This review aims to examine the hydrogel structure concisely, approaches to hydrogel synthesis, and the most recent progressions in hydrogel technology along with its multifaceted applications within the domain of biomedicine, emphasizing its capacity to transform the delivery of drugs, tissue engineering, and diagnostics. This review employs an organized search of the literature to gather and evaluate state-of-the-art examines on hydrogel uses for biomedicine, synthesizing significant developments and breakthroughs to provide a holistic comprehension of their developing role and possible impact. The review's findings emphasize the revolutionary potential of recent advances in hydrogel uses within biomedicine, which includes improved drug delivery, cutting-edge tissue engineering, and recognized diagnostics. In summary, this scholarly article explores the intricacies of hydrogel structure, methodologies for hydrogel synthesis, and notable breakthroughs in the biomedical utilization of hydrogels. Given the extraordinary potential of hydrogels to transform diagnostic and therapeutic methodologies, this article emphasizes the growing significance of hydrogels in biomedicine and the critical need for further investigation into this subject matter. Consequently, hydrogels can pave the way for enhanced healthcare standards.
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