Artificial intelligence (AI) has the potential to make substantial progress toward the goal of making healthcare more personalized, predictive, preventative, and interactive. We believe AI will continue its present path and ultimately become a mature and effective tool for the healthcare sector. Besides this AI-based systems raise concerns regarding data security and privacy. Because health records are important and vulnerable, hackers often target them during data breaches. The absence of standard guidelines for the moral use of AI and ML in healthcare has only served to worsen the situation. There is debate about how far artificial intelligence (AI) may be utilized ethically in healthcare settings since there are no universal guidelines for its use. Therefore, maintaining the confidentiality of medical records is crucial. This study enlightens the possible drawbacks of AI in the implementation of healthcare sector and their solutions to overcome these situations.
Graphical Abstract
Wearable bioelectronics and therapeutics are a rapidly evolving area of research, with researchers exploring new materials that offer greater flexibility and sophistication. Conductive hydrogels have emerged as a promising material due to their tunable electrical properties, flexible mechanical properties, high elasticity, stretchability, excellent biocompatibility, and responsiveness to stimuli. This review presents an overview of recent breakthroughs in conductive hydrogels, including their materials, classification, and applications. By providing a comprehensive review of current research, this paper aims to equip researchers with a deeper understanding of conductive hydrogels and inspire new design approaches for various healthcare applications.
Tissue engineers have recently been interested in triply periodic minimum surfaces (TPMSs) for use in creating biomimetic porous scaffolds. Improved cell attachment, migration, and proliferation may be achieved with TPMS scaffolds because of its many benefits, such as a high volume to surface area ratio, reduced stress concentration, and enhanced permeability compared to conventional lattice architectures. Some of the crucial tissue-specific parameters, such permeability, Elastic modulus, and pore size, have been considered by the designers of various TPMS scaffolds described in the literature. These days, triply periodic minimum surface (TPMS) is seen as a leading option for building porous structures due to its smooth edges, fully integrated porous architectures, and mathematically adjustable geometry. Many benefits of TPMS, however, are not being properly used in ongoing studies. This study suggests the future direction of the TMPS in the perspective of the mesenchymal stem cell differentiation to overcome many shortcoming which was faced by the researchers.
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