Graphene Hybrid Materials for Controlling Cellular Microenvironments

Kim, Cheol-Hwi; Kim, Tae-Hyung

doi:10.3390/ma13184008

Cited by 3 publications

(4 citation statements)

References 122 publications

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“… 9 Other studies report the use of graphene as a specific hybrid to attach graphene compounds in order to form composite nanoparticles with increased drug-binding capacity, greater water solubility and the ability to control drug release as a result of physiological changes (ionic strength). 54 , 60 , 61 Lin et al (2013) proved that DOX, loaded on GO with functionalized folic acid, increases the cytotoxicity against OCM-1 human choroidal melanoma cells (viability <20%) whereas the DOX-GO hybrid induced significantly lower cytotoxicity (~40% viability) relative to control human ARPE-19 retinal pigment epithelial cells (after 24 hours of incubation). In addition, it has been shown to be able to load almost 100% DOX up to a concentration of 0.2 mg DOX/mg GO.…”

Section: Graphene and Graphene Derivatives In Oncologymentioning

confidence: 99%

“…This is mainly the result of the activation of apoptotic pathways under the influence of 15-minute exposure to visible light (48.6 J cm −2 ). 61 …”

Section: Graphene and Graphene Derivatives In Oncologymentioning

confidence: 99%

“…Kim et al (2020) reported the possibility of regulating the cellular microenvironment, using graphene derivatives or graphene hybrid materials to effectively control cell differentiation and function, and consequently biological responsiveness of cancer cells. 61 Interestingly, the effect of graphene particle size on cell viability have not been much examined by researchers. Another important issue is the diffusion of particles through biological membranes, which can act as barriers and limit the penetration of graphene structures.…”

Section: Summary and Future Perspectivementioning

confidence: 99%

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Chasing Graphene-Based Anticancer Drugs: Where are We Now on the Biomedical Graphene Roadmap?

Uzdrowska,

Knap,

Gulczynski

et al. 2024

IJN

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Graphene and graphene-based materials have attracted growing interest for potential applications in medicine because of their good biocompatibility, cargo capability and possible surface functionalizations. In parallel, prototypic graphene-based devices have been developed to diagnose, imaging and track tumor growth in cancer patients. There is a growing number of reports on the use of graphene and its functionalized derivatives in the design of innovative drugs delivery systems, photothermal and photodynamic cancer therapy, and as a platform to combine multiple therapies. The aim of this review is to introduce the latest scientific achievements in the field of innovative composite graphene materials as potentially applied in cancer therapy. The “Technology and Innovation Roadmap” published in the Graphene Flagship indicates, that the first anti-cancer drugs using graphene and graphene-derived materials will have appeared on the market by 2030. However, it is necessary to broaden understanding of graphene-based material interactions with cellular metabolism and signaling at the functional level, as well as toxicity. The main aspects of further research should elucidate how treatment methods (e.g., photothermal therapy, photodynamic therapy, combination therapy) and the physicochemical properties of graphene materials influence their ability to modulate autophagy and kill cancer cells. Interestingly, recent scientific reports also prove that graphene nanocomposites modulate cancer cell death by inducing precise autophagy dysfunctions caused by lysosome damage. It turns out as well that developing photothermal oncological treatments, it should be taken into account that near-infrared-II radiation (1000–1500 nm) is a better option than NIR-I (750–1000 nm) because it can penetrate deeper into tissues due to less scattering at longer wavelengths radiation.

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Section: Graphene and Graphene Derivatives In Oncologymentioning

confidence: 99%

“…This is mainly the result of the activation of apoptotic pathways under the influence of 15-minute exposure to visible light (48.6 J cm −2 ). 61 …”

Section: Graphene and Graphene Derivatives In Oncologymentioning

confidence: 99%

Section: Summary and Future Perspectivementioning

confidence: 99%

See 1 more Smart Citation

Chasing Graphene-Based Anticancer Drugs: Where are We Now on the Biomedical Graphene Roadmap?

Uzdrowska,

Knap,

Gulczynski

et al. 2024

IJN

View full text Add to dashboard Cite

show abstract

“…[10][11][12] Such a strategy has been further extended to the use of graphene for guiding cellular differentiation into specific lineages, including the osteogenesis and neurogenesis of stem cells. [13][14][15] Despite the usefulness of graphene in biological applications, one of its major drawbacks is its costly and complex fabrication process. [16] Layer-controlled pure graphene is generally obtained via chemical vapor deposition (CVD); however, this method requires expensive instruments, high-purity carbon and hydrogen sources, and catalytic metals.…”

Section: Doi: 101002/smll202103596mentioning

confidence: 99%

Extremely Uniform Graphene Oxide Thin Film as a Universal Platform for One‐Step Biomaterial Patterning

Kim

Han

Choi

et al. 2021

Small

Self Cite

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Graphene oxide (GO) has proven to be a highly promising material across various biomedical research avenues, including cancer therapy and stem cell‐based regenerative medicine. However, creating a uniform GO coating as a thin layer on desired substrates has been considered challenging owing to the intrinsic variability of the size and shape of GO. Herein, a new method is introduced that enables highly uniform GO thin film (UGTF) fabrication on various biocompatible substrates. By optimizing the composition of the GO suspension and preheating process to the substrates, the “coffee‐ring effect” is significantly suppressed. After applying a special postsmoothing process referred to as the low‐oxygen concentration and low electrical energy plasma (LOLP) treatment, GO is converted to small fragments with a film thickness of up to several nanometers (≈5.1 nm) and a height variation of only 0.6 nm, based on atomic force microscopy images. The uniform GO thin film can also be generated as periodic micropatterns on glass and polymer substrates, which are effective in one‐step micropatterning of both antibodies and mouse melanoma cells (B16‐F10). Therefore, it can be concluded that the developed UGTF is useful for various graphene‐based biological applications.

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Rapid Formation of Stem Cell Spheroids Using Two-Dimensional MXene Particles

Jang

Lee

2021

Processes

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Cell spheroids have been studied as a biomimic medicine for tissue healing using cell sources. Rapid cell spheroid production increases cell survival and activity as well as the efficiency of mass production by reducing processing time. In this study, two-dimensional MXene (Ti3C2) particles were used to form mesenchymal stem cell spheroids, and the optimal MXene concentration, spheroid-production times, and bioactivity levels of spheroid cells during this process were assessed. A MXene concentration range of 1 to 10 μg/mL induced spheroid formation within 6 h. The MXene-induced spheroids exhibited osteogenic-differentiation behavior, with the highest activity levels at a concentration of 5 μg/mL. We report a novel and effective method for the rapid formation of stem cell spheroids using MXene.

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Graphene Hybrid Materials for Controlling Cellular Microenvironments

Cited by 3 publications

References 122 publications

Chasing Graphene-Based Anticancer Drugs: Where are We Now on the Biomedical Graphene Roadmap?

Chasing Graphene-Based Anticancer Drugs: Where are We Now on the Biomedical Graphene Roadmap?

Extremely Uniform Graphene Oxide Thin Film as a Universal Platform for One‐Step Biomaterial Patterning

Rapid Formation of Stem Cell Spheroids Using Two-Dimensional MXene Particles

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