Manish Ayushman scite author profile

Pattern formation during evaporation of biofluids has numerous biomedical applications, e.g., in disease identification. The drying of a bidisperse colloidal droplet involves formation of coffee ring patterns owing to the deposition of constituent particles. In the present study, we examine the distinctly different pattern formations during the drying of a colloidal solution depending on the nature of the constituent proteins. The pattern formations of two oppositely charged proteins, namely HSA and lysozyme, have been studied in the presence of fluorescence polystyrene beads of two different sizes (providing better image contrast for further analysis). The variation of pattern formation has been studied by varying the concentrations of the proteins as well as the particles. Furthermore, using image analysis, the patterns are segmented into different regions for quantification. To explain the variations in the patterns, we delve into the interplay of the interactions, especially the capillary and the DLVO forces (between the particles and the substrate). The developed methodology based on the coffee ring effect may be used to identify individual proteins.

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Interfacial energy driven distinctive pattern formation during the drying of blood droplets

Mukhopadhyay

Ray²,

Ayushman

et al. 2020

Journal of Colloid and Interface Science

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Dynamically Crosslinked Poly(ethylene‐glycol) Hydrogels Reveal a Critical Role of Viscoelasticity in Modulating Glioblastoma Fates and Drug Responses in 3D

Sinha

Ayushman

Tong

et al. 2022

Adv Healthcare Materials

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Glioblastoma multiforme (GBM) is the most prevalent and aggressive brain tumor in adults. Hydrogels have been employed as 3D in vitro culture models to elucidate how matrix cues such as stiffness and degradation drive GBM progression and drug responses. Recently, viscoelasticity has been identified as an important niche cue in regulating stem cell differentiation and morphogenesis in 3D. Brain is a viscoelastic tissue, yet how viscoelasticity modulates GBM fate and drug response remains largely unknown. Using dynamic hydrazone crosslinking chemistry, a poly(ethylene‐glycol)‐based hydrogel system with brain‐mimicking stiffness and tunable stress relaxation is reported to interrogate the role of viscoelasticity on GBM fates in 3D. The hydrogel design allows tuning stress relaxation without changing stiffness, biochemical ligand density, or diffusion. The results reveal that increasing stress relaxation promotes invasive GBM behavior, such as cell spreading, migration, and GBM stem‐like cell marker expression. Furthermore, increasing stress relaxation enhances GBM proliferation and drug sensitivity. Stress‐relaxation induced changes on GBM fates and drug response are found to be mediated through the cytoskeleton and transient receptor potential vanilloid‐type 4. These results highlight the importance of incorporating viscoelasticity into 3D in vitro GBM models and provide novel insights into how viscoelasticity modulates GBM cell fates.

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Sliding hydrogels enhance MSC chondrogenesis by facilitating early stage cytoskeletal/nuclear dynamics and mechanical loading

Ayushman

Tong

Yang

2022

Biophysical Journal

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The experiences of a cancer patient: A son's perspective

Ayushman¹

2020

Cancer Res Stat Treat

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Manish Ayushman

Analysis of the Distinct Pattern Formation of Globular Proteins in the Presence of Micro- and Nanoparticles

Interfacial energy driven distinctive pattern formation during the drying of blood droplets

Dynamically Crosslinked Poly(ethylene‐glycol) Hydrogels Reveal a Critical Role of Viscoelasticity in Modulating Glioblastoma Fates and Drug Responses in 3D

Sliding hydrogels enhance MSC chondrogenesis by facilitating early stage cytoskeletal/nuclear dynamics and mechanical loading

The experiences of a cancer patient: A son's perspective

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