Mohan Vedhanayagam scite author profile

Native collagen is arranged in bundles of aligned fibrils to withstand in vivo mechanical loads. Reproducing such a process under in vitro conditions has not met with major success. Our approach has been to induce nanolinks, during the self-assembly process, leading to delayed rather than inhibited fibrillogenesis. For this, a designed synthesis of nanoparticles - using starch as a template and a reflux process, which would provide a highly anisotropic (star shaped) nanoparticle, with large surface area was adopted. Anisotropy associated decrease in Morin temperature and superparamagnetic behavior was observed. Polysaccharide on the nanoparticle surface provided aqueous stability and low cytotoxicity. Starch coated nanoparticles was utilized to build polysaccharide - collagen crosslinks, which supplemented natural crosslinks in collagen, without disturbing the conformation of collagen. The resulting fibrillar lamellae showed a striking resemblance to native lamellae, but had a melting and denaturation temperature higher than native collagen. The biocompatibility and superparamagnetism of the nanoparticles also come handy in the development of stable collagen constructs for various biomedical applications, including that of MRI contrast agents.

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Polymethyl methacrylate (PMMA) grafted collagen scaffold reinforced by PdO–TiO2 nanocomposites

Vedhanayagam

Sadagopan

Nair

et al. 2020

Materials Science and Engineering: C

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Role of nanoparticle size in self-assemble processes of collagen for tissue engineering application

Vedhanayagam

Nidhin

Duraipandy

et al. 2017

International Journal of Biological Macromolecules

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Collagen-ZnO Scaffolds for Wound Healing Applications: Role of Dendrimer Functionalization and Nanoparticle Morphology

Vedhanayagam

Nair

Sreeram

2018

ACS Appl. Bio Mater.

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Functionalized nanoparticle cross-linked collagen scaffolds offer improved properties to biomaterials and regenerated tissues, as influence of nanoparticle shape on collagen scaffold has received little attention. The present study evaluates the role of ZnO nanoparticle shape (sphere, rod, hexagonal, needle, flower, star, circular disk, doughnut, and cube) on collagen self-assembly. The nanoparticle was prepared by using coprecipitation method and subsequently functionalized with triethoxysilane poly(amidoamine) dendrimer generation 1 (TES-PAMAM-G1 or G1) on the nanoparticle surface. The self-assembly process of collagen, facilitated by EDC-NHS cross-linking, led to stable ZnO-TES-PAMAM-G1-collagen scaffolds. Physicochemical properties and biocompatibility of scaffolds were analyzed to determine the thermal, mechanical and pore size transformation and cell viability, etc. and obtained results compared against collagen scaffolds with/without EDC-NHS cross-linking. In vivo wound healing activity of ZnO-TES-PAMAM-G1-collagen scaffolds was tested on Albino rats that were subjected to excisional wounds and results were compared with control and collagen scaffold. Our findings suggested that the functionalized nanostructure mediated collagen scaffolds exhibited higher thermal (91.2 ± 0.3 °C) and mechanical stability (130.23−305.45 ± 0.1−2.0 MPa) than collagen scaffold (77.36 ± 0.5 °C and 7.96 ± 0.8 MPa). The result of in vivo wound healing study indicated that spherical shape of ZnO-TES-PAMAM -G1 NPs cross-linked collagen scaffold showed enhanced re-epithelization and faster collagen deposition than other scaffolds probably owing to their higher surface area, which led to higher grafting density on the surface. This work provides a new approach for designing nanoparticle mediated collagen scaffold for wound healing application.

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