Advanced Ceramic-Based Biomaterials for Bone Repair: Real- Time Biomechanical Assessments Using Wireless e-Health Solutions | [International Journal of Communication Networks and Information Security • 2024]

Author(s):

1. Zahra Baradaran Shoraka: Department of Psychological and Quantitative Foundations, University of Iowa

Abstract:

As a result, biomaterials have experienced great advances in the burgeoning need for suitable bone repair solutions, and ceramicbased biomaterials, in particular, have been suggested as a solution due to their biocompatibility, bioactivity, and mechanical properties. In this paper, we explore the application of advanced ceramic-based biomaterials in bone repair and the integration of real-time biomechanical assessment with wireless e-health solutions. Hydroxyapatite (HA), calcium phosphates, and bioactive glass are discussed as examples of ceramic biomaterials that mimic natural bone structure and can support osteogenesis and, thus, bone regeneration. Ceramics have unique mechanical properties, such as high compressive strength and similar chemical properties to bone mineral as a body material for loadbearing applications. Composite materials, however, are 3D printed, overcoming brittleness and lack of flexibility. We propose a real-time biomechanical monitoring system with wireless health solutions to improve patient outcomes and reduce recovery time. In these systems, bone healing load distribution and implant stability are measured by a ceramic implant loaded with sensors. By doing this, the risk of implant failure is minimized, as is the risk of potential complications, and bidirectional transmission of biomechanical data wirelessly from the implant to healthcare providers is enabled on a timely basis. It also considers data privacy and security ethics, and finally.

Page(s): 1990-2005

DOI: DOI not available

Published: Journal: International Journal of Communication Networks and Information Security, Volume: 16, Issue: 4, Year: 2024

Keywords:

Bioactive glass , wireless ehealth solutions , biomechanical assessments , Advanced ceramic biomaterials

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