Graphene Oxide Content Research Articles

Synthesis of a PVA-GO drug delivery system for sustained release of 4-methyl umbelliferon

Introduction 4-methyl umbelliferon (4MU) is a coumarin with anti-inflammatory, anti-thrombotic, enzyme-inhibiting, and antioxidant properties. Despite the benefits of the compound, it is eliminated very quickly from the blood circulation through the liver, kidney, and digestive system due to its hydrophobic properties. In this study we proposed to improve the durability of 4MU by binding of 4MU to poly vinyl alcohol (PVA) and graphene oxide (GO). Methods The PVA-4MU-GO complex was synthesized and characterized. Release of 4MU from the complex was investigated. H9C2 cells viability was investigated and the entry of complex to the cell was analyzed using flow cytometry. Result UV-Vis and FTIR studies confirmed the interaction of 4MU with PVA and GO. SEM measurement also revealed a particle size around 101 nm for PVA-4MU-GO complexes. The obtained results confirmed the assembly of PVA-4MU-GO. A continuous drug release for 8 d (160 h) was achieved. Cytotoxic studies on H9C2 cell showed that PVA-4MU-GO complex is dependent to the concentration of GO and also the relation of 4MU to GO. Sustained release and penetration of PVA-4MU-GO complex into the H9C2 cell were observed. Conclusion PVA-4MU-GO complex is recommended as an alternative for 4MU. Synthesis the complex of PVA-4MU-GO, verifying the correct binding, showing the in vitro release of the 4MU, as well as checking its toxicity and its gradual entry into the H9C2 cell, were performed in this study.

Structural, electrical, and photothermal conversion studies of Triglycine sulfate/Graphene oxide composites for pyroelectric detector and energy harvesting applications

Abstract The aim of this study is to investigate the figures of merit for pyroelectric detectors and energy harvesting of polycrystalline triglycine sulfate (TGS) loaded with different weight ratios of graphene oxide (GO). FTIR, XRD, and DSC techniques are used to characterize the synthesized composites. Structural changes in TGS upon GO loading correlate to the subsequent variations in composites' dielectric, pyroelectric, optical, and photothermal properties. The results revealed that doping TGS by low content of GO (1% – 5% by weight) could improve its photothermal effectiveness and figures of merit for pyroelectric detectors and energy harvesting applications.

Trace concentrations of graphene oxide and magnetic graphene oxide rescue anaerobic municipal sludge digesters under stress

This study evaluated long-term performance of graphene oxide (GO) and magnetic GO (MGO) nanosheets in semi-continuous-flow anaerobic digestion (AD) of municipal sludge over 230 days. At organic loading rates (OLRs) of 2.6 and 3.4 g chemical oxygen demand (COD)fed/L/day, 20 and 200 mg/L of GO and MGO did not affect AD performance. However, at an OLR of 5.2 g CODfed/L/day, where control digesters failed, 20 and 200 mg/L of GO and MGO sustained biogas yields at 190 mL/g CODfed/day, similar to yields at lower OLRs (2.6 and 3.4 g CODfed/L/day). This performance persisted after thedaily nanosheet replenishment stopped. Improvements were due to enhanced conductivity and microbial syntropy. The results showed a strong correlation with previous biochemical methane potential (BMP) assays, positioning BMPs as a predictive tool for continuous-flow AD performance. Overall, this study demonstrated potential of GO/MGO nanosheets to improve the stability and efficiency of AD systems under stress.

Optimization studies on output stabilization time and graphene oxide concentration in graphene-based flexible micro-supercapacitor.

Miniature energy storage devices are vital for developing flexible and wearable electronics. This paper discusses the fabrication of flexible laser-induced graphene-based micro-supercapacitors (MSCs) using a layered polyimide film and graphene oxide as the precursor for laser scribing. The areal capacitance of the MSCs was assessed daily after applying a H₂SO₄/PVA gel electrolyte. The capacitance displayed a substantial increase in the early days before stabilizing at a consistent value. The stabilization time was evaluated through systematic experimentation conducted over ten consecutive days. The experiments showed that the capacitance stabilized after six days. Various concentrations of graphene oxide were used to assemble the MSCs, and their performance was evaluated to determine the optimal concentration. The electrochemical impedance spectroscopy revealed that the supercapacitor fabricated with the optimum concentration of graphene oxide exhibited the lowest resistance. The optimized MSC displayed an areal capacitance of 10.07 mF/cm2 at a current density of 13 µA/cm2. The device could maintain a reliable output at different bending states and retain 87.9% of its original capacitance after 5000 charge-discharge cycles, highlighting its suitability for flexible and self-powered systems.

Green synthesis of graphene oxide from invasive plant species (Nymphaeaceae) for enhancing cement paste microstructure and compressive strength

The proliferation of invasive species, particularly water lilies (Nymphaeaceae), in aquatic ecosystems, such as Dal Lake in Srinagar, J&K, India, has led to significant challenges for aquatic life. This research addresses this issue by harnessing the invasive water lily as a resource for an environmentally conscious approach to produce graphene oxide (GO) through thermal pyrolysis. The synthesized GO was incorporated into cement paste (CP) (ranging from 0 to 0.09 wt%) to explore its impact on workability, mechanical properties, and microstructure. Increasing GO concentrations led to decreased workability. However, GO positively influenced compressive strength, with optimal enhancements observed at 0.06 %, a maximum enhancement in compressive strength of 53.7 % and 35.4 % at 7 and 28 days when compared to the control CP. Microstructure analysis through FE-SEM revealed improved cement hydration, pore filling, and densified microstructure, supported by XRD and FT-IR findings. Specifically, GO at 0.06 % concentration showed notable improvements, indicating its crucial role in enhancing mechanical properties.

Synthesis and characterization of the chitosan-xanthan-graphene oxide film for bone regeneration using advanced cell therapy

The present study aimed to synthesize and characterize polymer films at different graphene oxide (GO) concentrations for use in advanced cell therapy. Chitosan-xanthan (CX) films were prepared and combined with GO and then assigned to the following groups: G1 – CX; G2 – CX GO 0.5%; G3 – CX GO 1.0%; and G4 – CX GO 1.5%. The films were analyzed for their structural, mechanical, and biological properties by Raman and Fourier-Transform Infrared (FTIR) spectroscopy, Thermogravimetric Analysis (TGA), Scanning Electron Microscopy (SEM), Confocal Laser Scanning Microscopy (surface roughness measurement), Tensile Strength, and in vitro Bioactivity assay. Tensile strength and surface roughness data were analyzed by one-way analysis of variance (ANOVA), followed by Tukey’s test (α = 0.05). FTIR spectroscopy showed the presence of amide I and II bands (characteristic of chitosan) and carboxyl group (characteristic of xanthan). CO bands characteristic of GO were observed in groups containing these particles. Raman spectroscopy revealed D and G bands in the GO-containing groups. Film surface morphology exhibited a homogeneous, compact, and pore-free surface. The CX group had higher tensile strength (5.89 ± 1.62 KPa) ( p < 0.05). No statistically significant difference was observed in the other GO-containing groups ( p > 0.05). The films induced the deposition of apatite crystals on their surfaces, exhibiting activity under biomineralization conditions. Graphene oxide added into chitosan-xanthan films enhanced surface roughness and bioactivity but decreased tensile strength. The synthesized CXGO films are promising for advanced cell therapy because of their physicochemical, morphological, and mechanical properties, which seem ideal for tissue regeneration.

Revolutionizing copper pipe durability: Shielding against corrosion with graphene oxide through electrophoretic application

This research endeavors to utilize electrophoretic deposition (EPD) to coat copper (Cu) pipes with graphene oxide (GO) nanosheets, aiming to bolster their resistance against corrosion. To achieve this, a stable aqueous colloidal suspension of GO was meticulously prepared via liquid exfoliation in deionized water. This suspension served as an electrolytic solution for EPD. The EPD process involved the meticulous application of varied operational parameters such as deposition time, applied voltage, and GO nanosheet concentration to facilitate anodic deposition on the copper pipe’s surface. To gauge the efficacy of the GO coating, evaluations were conducted to assess adhesive force and stabilization using specialized coating adhesion scratch testing equipment. Further analysis of the resulting film on the Cu pipe was executed employing X-ray diffraction (XRD), scanning electron microscopy (SEM), Raman spectroscopy, and Fourier transform infrared spectroscopy (FT-IR). These methods provided detailed insights into the characteristics and properties of the GO material post-deposition. The study yielded noteworthy outcomes, revealing the achievement of a uniform, unbroken, and consistent coating film on the Cu pipe. This was accomplished by employing specific parameters as 60 s of deposition time, a GO concentration of 0.5 mg/mL, and a voltage of 20 V. Impressively, when subjected to a corrosive solution containing 3.5% sodium chloride, the corrosion protection exhibited a remarkable twofold enhancement compared to untreated copper tubing, boasting an efficiency (η) of 90.48%. These findings suggest that the Cu pipe, coated with GO using the EPD technique, holds significant promise for utilization in demanding industrial settings susceptible to corrosion challenges.

Fabrication and characterization of PVDF/PMMA nanocomposite membranes doped with graphene oxide (GO) for separation of CO2/CH4 from flue gas

This work focuses on developing polyvinylidene fluoride/polymethyl methacrylate (PVDF/PMMA) polymer blend nanocomposites incorporating varying concentrations of graphene oxide (GO) nanoparticles fabricated via casting solution processes. XRD and FT-IR confirmed GO-induced structural modifications in PVDF/PMMA blend. The addition of GO into PMMA/PVDF blend decreased and weakened the intensity of XRD peaks, suggesting that adding GO gradually reduces the crystallinity of the films. FT-IR verified miscibility and complex formation between the pristine polymer blend and the GO-filled nanocomposite. The incorporation of GO caused shifts in the optical absorption edge to lower wavelengths, causing a decrease in the optical bandgap energy (Eg). The real and imaginary parts of the dielectric permittivity (ε′ and ε′′), electric modulus (M′, M″), and AC conductivity (σac) have been measured from 0.1 Hz to 6 MHz. Both ε′ and ε′′ declined with rising frequency. The addition of different concentrations of GO generated charge transfer complexes in the polymer nanocomposites. SEM images show good homogeny with random dispersion of GO inside the polymer blend. The thermoluminescence (TL) glow curves for the nanocomposite samples irradiated 0.5, 1.0, 1.5, and 2 Gy doses show peak cantered at 207 °C. The peak position remained unchanged with increasing irradiation dosage. The dose-dependent linear growth in maximum peak height indicates radiation detection and monitoring capability.

Influence of graphene oxide and reduced graphene oxide on TiO2-reinforced flexible poly(vinyl alcohol) films for electromagnetic interference shielding

This study evaluates the impact of graphene oxide (GO) and reduced graphene oxide (rGO) on the structural characteristics and electromagnetic interference shielding effectiveness (EMI SE) of poly(vinyl alcohol) (PVA) films containing titanium dioxide (TiO₂). The composite films were prepared by solution casting, and their structural properties were analyzed through FTIR, electron microscopy, and X-ray diffraction. EMI SE was evaluated as a function of GO and rGO concentrations. Spectroscopic data indicated that TiO₂ and GO interact with PVA primarily through hydrogen bonding. The inclusion of TiO₂ increased the crystallinity of the films, although its interaction with PVA was not uniform. In composites containing GO, TiO₂ exhibited enhanced affinity for the polymer matrix due to the hydrophilic nature of both components. As a result, GO influenced the action of TiO₂ in the composite, leading to EMI SE values of 3.27 dB/mm in the X-band and 7.28 dB/mm at 9.3 GHz. The addition of rGO led to reduced interaction with TiO₂ due to a lower content of oxygen-containing groups, with the higher electrical conductivity of rGO being the most prominent effect observed. rGO demonstrated a competitive effect at 1 % filler and a synergistic effect at 4 % filler, with EMI SE values at 9.9 GHz increasing to 31.34 dB/mm and 55.80 dB/mm, respectively. This study shows that GO/TiO₂/PVA and rGO/TiO₂/PVA composite films exhibit promising EMI shielding properties. The different interactions between GO and rGO with TiO₂ and PVA result in distinct EMI SE mechanisms, with rGO showing superior performance. Combined with excellent mechanical flexibility and relatively low thickness, these data highlight the potential of these composite films for EMI shielding applications.

Experimental study on the shear behaviour of high-strength lightweight concrete beams incorporating graphene oxide

Graphene oxide (GO) has achieved significant progress in the material behaviour of cement-based materials. However, research on its structural behaviour in high-strength lightweight concrete (HSLWC) structures is limited, which restricts its engineering applications. This study focused on investigating the effects of low contents of GO on the shear behaviour of HSLWC beams. A total of four HSLWC beams with GO contents of 0, 0.01, 0.03 and 0.05% (by weight of cement) were designed to observe failure modes, load‒deformation curves, shear capacities, crack behaviour and load‒strain curves under four-point loading by a 300 kN servo loading device. The results revealed that all the beams exhibited shear compression failure. GO improved the shear capacity of the HSLWC beams, and this strengthening effect increased with increase in GO content. When the content of GO was 0.05%, the ultimate load of the beam reached a maximum, which was 39.2% greater than that of the control beam. GO can endow the HSLWC beams with a certain degree of ductility. In addition, a modified JGJ 12-2006 model was proposed to predict the shear capacity of HSLWC beams containing different GO contents on the basis of a comparison of typical models. This study can provide exploratory engineering practice for evaluating and designing GO-reinforced HSLWC structures.

Apoptotic Impact of Heliox Cold Plasma on a Cervical Cell Line Using Gold Nanoparticle-Doped Graphene Oxide Nanosheets

Background: Invasive cervical cancer is recognized as the second most common malignancy in women after breast cancer. Objectives: This study investigates, for the first time, the effect of gold nanoparticle-doped graphene oxide (GO) nanosheets on the human epithelial carcinoma (HeLa) cell line in the presence of heliox cold plasma. Methods: Graphene oxide nanosheets were synthesized using the Hummer method and then doped with gold nanoparticles. The nanoparticles were characterized by transmission electron microscopy (TEM), and the diffraction peaks of GO and gold nanoparticles were confirmed through X-ray diffraction (XRD) analysis. Additionally, the optical absorbance of the nanoparticles was measured in the range of 200 - 900 nm using UV-Visible spectroscopy. A plasma generator was fabricated to produce cold plasma using helium (He) and oxygen (O₂) gases at a 99:1 ratio. The radicals generated by the cold plasma were analyzed via optical emission spectroscopy (OES). Cell treatment was conducted by applying various concentrations of GO and GO/Au nanoparticles. Cellular phenotype was monitored through optical microscopy, and biocompatible concentrations of both nanoparticles were determined using the 3-[4,5-dimethylthiazol-2-yl]-2,5 diphenyl tetrazolium bromide (MTT) assay. Subsequently, cold plasma at varying distances and durations was applied to the nanoparticle-treated cells. The generated radicals and the expression of apoptotic genes in treated cells were assessed using 2,2-diphenyl-1-picrylhydrazyl (DPPH) and real-time PCR, respectively. Results: The width of the bacillus-like gold nanoparticles was 15.13 ± 0.96 nm. The cold plasma generated radicals such as N2I2⁺, N2II1⁻, He•, and O⁻•. XRD analysis confirmed the successful coupling of gold onto the GO nanosheets. The biocompatible concentrations of GO and GO/Au nanoparticles were found to be 30 µg/100 µL and 20 µg/100 µL, respectively, as determined by the MTT assay. Radical formation increased as incubation time was extended from 30 to 60 seconds. Furthermore, real-time PCR analysis demonstrated the highest levels of p53, Bax, and caspase 3/8 expression at a plasma exposure time of 60 seconds in the composite-treated group, while Bcl2 expression was significantly reduced. Conclusions: The findings suggest that the parameters of heliox cold plasma and the concentrations of GO/Au nanoparticles must be optimized to effectively induce apoptosis in cervical cancer cells.

Self-assembly fabrication of SASN@GO composites with high electrostatic safety and thermal stability performances

ABSTRACT The high electrostatic discharge (ESD) sensitivity and mechanical sensitivity of silver acetylide-silver nitrate (SASN) seriously affects its application. For solving this problem, novel SASN@GO nanocomposites were successfully prepared by a self-assembly method. Thin sheet graphene oxide (GO) was coated on the surface of SASN, and prevented the agglomeration of SASN nanoparticles effectively. GO content in SASN@GO nanocomposites was controlled (0.5 ~ 1.5 wt%) to balance explosive performance and safety. Results reveal that SASN@(1%)GO exhibits the best thermal safety and desensitization, with thermal decomposition temperature, impact sensitivity (I s), friction sensitivity (F s) and electrostatic energy at 50% ignition probability (E 50) of 208.2°C, 1.96 J, 128 N and 0.64 mJ respectively, which are much better than that of SASN, indicating safety performances of SASN are improved through the introducetion of a small amount of GO. This work provides a strategy for reducing the explosion risk of SASN.

Exploring potential of graphene oxide as an alternative antiviral approach for influenza A H1N1.

Aim: Graphene oxide (GO), known for its distinctive physicochemical properties, shows promise as a nanomaterial capable of combating infectious agents. This study investigates the efficacy of GO nanoparticles in restricting influenza A H1N1 replication in MDCK cells.Methods: GO nanoparticles were synthesized. After evaluating the toxicity of GO nanoparticles, the antiviral activity of the highest nontoxic concentration of GO against influenza A H1N1 in MDCK cells was studied.Results: GO treatments resulted in substantial decreases in virus titers, as shown via hemagglutination assay, TCID50 assay and real-time PCR analysis.Conclusion: This study emphasizes that GO nanoparticles have a high level of effectiveness against influenza A H1N1 viruses, making them an intriguing option for various antiviral uses.

The corrosion-inhibitory influence of graphene oxide on steel reinforcement embedded in concrete exposed to a 3.5M NaCl solution

Steel reinforcement corrosion significantly reduces the durability and service life of concrete structures, particularly in chloride-rich environments such as marine and coastal areas. This study aims to reduce the corrosion rate using graphene oxide (GO) as a corrosion inhibitor. Two GO dosages (0.0005 and 0.005 wt%) were evaluated for their effectiveness in mitigating corrosion in reinforced concrete exposed to a 3.5M NaCl solution. To assess the corrosion behavior of the steel reinforcement, Open Circuit Potential (OCP), Electrochemical Impedance Spectroscopy (EIS), and Linear Polarization Resistance (LPR) were evaluated over one year by wetting/drying cycles. Oxygen permeability and electrical resistivity tests were also conducted to evaluate the concrete's susceptibility to corrosion. Both GO content demonstrated significant corrosion inhibition, with the 0.005 wt% dosage providing the most effective protection. This was evidenced by the lowest icorr values recorded during the final cycle (52), larger capacitive loops, and higher impedance in EIS results, indicating enhanced corrosion resistance. Visual inspection of steel bars further confirmed these findings, showing no signs of deterioration or discoloration in GO-modified concrete compared to steel bars extracted from reference concrete. SEM-EDS analysis revealed higher carbon content on the steel surface, suggesting GO adsorption and the formation of a protective passive layer. These results suggest that GO is a promising nanomaterial for inhibiting corrosion in steel-reinforced concrete exposed to aggressive environmental conditions.

Design and Implementation of Leaf Wetness Sensor with different Graphene Oxide Concentration

Design and Implementation of Leaf Wetness Sensor with different Graphene Oxide Concentration

Enhancement of 5-Fluorouracil Drug Delivery in a Graphene Oxide Containing Electrospun Chitosan/Polyvinylpyrrolidone Construct.

Electrospun nanofibrous mats, consisting of chitosan (CS) and polyvinylpyrrolidone (PVP), were constructed with the addition of graphene oxide (GO) for enhancement of delivery of the 5-Fluorouracil (5-Fu) chemotherapy drug. Upon studying the range of GO concentrations in CS/PVP, the concentration of 0.2% w/v GO was chosen for inclusion in the drug delivery model. SEM showed bead-free, homogenous fibres within this construct. This construct also proved to be non-toxic to CaCo-2 cells over 24 and 48 h exposure. The construction of a drug delivery vehicle whereby 5-Fu was loaded with and without GO in various concentrations showed several interesting findings. The presence of CS/PVP was revealed through XPS, FTIR and Raman spectroscopies. FTIR was also imperative for the analysis of 5-Fu while Raman exclusively highlighted the presence of GO in the samples. In particular, a detailed analysis of the IR spectra recorded using two FTIR spectrometers, several options for determining the concentration of 5-Fu in composite fibre systems CS/PVP/5-Fu and GO/CS/PVP/5-Fu were demonstrated. By analysis of Raman spectra in the region of D and G bands, a linear dependence of ratios of integrated intensities of AD and AG on the intensity of host polymer band at 1425 cm-1 vs. GO content was found. Both methods, therefore, can be used for monitoring of GO content and 5-Fu release in studied complex systems. After incorporating the chemotherapy drug 5-Fu into the constructs, cell viability studies were also performed. This study demonstrated that GO/CS/PVP/5-Fu constructs have potential in chemotherapy drug delivery systems.

Potential advantage of invasive estuarine worms over native species under exposure to relevant concentrations of graphene oxide: Behavioral and biochemical insights

Technological development using graphene oxide (GO) has increased in the last years, leading to the release of this contaminant to final sinks, such as estuaries. Due to their potential to flocculate and deposit when interacting with high ionic strength media, GO poses a threat, especially to benthic organisms like polychaetes. In addition to chemical contamination, estuaries also face a severe threat from invasive species, which can cause irreversible damage to ecosystems. The combination of abiotic and biotic stressors may work together on native species, decreasing their resilience. Thus, this study aims to assess the effects of an abiotic stressor, GO nanosheets (0.001, 0.01, 0.1, 1, 10 mg GO/Kg dw) on Hediste diversicolor (native species) and Arenicola marina (invasive species) through several behavioral assays and biochemical markers. The impact of invasive species A. marina (biotic factor) on H. diversicolor avoidance behavior was also evaluated. Obtained results demonstrated that H. diversicolor fled from lower GO contamination compartments to higher ones and that exposure to increased GO concentrations negatively impacted its burrowing activity. They were unable to escape from higher contamination compartments, but at the highest concentrations, the bioturbation activity was significantly higher, which may indicate that H. diversicolor tended to dwell deeper in the sediment. A. marina showed an escape behavior from compartments with higher GO concentrations. Additionally, this species' bioturbation activity significantly decreased when exposed to GO. Moreover, avoidance tests demonstrated that the presence of A. marina affected the behavior of H. diversicolor. Regarding oxidative stress, H. diversicolor seems to be more impacted than A. marina, since Lipid peroxidation levels were higher in all GO concentrations and Superoxide dismutase activity significantly increased in the lowest GO levels. Overall, H. diversicolor spatial distribution may be severely constrained under abiotic and biotic stress, while A. marina's higher foraging activity may promote its propagation in the estuary. Behavioral tests, combined with biochemical markers have shown to be relevant tools for the development of more environmental-realistic assessment and monitoring frameworks for estuaries.

Reaction mechanism study of calcium carbide residue with graphene oxide in aqueous environment: Adsorption properties and mechanical potentials

Graphene Oxide (GO) is widely used, but its hydrophilic properties make it difficult to remove once it enters water and soil environments. In this paper, the adsorption effect of calcium carbide residue (CCR) as adsorbent on GO was investigated through a series of adsorption tests. Adsorption thermodynamics, kinetics, isotherm models, and various characterization techniques were employed to explore the adsorption mechanism. Additionally, the study assessed CCR’s ability to stabilize GO-contaminated soils through unconfined compressive strength tests. The results showed that (1) at T = 303 K, with a pH of 11 and an initial GO concentration of 80 mg/L, CCR demonstrated excellent adsorption performance. (2) The adsorption process followed the Langmuir isotherm and a quasi-second-order kinetic model, indicating chemical adsorption with spontaneous heat adsorption. (3) CCR not only acts as an effective adsorbent for removing GO from wastewater but also has the potential to strengthen GO-contaminated soils. In addition, due to its favorable environmental benefits, this study has a wide range of potential applications in industrial fields such as wastewater treatment, air purification, and energy storage and conversion. This study not only proposes an effective method for removing graphene oxide from aqueous environments, but also provides a new idea for waste resource utilization, which helps to achieve the dual goals of environmental protection and resource reuse.

Graphene oxide in low concentrations can change mitochondrial potential, autophagy, and apoptosis paths in two strains of invertebrates with different life strategies

Nanoparticles, like graphene oxide (GO), are particles with unique physiochemical properties that enable their wide application in various areas of life. The effects of GO on individual cell organelles like mitochondria and the effects of interactions are worth investigating, as they can activate multiple cellular processes, such as autophagy or apoptosis. Mitochondrial injury plays an essential role in the majority of cell death routines. In the project, we investigated cell health status measured as mitochondrial inner membrane depolarization, autophagy, and apoptosis induction during long-term GO administration in food (0.02 μg g−1 and 0.2 μg g−1 of food). Two unique Acheta domesticus strains that differ in life strategy were used: wild-type and long-lived at three different life stages (larva, young adult, mature adult). The changes in mitochondrial trans-membrane potential were marked in the wild-type strain. The autophagy was lower in all GO-treated groups in both strains, and the apoptosis was lower in both strains in the mature adult crickets. Low GO concentrations treatment for the whole life, despite mitochondrial dysfunction, may lead to inhibition of autophagy and apoptosis by arresting the cell cycle for the duration of repair, and other repair tools are involved in the process of restoring homeostasis.

Art and Science of Reinforcing Ceramics with Graphene via Ultrasonication Mixing.

This work presents an interdisciplinary approach combining materials science, ultrasonication, artistic expression, and curatorial practice to develop and investigate novel composites. The focus of the approach is incorporating graphene oxide (GO) into kaolin and exploring its effects on material properties. The composites were prepared with varying GO concentrations and sonication times, and their mechanical, thermal, and morphological characteristics were evaluated. The results reveal that the addition of 0.5 wt % GO, combined with a sonication time of 10 min, leads to the highest storage modulus and improved thermal stability. Ultrasonication proved to be an effective method for dispersing and distributing GO particles within the kaolin matrix, resulting in an enhanced material performance. Furthermore, the application of novel composites provided by Prvački adds a unique dimension to the study. Through the artistic interpretation, the tactile qualities and aesthetic potential of the composites are explored, shedding light on the transformative power of materials and cultural significance organized as part of an artist-in-residence commission, introduced in conjunction with the NUS Public Art Initiative. This interdisciplinary collaboration accompanied by an exhibition at the NUS Museum demonstrates the value of merging scientific research, technological advancements, and artistic exploration.