Marine Algae Derived Polysaccharides for Bone Tissue Regeneration

“…Generally speaking, the scaffolds have been used in two different ways to assist osteogenesis or chondrogenesis: i) in combination with growth factors to facilitate differentiation of cells via controlled release of growth factors, or ii) in the absence of any growth factors by solely relying on intermolecular interactions with important cell-membrance receptors. [55,56] This paper, reviews the most recent progress in sulfated polysaccharide-based scaffolds for skeletal tissue engineering, with particular focus on bone and cartilage tissue engineering. Specifically, three different groups of sulfated polysaccharides -sulfated GAGs, marine sulfated glycans and chemically sulfated polysaccharides, and their usage as building blocks in orthopaedic scaffolds are reviewed; since these polysaccharides present the most promising avenues in this field.…”

Sulfated polysaccharide-based scaffolds for orthopaedic tissue engineering

“…Generally speaking, the scaffolds have been used in two different ways to assist osteogenesis or chondrogenesis: i) in combination with growth factors to facilitate differentiation of cells via controlled release of growth factors, or ii) in the absence of any growth factors by solely relying on intermolecular interactions with important cell-membrance receptors. [55,56] This paper, reviews the most recent progress in sulfated polysaccharide-based scaffolds for skeletal tissue engineering, with particular focus on bone and cartilage tissue engineering. Specifically, three different groups of sulfated polysaccharides -sulfated GAGs, marine sulfated glycans and chemically sulfated polysaccharides, and their usage as building blocks in orthopaedic scaffolds are reviewed; since these polysaccharides present the most promising avenues in this field.…”

Sulfated polysaccharide-based scaffolds for orthopaedic tissue engineering

“…Jeong et al observed two times higher mineralization in fucoidan/nanohydroxyapatite scaffolds than in nanohydroxyapatite scaffolds, suggesting that the former matrices could be promising biomaterials for bone tissue engineering (Jeong et al 2013). Jin et al developed structures of PCL/ fucoidan using rapid prototyping technique (Gyuhyun Jin 2011), with mechanical properties and mineralization promotion superior to the ones composed by pure PCL (Gyuhyun Jin 2011;Venkatesan and Kim 2015). A recent approach to treat bone diseases involves the effect of fucoidan on human mesenchymal stem cells, observing that the fucoidan improved the stem cell behavior regarding osteogenic differentiation, namely by registering an increase in the expression of ALP, osteopontin, type I collagen, RUNX-2, and osteocalcin (Park et al 2012;Venkatesan and Kim 2015).…”

Marine‐origin Polysaccharides for Tissue Engineering and Regenerative Medicine

“…Alginat merupakan komponen polisakarida terbesar dalam alga perang dan dilaporkan menyumbang kepada 40% berat kering alga perang (Mohammad Latifi et al 2015;Venkatesan & Kim 2015). Menurut McHugh (1987), alginat kebanyakannya diekstrak daripada Laminaria sp., Macrocystis sp.…”

Kesan Kaedah Pemendakan Berbeza terhadap Ciri Fizikokimia dan Aktiviti Antioksidan Alginat daripada Sargassum sp.