25 to 120°C, different phases of BSA protein have been synthesized. First, sol-to-gel transition occurs at 70°C, where BSA protein transforms into a self-assembled hydrogel phase, further heating of BSA protein at 120°C leads to the second-phase transition from gel to carbon quantum dots. Developed phases were thoroughly characterized using various physical and optical techniques such as SEM, TEM, FTIR, and SAXS, for studying their efficient applicability in the biomedical field. Biological efficacy was studied through cytotoxicity studies, and UV-B blocking efficiency of developed hydrogel was studied in primary mice skin cell culture as well as in vivo in mice model.

2 Material and methods

2.1 Chemicals and materials

BSA (lyophilized powder, >96% (agarose gel electrophoresis), M W = 66,430 Da), rutile nanosized TiO2, sodium chloride, hydrochloric acid, disodium hydrogen phosphate, and sodium dihydrogen phosphate were purchased from Sigma-Aldrich and used without further purification. Deionized water (12M-cm) from the Millipore water purification system was used for all aqueous solution preparations.

2.2 Synthesis of temperature-dependent phases of BSA

All the temperature-dependent phases of BSA were synthesized using the single-pot hydrothermal method. The homogenous solutions of concentration 40 mg/mL of lyophilized BSA powder were prepared using Sorensen’s phosphate buffer (pH-7.4) with a sodium salt concentration of 150 mM. The prepared solutions were transferred to a 25 mL Teflon cylinder with a steel autoclave and heated for the hydrothermal reaction at temperature ranges from 25 to 120°C for 15 h. During heating at different temperatures, different phases of BSA were resulted. The resultant samples were named according to their heating temperature, for example, H-100 suggests that BSA solution has been heated at 100°C for 15 h using the hydrothermal method.

2.3 Characterization techniques

A different phase of BSA has been characterized using suitable physical techniques. UV-Vis measurements have been performed using JASCO V770 UV-Vis spectrophotometer and Eppendorf Biospectrometer for solid and liquid samples, respectively. Photoluminescence (PL) properties have been studied using Fluorolog (Horiba). Fourier transform infrared (FT-IR) spectroscopy was performed using the Thermo Scientific Nicolet iD7 spectrometer over the wavenumber 500–4,000 cm−1 region with a resolution of 4 cm−1. Field emission scanning electron microscope (FESEM) images were taken using a FEI Nova NanoSEM 450 FESEM. A transmission electron microscopy (TEM) image was obtained using the TECNAI-T-20 (FEI instrument) at 200 kV accelerating voltage. LV100ND fluorescence microscope and Carl Zeiss 780 LSM laser scanning confocal microscopy system (Germany) were used for fluorescence microscopy. Rheological characterization of BSA hydrogels was performed using the Anton Paar Physica MCR301 rheometer. The BSA hydrogels were prepared in a hydrothermal autoclave and transferred to the rheological geometry of 8 mm parallel plates having a gap of 1 mm at room temperature for further studies. The measurement for storage and loss modulus as a function of strain and frequency was also performed for all hydrogels (H-70 to H-110) between the frequency range of 0.1 and 10 rad s−1 with a constant strain of 0.5% at 25°C. Xenocs SAS, model Xeuses 2.0, with a dual-source module X-ray source (Q range varies from 0.005 to 1.2 Angstrom−1) was used for the small-angle X-ray scattering (SAXS) measurement.

2.4 In vitro studies

2.4.1 Cell culture

For primary skin cell culture, skin tissue was collected from the hairless skin of Swiss albino mice, and the isolation of primary epidermal cells, endothelial cells, dermal cells, and fibroblast cells was performed by following the protocol given by Pauline Henrot et al. [37]. For experimental purposes, epidermal cells were used.

2.4.2 Cell viability

The biocompatibilities of all samples, i.e., H-25, H-60, H-70, H-80, H-90, H-100, H-110, H-120, and H-200, were determined by the MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide] assay where the primary mice skin cells were plated at 104 cells/well in 96-well plates (Genetix) 24 h prior to the experiments. After completion of 24 h, the cells were treated with H-25, H-60, H-70, H-80, H-90, H-100, H-110, H-120, and H-200 with the same dose (20 mg/mL, i.e., 1:1 sample: complete media). In control (with cells) and negative control or blank (without cells) groups, the complete media were added. After 24 h of treatment, the cells were processed for the MTT assay following the laboratory standard process [38], and the optical density was measured in triplicate at 595 nm in a microplate reader (Biorad).

2.4.3 Cellular uptake

For the cellular uptake study of each sample, primary mice skin cells were seeded at 6,000 cells/well upon the round coverslips placed inside the 24 well plates 24 h prior to treatments. After 24 h, the cells were treated with the samples (H-25, H-60, H-70, H-80, H-90, H-100, H-110, H-120, and H-200) at the concentration of 20 mg/mL for the next 24 h similarly to MTT assay. After completion of 24 h, treated cells were fixed, permeabilized, and stained with DAPI according to the laboratory standard procedure [39], and finally, images were captured by a Carl Zeiss 780 LSM laser scanning confocal microscope (Germany).

2.4.4 UVB treatment study

An UVB lamp (G25T8E, Sankyo Denki) with peak emission at 306 nm was used for the generation of UVB radiation. For the UVB treatment study, the whole experiment was divided into two primary groups, i.e., UVB treated and UVB + H-110 treated. Each group was further subdivided into three subgroups according to UVB exposures, i.e., 5, 10, and 15 min according to ref. [17]. For each subgroup, primary mice skin cells were seeded at 6,000 cells/well on coverslip (3 wells) and 12,000 cells/well in other 3 wells of 6 well plates [thus 3 separate 6-well plates for 5′, 10′, and 15′ UVB treatment] for 24 h for acclimatization. After the completion of 24 h, every six-well plates was placed under UVB light of the self-made UVB chamber (Figure S1) for respective 5′, 10′, and 15′ UVB treatment. On the same day, the cells of the UVB + H-110 group were first layered and incubated with H-110 for 1 h inside the CO2 incubator. After 1 h, the cells were treated with UVB as described earlier. After all treatments, the cells seeded on the coverslips were fixed permeabilized and stained with DAPI, and the images were captured by a Carl Zeiss 780 LSM laser scanning confocal microscope (Germany) for cytological study. Other treated cells were processed for survival analysis through MTT assay.

2.5 In vivo mice model study

Two weeks prior to experimentations, all-female Swiss albino mice (N = 30) were maintained at 12 h light: 12 h dark cycle with 25 ± 2°C temperature at the Department of Zoology, Banaras Hindu University, Varanasi, Uttar Pradesh, India. All maintenance procedures along with experimentations were performed following the revised Animals Act Government of India, 2007, approved rules [Committee for the Purpose of Control and Supervision of Experiments on Animals (CPCSEA), Registration No. 1802/GO/Re/S/15/CPCSEA].

After acclimatization, animals were divided into six following groups with five animals in each group:

  1. Control (n = 5) – without any treatment,

  2. H-110 treated group (n = 5) – where a single layer of H-110 at the backside was applied to each animal,

  3. 3 days UVB-treated group (UV 3D, n = 5), treated with UVB for 20 min for 3 days,

  4. 5 days UVB-treated group (UV 5D, n = 5), treated with UVB for 20 min for 5 days,

  5. 3 days H-110 + UVB-treated group (H-110 + UV 3D, n = 5), where a single layer of H-110 at the backside was first applied and then the UVB treatment was given for 20 min for 3 days,

  6. 5 days H-110 + UVB-treated group (H-110 + UV 5D, n = 5), where a single layer of H-110 at the backside was first applied and then UVB treatment was given for 20 min for 5 days.

During treatment, mild ether anesthesia was continually given to the animals. After completion of the experimental periods, part of the treated skin was collected from each animal for further histoarchitectural analysis. No animals were sacrificed during this experimentation; as after skin collection, animals were given proper medical care to heal the wounds.

2.5.1 Morphometric analysis

For histological analysis, skin were immediately removed from each group of animals and fixed in 10% formalin, followed by dehydration, clearing with xylene, and finally processed in wax and sectioned (7 microns) for hematoxylin and eosin staining (HE staining) [39]. Histoarchitectures were observed under a research microscope (Nikon E 200, Japan) in randomly selected sections.

3 Results and discussion

3.1 Sol–gel–sol transformations of BSA hydrogel

BSA gels were prepared at different hydrothermal temperatures varying from 25 to 120°C with the 40 mg/mL protein concentration without using any cross-linker or chemical agent. At 25°C, the BSA solution does not go for the gelation process even after 15 h of heating, and the resultant has the same sol phase as the BSA initial solution. Further heating at 60°C, the turbidity of the solution is increased; however, no gelation occurs. One of the plausible reasons is that below the melting temperature (63°C), protein starts to unfold and thermal energy and electrostatic forces between the amino acid start to encounter each other during the hydrothermal process [40]. The melting temperature of the BSA is above 63°C, so the BSA solution was heated at 70°C hydrothermally for 15 h. Heating protein solution at a temperature of 70°C changed the turbid sol phase into a very fine gel, and this gel phase remains till the temperature of 100°C. Further heating of the protein solution above 110°C leads to the formation of new phases, and the phase separation between sol and gel was observed. The major portion of the protein solution changes into gel but the color of the gel becomes brownish and the remaining liquid was white. When the protein solution was heated to 120°C, the whole protein solution was converted into a sol phase and shows the physical and optical properties of carbon quantum dots. All the phases of the BSA are shown in Figure 1.

Figure 1 Different phases of developed BSA hydrogel at different temperatures.
Figure 1

Different phases of developed BSA hydrogel at different temperatures.

The sol–gel–sol phase transition as a function of temperature was tested using the tube inversion method. Thermally elevated phases of BSA show sol-to-gel and gel-to-sol transformation at 70 and 120°C, respectively. The melting temperature of BSA is 63°C, and studies show that BSA has different oligomeric states above and below its melting temperature [41]. The heating of proteins above melting temperature results in weakening the hydrogen bonds and strengthening the hydrophobic interaction which alters the diffusion, accessibility, and exposure of polypeptide chains segment and dilutes the ligand binding properties [42]. Interactions between electrostatic and hydrophobic interaction result in connecting the protein molecules and led to form a gel-like structure. The aggregation of BSA can be elevated with temperature, pH, ionic strength, and other external stimuli. These factors play a significant role in the transition temperature of the various phases. As we heat the protein solution at a higher temperature, the strength of the gel decreases, which was further supported by rheological studies and a tube inversion test. At high temperatures, interactions present between the gels start to break, and gel-to-sol phase transition happens. Physical and optical characterizations of the sol phase confirm the nanostructure of the carbon quantum dots that are homogeneously dispersed in the medium [42,38]. Thus, different phases of BSA hydrogels have been synthesized using a single hydrothermal technique just by varying temperatures without the addition of a cross-linker molecule.

3.2 Optical characterization of various phases of BSA hydrogels

It was observed that all the BSA hydrogels synthesized at various temperatures show different colors in appearance. As the heating temperature increases, there is a change in color. It becomes a transparent solution to translucent white in the gel phase and dense yellow in the CQDs phase. UV-Vis spectroscopy was used to analyze the optical changes shown in Figure 2(a). UV-Vis spectra of H-25 (hydrogel synthesized at 25°C) show the typical characteristic peak of BSA observed at 278 nm. As there is an increase in the temperature, protein starts to aggregate and forms a gel. H-70 (hydrogel synthesized at 70°C) and H-110 (hydrogel synthesized at 110°C) also show the BSA peak but absorb in a broader range from UV to visible, which make them a suitable candidate for skin protection from UVB (Figure S2(a)). H-110 shows a new peak at 340 nm, which reveals the possibility that there might be a generation of new fluorescent compounds during the gelation process. H-120 shows the characteristic peak of CQDs at 275 nm which is due to the π–π* electronic transition of C═C on the CQDs surface. The board absorbance shows the presence of a large number of functional moieties present on the surface. Figure 2(b) shows the auto-fluorescence property of various phases of BSA. It is well established that BSA has blue auto-fluorescence because of the aromatic amino acids such as tyrosine, tryptophan, and phenylalanine [43]. The emission spectra of H-25 and H-60 show intrinsic fluorescence such as BSA solution centered at 340–350 nm with the excitation wavelength of 280 nm. The excitation spectrum is also centered at 270–290 nm and does not show long-range excitation. Moreover, the gel phases of the BSA (H-70 to H-110) exhibit a strong fluorescence at 450 nm when excited with 365 nm. The PL spectrum of the gels (Figure S2(b)) shows a redshift in excitation and emission compared to the sol phase. The emission spectrum ranges from 400 to 550 nm for emission with the broad excitation wavelength ranging from 325 to 375 nm. This phenomenon can be explained by the fact that the heating of the protein reduces the steric hindrance of peptide chains and exposed the aromatic amino acids that can favor the energy transfer among the C═C and C═O bonds that existed in the protein as well as the proximity of amine groups. Another reason could be the formation of new fluorophores that have been promoted by the temperature-induced gelation process. The intensity of the fluorescence also increases with the hydrothermal temperature but does not show a strong redshift. Due to the presence of a larger number of amino acids and the non-availability of information regarding their interactions, it is difficult to probe the accurate reason for the red-shifted and high auto-fluorescence intensity in hydrogels. The CQDs phase of the BSA shows a blue shift in excitation and emission wavelength compared to the gel phase which can be tuned by concentration and excitation wavelength. Wavelength-dependent emission in CQDs can be due to the non-uniform size distribution in dispersive medium and various surface functional groups such as carboxyl, hydroxyl, and other oxygen species.

Figure 2 (a) UV-Vis spectrum of different phases of BSA protein; (b) PL spectrum of different phases of protein at their maximum excitation wavelength; (c) FTIR spectrum of different phases.
Figure 2

(a) UV-Vis spectrum of different phases of BSA protein; (b) PL spectrum of different phases of protein at their maximum excitation wavelength; (c) FTIR spectrum of different phases.

To get more insight into the involvement of various functional groups to form different phases of BSA at various temperatures, FTIR analysis has been performed. Full scan FITR spectra (4,000–500 cm−1) of all phases of BSA are shown in Figure 2(c). Intensity variation and small spectral shifts have been observed during the gelation process, and some new peaks have been observed when the gel phase is converted to CQDs. The broad peak at 3,500 cm−1 corresponds to the amide II bond due to the N–H stretching present in all the phases. From the sol-to-gel transition, only the peak becomes broader, but during the gel to CQDs transition, new peak occurs at 3,252 cm−1 corresponding to the N–H bond of the amine (–NH2) group. Amide band (1,400–1,700 cm−1) exists during both phase transitions and supports the fact that the protein main chain remains intact after heating at high temperature [44]. Peaks due to amide I bond C═O stretch at 1,650 cm−1 become strong with gel formation but amide II bond (C–N stretch coupled with N–H bending) at 1,580 cm−1 disappears in gel; however, it becomes stronger in the CQD phase. The decrease of amide II at approximately 1,580 cm−1 and increase of Amide II at approximately 1,450 cm−1 are related, which shows the conformational changes at a tertiary structural level. CQDs are nano-dimensional structural with an exposed functional group on the surface. The very strong peak around 1,400 cm−1 in the CQD phase corresponds to the symmetric stretching vibration of COO–, which disappear in gel form due to the CO–NH bond formation and also the peak at 1,093 cm−1 due to C–O vibration becomes prominent in the CQD phase. The limitation of the FTIR instrument investigation of new chemical bond formation overrules and limits the accurate analysis of the sol-to-gel transition.

SAXS has been performed on the samples prepared namely H-25, H-60, H-70, H-90, H-110, and H-120. No gel formation was observed in the samples prepared at the temperatures 25 and 60°C, and they remained in the solution state. On the other hand, gel formation was observed in the samples, which was prepared above the transition temperature. Raw data for the samples are shown in Figure 3(a). Sample H-25 shows a characteristic curve for a sphere. BSA in the solution state was found to form a globular structure, and the radius of the globule has been calculated by fitting the spherical model. The calculated radius of the BSA is found to be 3.198 nm. The fitted data are shown in Figure 3(b).

Figure 3 (a) Small-angle X-ray diffraction analysis of all phases of BSA protein; (b) shows that fitting of the SAXS of the H-25 samples using the spherical model; (c) H-60 is prepared near the transition temperature, SAXS for H-60 is fitted using the combination of Lorentz and Guinier equation; (d) shows the fitting of H-70, H-90 and H-110 using the Lorentz and porod fitting.
Figure 3

(a) Small-angle X-ray diffraction analysis of all phases of BSA protein; (b) shows that fitting of the SAXS of the H-25 samples using the spherical model; (c) H-60 is prepared near the transition temperature, SAXS for H-60 is fitted using the combination of Lorentz and Guinier equation; (d) shows the fitting of H-70, H-90 and H-110 using the Lorentz and porod fitting.

For the sample H-60, it is near the phase-transition temperature. It was observed that it was neither showing the characteristic curve for a sphere nor a gel. As the samples are prepared near the phase transition temperature, it can be assumed that SAXS data will be a combination of both the solution state sample and hydrogels. The mathematical equation used to fit the curve is given by equation (1) [45]:

(1) I ( q ) = I ( 0 ) C 1 + [ ( D + 1 3 ( q 2 a 1 2 ) ) ] D 2 + I ( 0 ) G e x p ( q 2 a 2 2 ) ,

where I(0) is the scaling factor, C is the Lorentz scale, G is the Guinier scale, a 1 is the correlation length, a 2 is related to the radius of gyration of the globule structures of the BSA formed and can be given as a 2 2 = R g 2 /3, and D is the fractal dimension of the system.

The fitted curve for the H-60 is shown in Figure 3(c). Fitted parameters for the H-60 are listed in Table S1. The value of D indicates the solvent condition. D value greater than 2 indicates a bad solvent condition; D value less than 2 indicates that the BSA is in good solvent condition and equal to 2 indicates that BSA is in the theta solvent condition. For the H-60 sample, the value of D is 1.75 which is close to the value of 5/3 indicating that the BSA below the transition temperature is in good solvent condition. a 1 indicates the mesh size of the crosslinks formed. The fitted mess size comes out to be 22 nm. The R g 2 value calculated is 5.9 nm. From this fitted data, it can be confirmed that near the transition temperature BSA molecules start to swell and start to form the network. The force between the molecules is not strong enough to form a strong network of BSA. Thus, there is a possibility of the existence of both globular structures along with a mesh. For gel samples, namely H-70, H-90, and H-110 fitted data are shown in Figure 3(d). To fit the experimental data, equation (2) has been used [46,47,48].

(2) I ( q ) = A q n + C ( 1 + ( q a 1 ) m ,

where A is the porod constant, C is the Lorentz constant, n is the porod factor, m is the Lorentz factor, and a 1 is the mesh size.

The fitting parameters are shown in Table S2. n is the factor that corresponds to t homogeneity of the system. n value above 2 indicates that formed gels are homogeneous. As the temperature is increased, the value of n also increases indicating that with an increase in temperature, BSA molecules unfold and form a homogeneous structure. For H-70, as the temperature is closer to the transition temperature, n is a little less than 2 which indicates that the gel structure is not fully homogeneous and the interaction between the molecules to form the crosslinks is not strong enough. For samples H-90 and H-110, the n value is above 2, and it indicates that the samples are homogeneous, and the bonds are strong enough to form the crosslinks to form stable hydrogels.

Lorentz part of the curve has two parameters m and a 1 . Lorentz factor m suggests the interaction of the molecules with the solvent. m above the value of 2 indicates that the molecules are in poor solvent condition, and the interaction between the molecules is dominating. As the temperature is increased, m value also increases indicating that the molecules are coming together to form the denser crosslinks. a 1 . value is found to decrease with an increase in temperature which tells us that the distance between the crosslinks is decreasing. Therefore, this indicates that gels formed at higher temperatures are much denser. Also, for the H-70 sample, as the temperature is near the phase transition, mess size is larger when compared with samples prepared at a higher temperature. This indicates that gels formed are not very dense, and the bonding between the molecules is not strong enough to form denser gels. For H-120, SAXS scattering is very weak and is very close to the background; so, it is not possible to analyze the same.

To investigate the surface morphology and mechanical strength of the temperature elevated self-assembled hydrogels, SEM and rheology studies were employed. The SEM images of lyophilized powder of BSA hydrogels (H-70, H-90, H-110) are shown in Figure 4(a)–(c). All hydrogel phases exhibit a three-dimensional highly porous honeycomb-like structure with irregularities in shape and size. During the lyophilization process, water gets evaporated and lefts the voids between the interconnected areas [49]. As there is an increase in the hydrothermal temperature, the pore size of the hydrogels gets smaller. Relative decreases in pore size of hydrogels are shown in Figure 4(d).

Figure 4 SEM images of hydrogel: (a) H-70; (b) H-90; (c) H-110; and (d) histogram of the area of voids.
Figure 4

SEM images of hydrogel: (a) H-70; (b) H-90; (c) H-110; and (d) histogram of the area of voids.

3.3 Rheological analysis

Rheological studies have been performed to investigate the viscoelastic behavior of the hydrogels. Strain sweep test and frequency sweep test were performed to get insight into change in storage and loss modulus of gels as a function of strain and frequency. To evaluate the limits of the viscoelastic region, strain sweep tests were carried out on all the hydrothermally synthesized gel phases of BSA. In the linear viscoelastic region, the storage modulus G′ and viscous modulus G′′ are independent of strain and frequency [50]. Under higher strain conditions, the stress response of the gels is no longer sinusoidal, and similarly, higher harmonic contributions lead to a nonlinear stress–strain relationship. In the case of the strain sweep test, G′ and G′′ were plotted as a function of strain (%). As we increase the hydrothermal temperature from 70 to 90°C, both G′ and G′′ increase linearly as shown in Figure 5(a). However, at 100°C, the G′ and G′′ start to decrease, which suggests that due to the hydrothermal process, the lower-order structure starts to form that alters the viscoelastic property of hydrogel. Also, for the H-110 phase, we are getting similar viscoelastic trends as H-70. Additionally, in the case of the frequency sweep test, both G′ and G′′ moduli also increase as we increase the temperature from 70 to 110°C (Figure 5(b)). The higher values of G′ over G′′ indicate that the elastic component is predominant on the viscous one in a swiped frequency range.

Figure 5 (a) Strain sweep test: G′ and G′′ modulus as a function of strain and (b) frequency sweep test: G′ and G′′ modulus as a function of frequency.
Figure 5

(a) Strain sweep test: G′ and G′′ modulus as a function of strain and (b) frequency sweep test: G′ and G′′ modulus as a function of frequency.

3.4 Biological studies

3.4.1 Cell toxicity and cellular uptake analysis

BSA has been extensively used in biomedical applications due to its higher bioavailability, biocompatibility, and biodegradability properties [51]. Herein, our objective was to study the cytotoxicity aspect of synthesized BSA hydrogel using BSA at various temperatures. In vitro, the biocompatibility of all hydrogel samples, i.e., H-25, H-60, H-70, H-80, H-90, H-100, H-110, H-120, and H-200. is studied and shown in Figure 6. The MTT assay results demonstrated that all samples showed the % cell survival between 93.6 and 99.16%, which suggests its excellent biocompatibility. Among all of them, H-110 showed the highest % cell survival of 99.16%.

Figure 6 Cell viability study of hydrogel samples for 24 h. Vertical bars representing mean ± SEM. Significance was tested using one-way ANOVA followed by Tukey post-hoc test.
Figure 6

Cell viability study of hydrogel samples for 24 h. Vertical bars representing mean ± SEM. Significance was tested using one-way ANOVA followed by Tukey post-hoc test.

Cellular uptake studies further confirm its good bioimaging green autofluorescence capacity in all hydrogel samples. Interestingly, H-110 has shown maximum cellular penetration (Figure 7) with a higher cytoplasmic and nuclear distribution. Hence, we have applied H-110 for further experimental studies.

Figure 7 Confocal imaging of cellular uptake of H-60, H-70, H-80, H-90, H-100, and H-110.
Figure 7

Confocal imaging of cellular uptake of H-60, H-70, H-80, H-90, H-100, and H-110.

3.4.2 Studying the protective role of H-110 on UVB induced cytological damaged primary skin cells

UVB attenuation activity of all the samples is tested and shown in Figure 8(a). All the gel phases have shown a significant reduction in UVB intensity. However, maximum attenuation is shown by H-110 with a density of 5 mg/cm2. The maximum UVB irradiance emitted by the UVB rod was 790 µW/cm2 at 11 cm away from the rod where all the UV attenuation studies were performed. The maximum attenuation is observed by H-110 hydrogel with a 36.7% decrease. Our MTT data have demonstrated aggressive normal skin cell death except UVB treated cells after all three-time points, i.e., 5, 10, and 15 min (P < 0.000, one-way ANOVA, followed by Tukey post-hoc test, Figure 8(b)). Minimum % cell survival was observed after 15 min UVB treatment (29.39 %) in comparison to control skin cells (P < 0.000, one-way ANOVA, followed by Tukey post-hoc test). No significant cell death was observed after 5 min UVB exposure in H-110 applied skin cells in comparison to control skin cells (P = 0.997, one-way ANOVA, followed by Tukey Posthoc test). After 20 and 15 min of UVB exposure, the H-110 applied cells showed 84.06 and 77.76% cell survival. Interestingly, the H-110 layer on skin cells significantly increased skin cell survival at 47.33, 39.09, and 50.36% after respective 5, 10, and 15 min UVB exposure (P < 0.000, one-way ANOVA, followed by Tukey Posthoc test) [52].

Figure 8 (a) UVB attenuation using different phases of BSA hydrogels, (b) protective role of H-110 from UVB-induced cytological damage primary skin cell culture by % cell viability assay, time-dependent experimental settings (5–15 min). Vertical bars representing mean ± SEM. Significance was tested using one-way ANOVA followed by Tukey Post-hoc test. The symbol * shows the significance level between control and only UVB, # shows the significance level between only UVB and H-110 + UVB, and @ shows the significance level between only control and H-110 + UVB. Data were considered statistically significant as ***/###/@@@ for P < 0.0001, **/##/@@ for P < 0.01, and */#/@ for P < 0.05.
Figure 8

(a) UVB attenuation using different phases of BSA hydrogels, (b) protective role of H-110 from UVB-induced cytological damage primary skin cell culture by % cell viability assay, time-dependent experimental settings (5–15 min). Vertical bars representing mean ± SEM. Significance was tested using one-way ANOVA followed by Tukey Post-hoc test. The symbol * shows the significance level between control and only UVB, # shows the significance level between only UVB and H-110 + UVB, and @ shows the significance level between only control and H-110 + UVB. Data were considered statistically significant as ***/###/@@@ for P < 0.0001, **/##/@@ for P < 0.01, and */#/@ for P < 0.05.

It was observed that the confocal imaging data (Figure 9) are also in the accordance with the results of the MTT assay with the protective role of H-110 after UVB treatment. In our study, with an increase of UVB exposure time to cells from 5 to 15 min, the intensity of emitted red fluorescence decreases. This might be due to the disruption of cellular components with increased time of UVB exposure as the morphology of cells was also changed toward dead cells at 15 min UVB exposed group. Previous studies have reported that the cell partially absorbs the smaller UV wavelength and emit a longer wavelength [52,53]. However, in the case of the H-110 applied group of cells, there was no significant morphological changes were observed after UVB exposure. Hence, this clearly shows that H-110 has the potential to protect the skin cells from UVB exposure.

Figure 9 Protective role of H-110 from UVB-induced cytological damage primary skin cell culture by confocal bioimaging, time-dependent experimental settings (5–15 min).
Figure 9

Protective role of H-110 from UVB-induced cytological damage primary skin cell culture by confocal bioimaging, time-dependent experimental settings (5–15 min).

3.4.3 In vivo protective role of H-110 on UVB-induced skin damage in mice

Our histological results with 3 days of UVB exposure (Figure 10(c)) showed no significant change, whereas 5 days of UVB exposure (Figure 10(d)) produced pathomorphological changes in the skin of mice, i.e., significant thickening of stratum corneum (SC) and epidermis (Tep, P < 0.000), and perivascular edema (Ed) in the dermis was prominent. At H-110, the monolayer applied group showed no significant morphometric changes after 3 days of UVB exposure (Figure 10(e)). Interestingly, 5 days of UVB exposure at H-110 monolayer (Figure 10(f)) applied group showed significant epidermal thickening as compared with the control tissues (P < 0.007); however, when the epidermal thickness of H110 + UV5D skin tissues was compared with the epidermal thickness of the UV5D skin tissue, the epiderma was significantly thinner in the H-110 + UV5D skin tissue (P < 0.000, Figure 10(g)). Hence, our mice model study also supports our finding that the topical administration of H-110 is potentially effective in protecting the skin from UVB-induced skin damage.

Figure 10 Transverse section showing histoarchitecture of skin tissue of M. musculus: (a) control, (b) H-110 treated, (c) UVB treated for 3 days, (d) UVB treated for 5 days, (e) H-110 + UV treated for 3 days, and (f) H-110 + UV treated for 5 days; Ep represents epidermis, Sc represents stratum corneum, Tep represents thickening epidermis, and Ed represents edema. (g) The vertical bar represents the epidermal thickness of different treatment groups (mean ± SEM). Significance was tested using one-way ANOVA followed by Tukey post-hoc test. The symbol * shows the significance level between control and only UVB 5 days, # shows the significance level between control and H-110 + UVB 5 days, and @ shows the significance level between only UVB 5 days and H-110 + UVB 5 days. Data were considered statistically significant as ***/###/@@@ for P < 0.0001.
Figure 10

Transverse section showing histoarchitecture of skin tissue of M. musculus: (a) control, (b) H-110 treated, (c) UVB treated for 3 days, (d) UVB treated for 5 days, (e) H-110 + UV treated for 3 days, and (f) H-110 + UV treated for 5 days; Ep represents epidermis, Sc represents stratum corneum, Tep represents thickening epidermis, and Ed represents edema. (g) The vertical bar represents the epidermal thickness of different treatment groups (mean ± SEM). Significance was tested using one-way ANOVA followed by Tukey post-hoc test. The symbol * shows the significance level between control and only UVB 5 days, # shows the significance level between control and H-110 + UVB 5 days, and @ shows the significance level between only UVB 5 days and H-110 + UVB 5 days. Data were considered statistically significant as ***/###/@@@ for P < 0.0001.

4 Conclusion

Using a simple and efficient hydrothermal method, a wide range of phases varying from sol–gel–sol of BSA hydrogel were synthesized. This is the first-of-this-kind of study wherein we observed that even without using cross-linkers, we can synthesize different phases of protein by varying the hydrothermal temperature. Extensive physico-chemical and optical characterization data of synthesized hydrogels has shown its potential application as a UVB blocker for skin protection. To ensure, in vitro cytotoxicity and UV protection ability of hydrogels were tested using primary skin cells. Among all, the H-110 sample has shown extraordinary applicability. Thus, in vivo protective role of H-110 on UVB-induced skin damage in the mice model was studied, and the results have confirmed that the topical administration of H-110 is potentially effective in protecting the skin from UVB-induced skin damages. The present study ensures that using BSA protein as a precursor, it is possible to prepare hydrogels with various functionalities, no cytotoxicity and it holds a prominent role in the biomedical field for the protection of skin and in the cure of skin cancer.

  1. Funding information: The authors would like to thank the Department of Science and Technology (SERB), India-CRG/2019/000903 (Core research Grant) & SB/S2/RJN-140/2014 (Ramanujan Fellowship Award) for the financial support of this study.

  2. Author contributions: Kanchan Yadav: Conception or design of the work, data collection, data analysis, and interpretation, drafting the article; Megha Das: data collection, data analysis, and interpretation, drafting the manuscript; Nitesh Kumar Mishra: data collection; Anuj Chhabra: data collection, data analysis, and interpretation; Archana Mishra: drafting the manuscript, data analysis and interpretation; Sunita Srivastava: data analysis and interpretation; Poonam Sharma: resource, editing of the manuscript; Sanjeev Kumar Yadav: data analysis and interpretation; Avanish Singh Parmar: conception or design of the work, drafting of the manuscript, funding, and resources. All authors have accepted responsibility for the entire content of this manuscript and approved its submission.

  3. Conflict of interest: The authors state no conflict of interest.

  4. Ethical approval: All maintenance procedures along with experimentations were performed following the revised Animals Act Government of India, 2007 approved rules [Committee for the Purpose of Control and Supervision of Experiments on Animals (CPCSEA), Registration No.-1802/GO/Re/S/15/CPCSEA].

References

[1] D’Orazio J, Jarrett S, Amaro-Ortiz A, Scott T. UV radiation and the skin. Int J Mol Sci. 2013;14(6):12222–48. 10.3390/ijms140612222.Search in Google Scholar PubMed PubMed Central

[2] Sanford JA, Gallo RL. Functions of the skin microbiota in health and disease. Semin Immunol. 2013;25(5):370. 10.1016/J.SMIM.2013.09.005.Search in Google Scholar PubMed PubMed Central

[3] Med CC. Ultraviolet radiation exposure and its impact on skin cancer risk. 2015;40(4):1291–6. 10.1097/CCM.0b013e31823da96d.Hydrogen.Search in Google Scholar

[4] Teresa M, Petersen S, Prakash G. UV light effects on proteins: from photochemistry to nanomedicine. Mol Photochem – Var Asp. 2012;37947:1–36. 10.5772/37947.Search in Google Scholar

[5] Harrison SC, Bergfeld WF. Ultraviolet light and skin cancer in athletes. Sports Health. 2009;1(4):335–40. 10.1177/1941738109338923.Search in Google Scholar PubMed PubMed Central

[6] Craig S, Earnshaw CH, Virós A. Ultraviolet light and melanoma. J Pathol. 2018;244(5):578–85. 10.1002/path.5039.Search in Google Scholar PubMed

[7] Fontanillas P, Alipanahi B, Furlotte NA, Johnson M, Wilson CH, Pitts SJ, et al. Disease risk scores for skin cancers. Nat Commun. 2021;12(1):1–13. 10.1038/s41467-020-20246-5.Search in Google Scholar PubMed PubMed Central

[8] Siegel RL, Miller KD, Fuchs HE, Jemal A. Cancer statistics, 2021. CA Cancer J Clin. 2021;71(1):7–33. 10.3322/CAAC.21654.Search in Google Scholar

[9] Nehal KS, Bichakjian CK. Update on keratinocyte carcinomas. N Engl J Med. 2018;379(4):363–74. 10.1056/NEJMRA1708701/SUPPL_FILE/NEJMRA1708701_DISCLOSURES.PDF.Search in Google Scholar

[10] Diepgen TL, Mahler V. The epidemiology of skin cancer. Br J Dermatol. 2002;146(s61):1–6. 10.1046/J.1365-2133.146.S61.2.X.Search in Google Scholar PubMed

[11] Xu L, Wu D, Zhou B, Xu Y, Wang W, Yu D, et al. Microencapsulated sunblock nanoparticles based on zeolitic imidazole frameworks for safe and effective UV protection. RSC Adv. 2018;8(22):12315–21. 10.1039/c8ra00632f.Search in Google Scholar PubMed PubMed Central

[12] Pristovnik M, Maver U, Orthaber K, Skok K, Perić B. Skin cancer and its treatment: novel treatment approaches with emphasis on nanotechnology. J Nanomater. 2017;2017:1–20. 10.1155/2017/2606271.Search in Google Scholar

[13] Jose J, Netto G. Role of solid lipid nanoparticles as photoprotective agents in cosmetics. J Cosmet Dermatol. 2019;18(1):315–21. 10.1111/jocd.12504.Search in Google Scholar PubMed

[14] Lu PJ, Fang SW, Cheng WL, Huang SC, Huang MC, Cheng HF. Characterization of titanium dioxide and zinc oxide nanoparticles in sunscreen powder by comparing different measurement methods. J Food Drug Anal. 2018;26(3):1192–200. 10.1016/J.JFDA.2018.01.010.Search in Google Scholar PubMed PubMed Central

[15] Singh P, Nanda A. Enhanced sun protection of nano-sized metal oxide particles over conventional metal oxide particles: an in vitro comparative study. Int J Cosmet Sci. 2014;36(3):273–83. 10.1111/ICS.12124.Search in Google Scholar PubMed

[16] Vitiello G, Zanfardino A, Tammaro O, Di Napoli M, Caso MF, Pezzella A, et al. Bioinspired hybrid eumelanin-TiO2 antimicrobial nanostructures: the key role of organo-inorganic frameworks in tuning eumelanin’s biocide action mechanism through membrane interaction. RSC Adv. 2018;8(50):28275–83. 10.1039/c8ra04315a.Search in Google Scholar PubMed PubMed Central

[17] Wu MS, Sun DS, Lin YC, Cheng CL, Hung SC, Chen PK, et al. Nanodiamonds protect skin from ultraviolet B-induced damage in mice. J Nanobiotechnol. 2015;13(1):1–12. 10.1186/s12951-015-0094-4.Search in Google Scholar PubMed PubMed Central

[18] Vishnubhakthula S, Elupula R, Durán-Lara EF. Recent advances in hydrogel-based drug delivery for melanoma cancer therapy: a mini review. J Drug Deliv. 2017;2017:1–9. 10.1155/2017/7275985.Search in Google Scholar PubMed PubMed Central

[19] Rigon RB, Oyafuso MH, Fujimura AT, Gonçalez ML, Prado AH, Gremião MP, et al. Nanotechnology-based drug delivery systems for melanoma antitumoral therapy: a review. Biomed Res Int. 2015;2015:16–20. 10.1155/2015/841817.Search in Google Scholar PubMed PubMed Central

[20] Tang JQ, Hou XY, Yang CS, Li YX, Xin Y, Guo WW, et al. Recent developments in nanomedicine for melanoma treatment. Int J Cancer. 2017;141(4):646–53. 10.1002/ijc.30708.Search in Google Scholar PubMed

[21] Vyas A, Das SK, Singh D, Sonker A, Gidwani B, Jain V, et al. Recent nanoparticuulate approches of drug delivery for skin cancer. Trends Appl Sci Res. 2012;7:620–35.10.3923/tasr.2012.620.635Search in Google Scholar

[22] Chang Z, Zhang S, Li F, Wang Z, Li J, Xia C, et al. Self-healable and biodegradable soy protein-based protective functional film with low cytotoxicity and high mechanical strength. Chem Eng J. 2021;404:126505. 10.1016/J.CEJ.2020.126505.Search in Google Scholar

[23] Kumar M, Sanford KJ, Cuevas WP, Du M, Collier KD, Chow N. Designer protein-based performance materials. Biomacromolecules. 2006;7(9):2543–51. 10.1021/BM060464A.Search in Google Scholar

[24] Debele TA, Su WP. Polysaccharide and protein-based functional wound dressing materials and applications. 2020;71:87–108. 10.1080/00914037.2020.1809403.Search in Google Scholar

[25] Zhang D, Wang Y. Functional protein-based bioinspired nanomaterials: from coupled proteins, synthetic approaches, nanostructures to applications. Int J Mol Sci. 2019;20(12):3054. 10.3390/IJMS20123054.Search in Google Scholar

[26] Mahler A, Reches M, Rechter M, Cohen S, Gazit E. Rigid, Self-assembled hydrogel composed of a modified aromatic dipeptide. Adv Mater. 2006;18(11):1365–70. 10.1002/ADMA.200501765.Search in Google Scholar

[27] Nagarajan S, Radhakrishnan S, Kalkura S, Balme S, Miele P, Bechelany M. Overview of protein-based biopolymers for biomedical application. Macromol Chem Phys. 2019;220(14):1900126. 10.1002/MACP.201900126.Search in Google Scholar

[28] Xing Y, Cheng E, Yang Y, Chen P, Zhang T, Sun Y, et al. Self-assembled dna hydrogels with designable thermal and enzymatic responsiveness. Adv Mater. 2011;23(9):1117–21. 10.1002/adma.201003343.Search in Google Scholar PubMed

[29] Arabi SH, Aghelnejad B, Schwieger C, Meister A, Kerth A, Hinderberger D. Biomaterials science rsc.li/biomaterials-science serum albumin hydrogels in broad pH and temperature ranges: characterization of their self-assembled structures and nanoscopic and macroscopic properties. Biomater Sci. 2018;6:478. 10.1039/c7bm00820a.Search in Google Scholar PubMed

[30] Su TJ, Lu JR, Thomas RK, Cui ZF, Penfold J. The conformational structure of bovine serum albumin layers adsorbed at the silica−water interface. J Phys Chem B. 1998;102(41):8100–8. 10.1021/JP981239T.Search in Google Scholar

[31] Jayabharathi J, Thanikachalam V, Venkatesh Perumal M. Mechanistic investigation on binding interaction of bioactive imidazole with protein bovine serum albumin—a biophysical study. Spectrochim Acta Part A Mol Biomol Spectrosc. 2011;79(3):502–7. 10.1016/J.SAA.2011.03.020.Search in Google Scholar PubMed

[32] Wu X, Lv L, Han X, Li C. Bovine serum albumin fibrous biofilm template synthesis of metallic nanomeshes for surface-enhanced Raman scattering and electrocatalytic detection. Mater Des. 2020;192:108777. 10.1016/J.MATDES.2020.108777.Search in Google Scholar

[33] Yuan H, Zheng X, Liu W, Zhang H, Shao J, Yao J, et al. A novel bovine serum albumin and sodium alginate hydrogel scaffold doped with hydroxyapatite nanowires for cartilage defects repair. Colloids Surfaces B Biointerfaces. 2020;192:111041. 10.1016/J.COLSURFB.2020.111041.Search in Google Scholar

[34] Zewde B, Atoyebi O, Gugssa A, Gaskell KJ, Raghavan D. An investigation of the interaction between bovine serum albumin-conjugated silver nanoparticles and the hydrogel in hydrogel nanocomposites. ACS Omega. 2021;6(17):11614–27. 10.1021/ACSOMEGA.1C00834/SUPPL_FILE/AO1C00834_SI_001.PDF.Search in Google Scholar

[35] Upadhyay A, Narula A, Rao CP. Copper-based metallogel of bovine serum albumin and its derived hybrid biomaterials as aerogel and sheet: comparative study of the adsorption and reduction of dyes and nitroaromatics. ACS Appl Bio Mater. 2020;3(12):8619–26. 10.1021/ACSABM.0C01028/SUPPL_FILE/MT0C01028_SI_001.PDF.Search in Google Scholar

[36] Phan VHG, Le TMD, Janarthanan G, Ngo PKT, Lee DS, Thambi T. Development of bioresorbable smart injectable hydrogels based on thermo-responsive copolymer integrated bovine serum albumin bioconjugates for accelerated healing of excisional wounds. J Ind Eng Chem. 2021;96:345–55. 10.1016/J.JIEC.2021.01.041.Search in Google Scholar

[37] Henrot P, Laurent P, Levionnois E, Leleu D, Pain C, Truchetet ME, et al. A method for isolating and culturing skin cells: application to endothelial cells, fibroblasts, keratinocytes, and melanocytes from punch biopsies in systemic sclerosis skin. Front Immunol. 2020;11:2408. 10.3389/FIMMU.2020.566607.Search in Google Scholar PubMed PubMed Central

[38] Yadav K, Das M, Hassan N, Mishra A, Lahiri J, Dubey A, et al. Synthesis and characterization of novel protein nanodots as drug delivery carriers with an enhanced biological efficacy of melatonin in breast cancer cells. RSC Adv. 2021;11(16):9076–85. 10.1039/D0RA08959A.Search in Google Scholar PubMed PubMed Central

[39] Shukla D, Das M, Kasade D, Pandey M, Dubey AK, Yadav SK, et al. Sandalwood-derived carbon quantum dots as bioimaging tools to investigate the toxicological effects of malachite green in model organisms. Chemosphere. 2020;248:125998. 10.1016/j.chemosphere.2020.125998.Search in Google Scholar PubMed

[40] Jiang B, Jain A, Lu Y, Hoag SW. Probing thermal stability of proteins with temperature scanning viscometer. Mol Pharm. 2019;16(8):3687–93. 10.1021/ACS.MOLPHARMACEUT.9B00598.Search in Google Scholar PubMed

[41] Michnik A, Michalik K, Drzazga Z. Stability of bovine serum albumin at different pH. J Therm Anal Calorim. 2005;80(2):399–406. 10.1007/S10973-005-0667-9.Search in Google Scholar

[42] Molodenskiy D, Shirshin E, Tikhonova T, Gruzinov A, Peters G, Spinozzi F. Thermally induced conformational changes and protein–protein interactions of bovine serum albumin in aqueous solution under different pH and ionic strengths as revealed by SAXS measurements. Phys Chem Chem Phys. 2017;19(26):17143–55. 10.1039/C6CP08809K.Search in Google Scholar

[43] Ma X, Sun X, Hargrove D, Chen J, Song D, Dong Q, et al. A biocompatible and biodegradable protein hydrogel with green and red autofluorescence: preparation, characterization and in vivo biodegradation tracking and modeling. Sci Rep. 2016;6(1):1–12. 10.1038/srep19370.Search in Google Scholar PubMed PubMed Central

[44] Arabi SH, Aghelnejad B, Schwieger C, Meister A, Kerth A, Hinderberger D. Serum albumin hydrogels in broad pH and temperature ranges: characterization of their self-assembled structures and nanoscopic and macroscopic properties. Biomater Sci. 2018;6(3):478–92. 10.1039/C7BM00820A.Search in Google Scholar

[45] Shibayama M, Tanaka T, Han CC. Small angle neutron scattering study on poly(N‐isopropyl acrylamide) gels near their volume‐phase transition temperature. J Chem Phys. 1998;97(9):6829. 10.1063/1.463636.Search in Google Scholar

[46] Hule RA, Nagarkar RP, Altunbas A, Ramay HR, Branco MC, Schneider JP, et al. Correlations between structure, material properties and bioproperties in self-assembled β-hairpin peptide hydrogels. Faraday Discuss. 2008;139:251. 10.1039/B717616C.Search in Google Scholar

[47] Surita S, Lackey MA, Griffin DM, Kishore S, Tew GN, Bhatia SR. SANS study of highly resilient poly(ethylene glycol) hydrogels. Soft Matter. 2014;10(12):1905–16. 10.1039/C3SM52395K.Search in Google Scholar PubMed PubMed Central

[48] Amdursky N, Mazo MM, Thomas MR, Humphrey EJ, Puetzer JL, St-Pierre JP, et al. Elastic serum-albumin based hydrogels: mechanism of formation and application in cardiac tissue engineering. J Mater Chem B. 2018;6(35):5604–12. 10.1039/C8TB01014E.Search in Google Scholar PubMed PubMed Central

[49] Bodenberger N, Kubiczek D, Abrosimova I, Scharm A, Kipper F, Walther P, et al. Evaluation of methods for pore generation and their influence on physio-chemical properties of a protein based hydrogel. Biotechnol Rep. 2016;12:6–12. 10.1016/J.BTRE.2016.09.001.Search in Google Scholar

[50] De Maria S, Ferrari G, Maresca P. Rheological characterization bovine serum albumin gels induced by high hydrostatic pressure. Food Nutr Sci. 2015;6(9):770–9. 10.4236/FNS.2015.69080.Search in Google Scholar

[51] Chen J, Ma X, Dong Q, Song D, Hargrove D, Vora SR, et al. Self-healing of thermally-induced, biocompatible and biodegradable protein hydrogel. RSC Adv. 2016;6(61):56183–92. 10.1039/C6RA11239K.Search in Google Scholar

[52] Allen M. Post hoc tests: tukey honestly significant difference test. SAGE Encycl Commun Res Methods. 2017;4:1–4. 10.4135/9781483381411.N452.Search in Google Scholar

[53] Notara M, Behboudifard S, Kluth MA, Maßlo C, Ganss C, Frank MH, et al. UV light-blocking contact lenses protect against short-term UVB-induced limbal stem cell niche damage and inflammation. Sci Rep. 2018;8(1):1–12. 10.1038/S41598-018-30021-8.Search in Google Scholar PubMed PubMed Central

Received: 2021-12-30
Revised: 2022-03-10
Accepted: 2022-03-28
Published Online: 2022-04-18

© 2022 Kanchan Yadav et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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  64. Elucidating the role of silicon dioxide and titanium dioxide nanoparticles in mitigating the disease of the eggplant caused by Phomopsis vexans, Ralstonia solanacearum, and root-knot nematode Meloidogyne incognita
  65. An implication of magnetic dipole in Carreau Yasuda liquid influenced by engine oil using ternary hybrid nanomaterial
  66. Robust synthesis of a composite phase of copper vanadium oxide with enhanced performance for durable aqueous Zn-ion batteries
  67. Tunning self-assembled phases of bovine serum albumin via hydrothermal process to synthesize novel functional hydrogel for skin protection against UVB
  68. A comparative experimental study on damping properties of epoxy nanocomposite beams reinforced with carbon nanotubes and graphene nanoplatelets
  69. Lightweight and hydrophobic Ni/GO/PVA composite aerogels for ultrahigh performance electromagnetic interference shielding
  70. Research on the auxetic behavior and mechanical properties of periodically rotating graphene nanostructures
  71. Repairing performances of novel cement mortar modified with graphene oxide and polyacrylate polymer
  72. Closed-loop recycling and fabrication of hydrophilic CNT films with high performance
  73. Design of thin-film configuration of SnO2–Ag2O composites for NO2 gas-sensing applications
  74. Study on stress distribution of SiC/Al composites based on microstructure models with microns and nanoparticles
  75. PVDF green nanofibers as potential carriers for improving self-healing and mechanical properties of carbon fiber/epoxy prepregs
  76. Osteogenesis capability of three-dimensionally printed poly(lactic acid)-halloysite nanotube scaffolds containing strontium ranelate
  77. Silver nanoparticles induce mitochondria-dependent apoptosis and late non-canonical autophagy in HT-29 colon cancer cells
  78. Preparation and bonding mechanisms of polymer/metal hybrid composite by nano molding technology
  79. Damage self-sensing and strain monitoring of glass-reinforced epoxy composite impregnated with graphene nanoplatelet and multiwalled carbon nanotubes
  80. Thermal analysis characterisation of solar-powered ship using Oldroyd hybrid nanofluids in parabolic trough solar collector: An optimal thermal application
  81. Pyrene-functionalized halloysite nanotubes for simultaneously detecting and separating Hg(ii) in aqueous media: A comprehensive comparison on interparticle and intraparticle excimers
  82. Fabrication of self-assembly CNT flexible film and its piezoresistive sensing behaviors
  83. Thermal valuation and entropy inspection of second-grade nanoscale fluid flow over a stretching surface by applying Koo–Kleinstreuer–Li relation
  84. Mechanical properties and microstructure of nano-SiO2 and basalt-fiber-reinforced recycled aggregate concrete
  85. Characterization and tribology performance of polyaniline-coated nanodiamond lubricant additives
  86. Combined impact of Marangoni convection and thermophoretic particle deposition on chemically reactive transport of nanofluid flow over a stretching surface
  87. Spark plasma extrusion of binder free hydroxyapatite powder
  88. An investigation on thermo-mechanical performance of graphene-oxide-reinforced shape memory polymer
  89. Effect of nanoadditives on the novel leather fiber/recycled poly(ethylene-vinyl-acetate) polymer composites for multifunctional applications: Fabrication, characterizations, and multiobjective optimization using central composite design
  90. Design selection for a hemispherical dimple core sandwich panel using hybrid multi-criteria decision-making methods
  91. Improving tensile strength and impact toughness of plasticized poly(lactic acid) biocomposites by incorporating nanofibrillated cellulose
  92. Green synthesis of spinel copper ferrite (CuFe2O4) nanoparticles and their toxicity
  93. The effect of TaC and NbC hybrid and mono-nanoparticles on AA2024 nanocomposites: Microstructure, strengthening, and artificial aging
  94. Excited-state geometry relaxation of pyrene-modified cellulose nanocrystals under UV-light excitation for detecting Fe3+
  95. Effect of CNTs and MEA on the creep of face-slab concrete at an early age
  96. Effect of deformation conditions on compression phase transformation of AZ31
  97. Application of MXene as a new generation of highly conductive coating materials for electromembrane-surrounded solid-phase microextraction
  98. A comparative study of the elasto-plastic properties for ceramic nanocomposites filled by graphene or graphene oxide nanoplates
  99. Encapsulation strategies for improving the biological behavior of CdS@ZIF-8 nanocomposites
  100. Biosynthesis of ZnO NPs from pumpkin seeds’ extract and elucidation of its anticancer potential against breast cancer
  101. Preliminary trials of the gold nanoparticles conjugated chrysin: An assessment of anti-oxidant, anti-microbial, and in vitro cytotoxic activities of a nanoformulated flavonoid
  102. Effect of micron-scale pores increased by nano-SiO2 sol modification on the strength of cement mortar
  103. Fractional simulations for thermal flow of hybrid nanofluid with aluminum oxide and titanium oxide nanoparticles with water and blood base fluids
  104. The effect of graphene nano-powder on the viscosity of water: An experimental study and artificial neural network modeling
  105. Development of a novel heat- and shear-resistant nano-silica gelling agent
  106. Characterization, biocompatibility and in vivo of nominal MnO2-containing wollastonite glass-ceramic
  107. Entropy production simulation of second-grade magnetic nanomaterials flowing across an expanding surface with viscidness dissipative flux
  108. Enhancement in structural, morphological, and optical properties of copper oxide for optoelectronic device applications
  109. Aptamer-functionalized chitosan-coated gold nanoparticle complex as a suitable targeted drug carrier for improved breast cancer treatment
  110. Performance and overall evaluation of nano-alumina-modified asphalt mixture
  111. Analysis of pure nanofluid (GO/engine oil) and hybrid nanofluid (GO–Fe3O4/engine oil): Novel thermal and magnetic features
  112. Synthesis of Ag@AgCl modified anatase/rutile/brookite mixed phase TiO2 and their photocatalytic property
  113. Mechanisms and influential variables on the abrasion resistance hydraulic concrete
  114. Synergistic reinforcement mechanism of basalt fiber/cellulose nanocrystals/polypropylene composites
  115. Achieving excellent oxidation resistance and mechanical properties of TiB2–B4C/carbon aerogel composites by quick-gelation and mechanical mixing
  116. Microwave-assisted sol–gel template-free synthesis and characterization of silica nanoparticles obtained from South African coal fly ash
  117. Pulsed laser-assisted synthesis of nano nickel(ii) oxide-anchored graphitic carbon nitride: Characterizations and their potential antibacterial/anti-biofilm applications
  118. Effects of nano-ZrSi2 on thermal stability of phenolic resin and thermal reusability of quartz–phenolic composites
  119. Benzaldehyde derivatives on tin electroplating as corrosion resistance for fabricating copper circuit
  120. Mechanical and heat transfer properties of 4D-printed shape memory graphene oxide/epoxy acrylate composites
  121. Coupling the vanadium-induced amorphous/crystalline NiFe2O4 with phosphide heterojunction toward active oxygen evolution reaction catalysts
  122. Graphene-oxide-reinforced cement composites mechanical and microstructural characteristics at elevated temperatures
  123. Gray correlation analysis of factors influencing compressive strength and durability of nano-SiO2 and PVA fiber reinforced geopolymer mortar
  124. Preparation of layered gradient Cu–Cr–Ti alloy with excellent mechanical properties, thermal stability, and electrical conductivity
  125. Recovery of Cr from chrome-containing leather wastes to develop aluminum-based composite material along with Al2O3 ceramic particles: An ingenious approach
  126. Mechanisms of the improved stiffness of flexible polymers under impact loading
  127. Anticancer potential of gold nanoparticles (AuNPs) using a battery of in vitro tests
  128. Review Articles
  129. Proposed approaches for coronaviruses elimination from wastewater: Membrane techniques and nanotechnology solutions
  130. Application of Pickering emulsion in oil drilling and production
  131. The contribution of microfluidics to the fight against tuberculosis
  132. Graphene-based biosensors for disease theranostics: Development, applications, and recent advancements
  133. Synthesis and encapsulation of iron oxide nanorods for application in magnetic hyperthermia and photothermal therapy
  134. Contemporary nano-architectured drugs and leads for ανβ3 integrin-based chemotherapy: Rationale and retrospect
  135. State-of-the-art review of fabrication, application, and mechanical properties of functionally graded porous nanocomposite materials
  136. Insights on magnetic spinel ferrites for targeted drug delivery and hyperthermia applications
  137. A review on heterogeneous oxidation of acetaminophen based on micro and nanoparticles catalyzed by different activators
  138. Early diagnosis of lung cancer using magnetic nanoparticles-integrated systems
  139. Advances in ZnO: Manipulation of defects for enhancing their technological potentials
  140. Efficacious nanomedicine track toward combating COVID-19
  141. A review of the design, processes, and properties of Mg-based composites
  142. Green synthesis of nanoparticles for varied applications: Green renewable resources and energy-efficient synthetic routes
  143. Two-dimensional nanomaterial-based polymer composites: Fundamentals and applications
  144. Recent progress and challenges in plasmonic nanomaterials
  145. Apoptotic cell-derived micro/nanosized extracellular vesicles in tissue regeneration
  146. Electronic noses based on metal oxide nanowires: A review
  147. Framework materials for supercapacitors
  148. An overview on the reproductive toxicity of graphene derivatives: Highlighting the importance
  149. Antibacterial nanomaterials: Upcoming hope to overcome antibiotic resistance crisis
  150. Research progress of carbon materials in the field of three-dimensional printing polymer nanocomposites
  151. A review of atomic layer deposition modelling and simulation methodologies: Density functional theory and molecular dynamics
  152. Recent advances in the preparation of PVDF-based piezoelectric materials
  153. Recent developments in tensile properties of friction welding of carbon fiber-reinforced composite: A review
  154. Comprehensive review of the properties of fly ash-based geopolymer with additive of nano-SiO2
  155. Perspectives in biopolymer/graphene-based composite application: Advances, challenges, and recommendations
  156. Graphene-based nanocomposite using new modeling molecular dynamic simulations for proposed neutralizing mechanism and real-time sensing of COVID-19
  157. Nanotechnology application on bamboo materials: A review
  158. Recent developments and future perspectives of biorenewable nanocomposites for advanced applications
  159. Nanostructured lipid carrier system: A compendium of their formulation development approaches, optimization strategies by quality by design, and recent applications in drug delivery
  160. 3D printing customized design of human bone tissue implant and its application
  161. Design, preparation, and functionalization of nanobiomaterials for enhanced efficacy in current and future biomedical applications
  162. A brief review of nanoparticles-doped PEDOT:PSS nanocomposite for OLED and OPV
  163. Nanotechnology interventions as a putative tool for the treatment of dental afflictions
  164. Recent advancements in metal–organic frameworks integrating quantum dots (QDs@MOF) and their potential applications
  165. A focused review of short electrospun nanofiber preparation techniques for composite reinforcement
  166. Microstructural characteristics and nano-modification of interfacial transition zone in concrete: A review
  167. Latest developments in the upconversion nanotechnology for the rapid detection of food safety: A review
  168. Strategic applications of nano-fertilizers for sustainable agriculture: Benefits and bottlenecks
  169. Molecular dynamics application of cocrystal energetic materials: A review
  170. Synthesis and application of nanometer hydroxyapatite in biomedicine
  171. Cutting-edge development in waste-recycled nanomaterials for energy storage and conversion applications
  172. Biological applications of ternary quantum dots: A review
  173. Nanotherapeutics for hydrogen sulfide-involved treatment: An emerging approach for cancer therapy
  174. Application of antibacterial nanoparticles in orthodontic materials
  175. Effect of natural-based biological hydrogels combined with growth factors on skin wound healing
  176. Nanozymes – A route to overcome microbial resistance: A viewpoint
  177. Recent developments and applications of smart nanoparticles in biomedicine
  178. Contemporary review on carbon nanotube (CNT) composites and their impact on multifarious applications
  179. Interfacial interactions and reinforcing mechanisms of cellulose and chitin nanomaterials and starch derivatives for cement and concrete strength and durability enhancement: A review
  180. Diamond-like carbon films for tribological modification of rubber
  181. Layered double hydroxides (LDHs) modified cement-based materials: A systematic review
  182. Recent research progress and advanced applications of silica/polymer nanocomposites
  183. Modeling of supramolecular biopolymers: Leading the in silico revolution of tissue engineering and nanomedicine
  184. Recent advances in perovskites-based optoelectronics
  185. Biogenic synthesis of palladium nanoparticles: New production methods and applications
  186. A comprehensive review of nanofluids with fractional derivatives: Modeling and application
  187. Electrospinning of marine polysaccharides: Processing and chemical aspects, challenges, and future prospects
  188. Electrohydrodynamic printing for demanding devices: A review of processing and applications
  189. Rapid Communications
  190. Structural material with designed thermal twist for a simple actuation
  191. Recent advances in photothermal materials for solar-driven crude oil adsorption
https://doi.org/10.1515/ntrev-2022-0102
Keywords for this article
hydrogel; self-assembly; skin protection; UVB
Creative Commons
BY 4.0

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  70. Research on the auxetic behavior and mechanical properties of periodically rotating graphene nanostructures
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  78. Preparation and bonding mechanisms of polymer/metal hybrid composite by nano molding technology
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  80. Thermal analysis characterisation of solar-powered ship using Oldroyd hybrid nanofluids in parabolic trough solar collector: An optimal thermal application
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  84. Mechanical properties and microstructure of nano-SiO2 and basalt-fiber-reinforced recycled aggregate concrete
  85. Characterization and tribology performance of polyaniline-coated nanodiamond lubricant additives
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  89. Effect of nanoadditives on the novel leather fiber/recycled poly(ethylene-vinyl-acetate) polymer composites for multifunctional applications: Fabrication, characterizations, and multiobjective optimization using central composite design
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  98. A comparative study of the elasto-plastic properties for ceramic nanocomposites filled by graphene or graphene oxide nanoplates
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  101. Preliminary trials of the gold nanoparticles conjugated chrysin: An assessment of anti-oxidant, anti-microbial, and in vitro cytotoxic activities of a nanoformulated flavonoid
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  103. Fractional simulations for thermal flow of hybrid nanofluid with aluminum oxide and titanium oxide nanoparticles with water and blood base fluids
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  106. Characterization, biocompatibility and in vivo of nominal MnO2-containing wollastonite glass-ceramic
  107. Entropy production simulation of second-grade magnetic nanomaterials flowing across an expanding surface with viscidness dissipative flux
  108. Enhancement in structural, morphological, and optical properties of copper oxide for optoelectronic device applications
  109. Aptamer-functionalized chitosan-coated gold nanoparticle complex as a suitable targeted drug carrier for improved breast cancer treatment
  110. Performance and overall evaluation of nano-alumina-modified asphalt mixture
  111. Analysis of pure nanofluid (GO/engine oil) and hybrid nanofluid (GO–Fe3O4/engine oil): Novel thermal and magnetic features
  112. Synthesis of Ag@AgCl modified anatase/rutile/brookite mixed phase TiO2 and their photocatalytic property
  113. Mechanisms and influential variables on the abrasion resistance hydraulic concrete
  114. Synergistic reinforcement mechanism of basalt fiber/cellulose nanocrystals/polypropylene composites
  115. Achieving excellent oxidation resistance and mechanical properties of TiB2–B4C/carbon aerogel composites by quick-gelation and mechanical mixing
  116. Microwave-assisted sol–gel template-free synthesis and characterization of silica nanoparticles obtained from South African coal fly ash
  117. Pulsed laser-assisted synthesis of nano nickel(ii) oxide-anchored graphitic carbon nitride: Characterizations and their potential antibacterial/anti-biofilm applications
  118. Effects of nano-ZrSi2 on thermal stability of phenolic resin and thermal reusability of quartz–phenolic composites
  119. Benzaldehyde derivatives on tin electroplating as corrosion resistance for fabricating copper circuit
  120. Mechanical and heat transfer properties of 4D-printed shape memory graphene oxide/epoxy acrylate composites
  121. Coupling the vanadium-induced amorphous/crystalline NiFe2O4 with phosphide heterojunction toward active oxygen evolution reaction catalysts
  122. Graphene-oxide-reinforced cement composites mechanical and microstructural characteristics at elevated temperatures
  123. Gray correlation analysis of factors influencing compressive strength and durability of nano-SiO2 and PVA fiber reinforced geopolymer mortar
  124. Preparation of layered gradient Cu–Cr–Ti alloy with excellent mechanical properties, thermal stability, and electrical conductivity
  125. Recovery of Cr from chrome-containing leather wastes to develop aluminum-based composite material along with Al2O3 ceramic particles: An ingenious approach
  126. Mechanisms of the improved stiffness of flexible polymers under impact loading
  127. Anticancer potential of gold nanoparticles (AuNPs) using a battery of in vitro tests
  128. Review Articles
  129. Proposed approaches for coronaviruses elimination from wastewater: Membrane techniques and nanotechnology solutions
  130. Application of Pickering emulsion in oil drilling and production
  131. The contribution of microfluidics to the fight against tuberculosis
  132. Graphene-based biosensors for disease theranostics: Development, applications, and recent advancements
  133. Synthesis and encapsulation of iron oxide nanorods for application in magnetic hyperthermia and photothermal therapy
  134. Contemporary nano-architectured drugs and leads for ανβ3 integrin-based chemotherapy: Rationale and retrospect
  135. State-of-the-art review of fabrication, application, and mechanical properties of functionally graded porous nanocomposite materials
  136. Insights on magnetic spinel ferrites for targeted drug delivery and hyperthermia applications
  137. A review on heterogeneous oxidation of acetaminophen based on micro and nanoparticles catalyzed by different activators
  138. Early diagnosis of lung cancer using magnetic nanoparticles-integrated systems
  139. Advances in ZnO: Manipulation of defects for enhancing their technological potentials
  140. Efficacious nanomedicine track toward combating COVID-19
  141. A review of the design, processes, and properties of Mg-based composites
  142. Green synthesis of nanoparticles for varied applications: Green renewable resources and energy-efficient synthetic routes
  143. Two-dimensional nanomaterial-based polymer composites: Fundamentals and applications
  144. Recent progress and challenges in plasmonic nanomaterials
  145. Apoptotic cell-derived micro/nanosized extracellular vesicles in tissue regeneration
  146. Electronic noses based on metal oxide nanowires: A review
  147. Framework materials for supercapacitors
  148. An overview on the reproductive toxicity of graphene derivatives: Highlighting the importance
  149. Antibacterial nanomaterials: Upcoming hope to overcome antibiotic resistance crisis
  150. Research progress of carbon materials in the field of three-dimensional printing polymer nanocomposites
  151. A review of atomic layer deposition modelling and simulation methodologies: Density functional theory and molecular dynamics
  152. Recent advances in the preparation of PVDF-based piezoelectric materials
  153. Recent developments in tensile properties of friction welding of carbon fiber-reinforced composite: A review
  154. Comprehensive review of the properties of fly ash-based geopolymer with additive of nano-SiO2
  155. Perspectives in biopolymer/graphene-based composite application: Advances, challenges, and recommendations
  156. Graphene-based nanocomposite using new modeling molecular dynamic simulations for proposed neutralizing mechanism and real-time sensing of COVID-19
  157. Nanotechnology application on bamboo materials: A review
  158. Recent developments and future perspectives of biorenewable nanocomposites for advanced applications
  159. Nanostructured lipid carrier system: A compendium of their formulation development approaches, optimization strategies by quality by design, and recent applications in drug delivery
  160. 3D printing customized design of human bone tissue implant and its application
  161. Design, preparation, and functionalization of nanobiomaterials for enhanced efficacy in current and future biomedical applications
  162. A brief review of nanoparticles-doped PEDOT:PSS nanocomposite for OLED and OPV
  163. Nanotechnology interventions as a putative tool for the treatment of dental afflictions
  164. Recent advancements in metal–organic frameworks integrating quantum dots (QDs@MOF) and their potential applications
  165. A focused review of short electrospun nanofiber preparation techniques for composite reinforcement
  166. Microstructural characteristics and nano-modification of interfacial transition zone in concrete: A review
  167. Latest developments in the upconversion nanotechnology for the rapid detection of food safety: A review
  168. Strategic applications of nano-fertilizers for sustainable agriculture: Benefits and bottlenecks
  169. Molecular dynamics application of cocrystal energetic materials: A review
  170. Synthesis and application of nanometer hydroxyapatite in biomedicine
  171. Cutting-edge development in waste-recycled nanomaterials for energy storage and conversion applications
  172. Biological applications of ternary quantum dots: A review
  173. Nanotherapeutics for hydrogen sulfide-involved treatment: An emerging approach for cancer therapy
  174. Application of antibacterial nanoparticles in orthodontic materials
  175. Effect of natural-based biological hydrogels combined with growth factors on skin wound healing
  176. Nanozymes – A route to overcome microbial resistance: A viewpoint
  177. Recent developments and applications of smart nanoparticles in biomedicine
  178. Contemporary review on carbon nanotube (CNT) composites and their impact on multifarious applications
  179. Interfacial interactions and reinforcing mechanisms of cellulose and chitin nanomaterials and starch derivatives for cement and concrete strength and durability enhancement: A review
  180. Diamond-like carbon films for tribological modification of rubber
  181. Layered double hydroxides (LDHs) modified cement-based materials: A systematic review
  182. Recent research progress and advanced applications of silica/polymer nanocomposites
  183. Modeling of supramolecular biopolymers: Leading the in silico revolution of tissue engineering and nanomedicine
  184. Recent advances in perovskites-based optoelectronics
  185. Biogenic synthesis of palladium nanoparticles: New production methods and applications
  186. A comprehensive review of nanofluids with fractional derivatives: Modeling and application
  187. Electrospinning of marine polysaccharides: Processing and chemical aspects, challenges, and future prospects
  188. Electrohydrodynamic printing for demanding devices: A review of processing and applications
  189. Rapid Communications
  190. Structural material with designed thermal twist for a simple actuation
  191. Recent advances in photothermal materials for solar-driven crude oil adsorption
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