Innovative Marine-Sourced Hydroxyapatite, Chitosan, Collagen, and Gelatin for Eco-Friendly Bone and Cartilage Regeneration.

Hoda Elkhenany, Mariam Waleed Soliman, Dina Atta, Nagwa El-Badri
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Abstract

In recent years, the exploration of sustainable alternatives in the field of bone tissue engineering has led researchers to focus on marine waste byproducts as a valuable resource. These marine resources, often overlooked remnants of various industries, exhibit a rich composition of hydroxyapatite, collagen, calcium carbonate, and other minerals essential to the complex framework of bone structure. Marine waste by-products can emit gases such as methane and carbon dioxide, highlighting the urgency to repurpose these materials for innovative tissue regeneration solutions, offering a sustainable approach to address environmental challenges while advancing medical science. Using these discarded materials offers a promising pathway for sustainable development in regenerative medicine. This review investigates the distinctive properties of marine waste byproducts, emphasizing their capacity to be recycled effectively to contribute to the rebuilding of bone and cartilage tissue during regeneration processes. We also highlight the compatibility of these resources with biological materials such as platelet-rich plasma (PRP), stem cells, exosomes, and natural bioproducts, as well as nanoparticles (NPs) and polymers. By using the natural potential of these resources, we simultaneously address environmental challenges and promote innovative solutions in skeletal tissue engineering, initiating a new era of environmentally green biomedical research.

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创新性的海洋来源羟基磷灰石、壳聚糖、胶原蛋白和明胶用于生态友好型骨和软骨再生。
近年来,骨组织工程领域对可持续替代品的探索促使研究人员将目光投向作为宝贵资源的海洋废弃物副产品。这些海洋资源往往是被忽视的各行各业的残余物,其中含有丰富的羟基磷灰石、胶原蛋白、碳酸钙和其他对复杂的骨结构框架至关重要的矿物质。海洋废弃物的副产品会释放甲烷和二氧化碳等气体,这凸显了将这些材料重新用于创新组织再生解决方案的紧迫性,为应对环境挑战提供了一种可持续的方法,同时也推动了医学科学的发展。利用这些废弃材料为再生医学的可持续发展提供了一条前景广阔的途径。本综述研究了海洋废弃物副产品的独特性质,强调了它们在再生过程中有效回收利用以促进骨和软骨组织重建的能力。我们还强调了这些资源与富血小板血浆(PRP)、干细胞、外泌体、天然生物制品以及纳米颗粒(NPs)和聚合物等生物材料的兼容性。通过利用这些资源的天然潜力,我们同时应对了环境挑战,并推动了骨骼组织工程的创新解决方案,开创了环境绿色生物医学研究的新时代。
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