DOI: 10.37421/2157-7552.2024.15.341
DOI: 10.37421/2157-7552.2024.15.342
DOI: 10.37421/2157-7552.2024.15.345
Breast cancer survivors often face numerous challenges post-treatment, including obesity and decreased quality of life. Obesity not only increases the risk of cancer recurrence but also hampers functional recovery and overall well-being. In this article, we delve into the interplay between obesity, cancer rehabilitation, functional recovery andquality of life in breast cancer survivors. We explore the importance of tailored rehabilitation programs, encompassing physical activity, dietary interventions and psychosocial support, in mitigating the adverse effects of obesity and enhancing posttreatment outcomes. Additionally, we discuss the role of healthcare professionals, policymakers andcommunity support in promoting holistic rehabilitation strategies for optimal functional recovery and quality of life among breast cancer survivors.
DOI: 10.37421/2157-7552.2024.15.343
DOI: 10.37421/2157-7552.2024.15.344
DOI: 10.37421/2157-7552.2024.15.346
DOI: 10.37421/2157-7552.2024.15.347
DOI: 10.37421/2157-7552.2024.15.348
Animal-Derived Polysaccharides (ADPs) have gained significant attention due to their diverse biological activities, including immunomodulatory, antitumor, antioxidant, and antimicrobial properties. However, the efficacy of ADPs greatly depends on their preparation methods, which influence their structural composition and biological functions. This article explores the relationship between the preparation techniques of ADPs and their resultant biological activities, highlighting the importance of understanding these relationships for the development of novel therapeutic agents.
DOI: 10.37421/2157-7552.2024.15.349
Platelet-Rich Fibrin (PRF) has emerged as a promising therapeutic tool in regenerative medicine due to its rich content of growth factors and cytokines. Among various PRF formulations, Advanced Platelet-rich Fibrin (A-PRF) stands out for its unique biological and cellular properties. This article provides an in-depth exploration of A-PRF, comparing its characteristics with other platelet concentrates. It examines the composition, preparation methods, biological activities, and clinical applications of A-PRF, shedding light on its potential in tissue regeneration and wound healing.
DOI: 10.37421/2157-7552.2024.15.350
Bone tissue engineering holds immense promise for revolutionizing the treatment of bone defects and injuries. With the integration of Artificial Intelligence (AI) techniques, significant progress has been made at all stages of bone tissue engineering, from design and fabrication to optimization and clinical translation. This article explores the application of AI in bone tissue engineering, highlighting its potential to enhance scaffold design, cell behavior prediction, biomaterial selection, and clinical outcomes. By leveraging AI, researchers and clinicians can accelerate the development of personalized and effective bone regeneration therapies, ultimately improving patient care and quality of life.
Ryan Moseley
Regenerative medicine "is aimed at replacing or repairing human cells, or regenerating tissues and organs to restore normal function," the commissioner said in a report. By emphasizing "normal function", this approach to medical treatment is distinguished from many commonly used drugs that tend to treat symptoms but cannot address the underlying cause. For example, people with type 1 diabetes cannot produce insulin. Instead, daily insulin injections are needed to control blood sugar levels. Regenerative medicine seeks to solve this problem by regenerating the islets of Langerhans, which allows individuals to produce insulin. This means that insulin injections are gone and normal glucose metabolism is restored. Although it is not yet realistic to treat type 1 diabetes in this way, there are some areas of regenerative medicine that are well established in the medical setting.
Bhumika Yadav*, Pritam Shinde and Sumant Wankhade
DOI: DOI: 10.37421/2157-7552.2022.13.280
Human CNS is a very vital component of body and any damage or injury to it can cause serious lethal and fatal consequences. So there is thus need to regenerate this system incase of injury and is currently the most challenging task due to difficult system and restricted regenerative capacity. 3D bioprinting has outgrowth as an advanced field in field of neural tissue engineering. Which has enabled researchers to develop novel 3D scaffolds with complicated architecture in an effort to alleviate challenges defining neural tissue engineering. Amongst all the possible treatment of neuro-regenerative treatment available, 3D scaffolds had gained immense potential due to the advantage of being highly alterable, promoting complete similarity to the native biological architecture. This high architectural similarity between printed constructs and in vivo structures is known to promote a greater capacity for repair of damaged nerve tissues. This article consists of advancements in several 3D bioprinting approaches in accordance with the emergence of 4D printing, which adds a dimension of transformation over time to traditional 3D printing.
Journal of Tissue Science and Engineering received 807 citations as per Google Scholar report