NanoMedicine; An Analysis of Hydrogels Scaffolds for Tissue Engineering Applications

Authors

  • Ananya Saridena Gifted Gabber
  • Abhaya Saridena
  • Jothsna Kethar Gifted Gabber

DOI:

https://doi.org/10.47611/jsrhs.v12i1.4360

Keywords:

Tissue Engineering, Hydrogels, Scaffolds, NanoMedicine, Regenerative Medicine, Synthetic scaffolds, Cell Support, Mechanical Support, Meta-Analysis, Tissue Damage

Abstract

Tissue damage and disease impose a significant burden on individuals, society, and the economy. Current tissue engineering techniques have limitations, and improvements are necessary to more effectively repair or regenerate damaged or diseased tissues. Hydrogels, a type of synthetic scaffold, have gained increasing attention in tissue engineering due to their mechanical support for cells, customizable characteristics, and potential to overcome challenges in specific applications. However, the full extent of their effectiveness and capabilities in tissue engineering is not yet determined. This research paper aims to analyze the uses and capabilities of hydrogels in tissue engineering through a meta-analysis of various studies, contributing to the advancement of regenerative medicine. Hydrogels present a versatile and promising scaffold for tissue engineering, with the potential to significantly improve the field of regenerative medicine.

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Author Biography

Jothsna Kethar, Gifted Gabber

The 8-week session where the student will conduct research and write a scientific journal guided by Dr. Rajagopal Appavu, Assistant Professor, Vaccine Developer, Senior Data Scientist/Analyst, Toxicologist, and Chemist. After the draft has been approved by Professor, students will be guided to submit their scientific journal. 

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Published

02-28-2023

How to Cite

Saridena, A., Saridena, A. ., & Kethar, J. (2023). NanoMedicine; An Analysis of Hydrogels Scaffolds for Tissue Engineering Applications. Journal of Student Research, 12(1). https://doi.org/10.47611/jsrhs.v12i1.4360

Issue

Vol. 12 No. 1 (2023)

Section

HS Research Articles

Copyright (c) 2023 Ananya Saridena, Abhaya Saridena; Jothsna Kethar

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