Accelerating full thickness wound healing using collagen sponge of mrigal fish (Cirrhinus cirrhosus) scale origin.

The potentiality of collagen sponge as a skin substitute, derived from mrigal (Cirrhinus cirrhosus) scale has been explored in this study. Acid soluble collagen (ASC) and pepsin soluble collagen (PSC) from the scale of mrigal were isolated and characterized. The yields of ASC and PSC were ∼3% and ∼7% based on the dry weight of scale while the hydroxyproline content was ∼90mg/g. Scanning electron microscope revealed progressive demineralization with EDTA on time dependent scale. Further, the D-Spacing in fibril bundles were calculated to be ∼67nm. Fourier transform infrared and circular dichroism spectra confirmed extracted protein to be collagen I, where both ASC and PSC comprised of two different α-chains (α1 and α2). The denaturation temperature (Td) of the collagen solution was 35°C closer to Td of mammalian collagen. In vitro cell culture studies on the extracted collagen sponge showed efficient cell growth and proliferation. Additionally, co-culture with fibroblast and keratinocyte cells showed development of stratified epidermal layer in vitro. Faster wound healing potential of the extracted collagen in a rat model proved its applicability as a dermal substitute.

Investigating the potential of human placenta-derived extracellular matrix sponges coupled with amniotic membrane-derived stem cells for osteochondral tissue engineering.

Osteochondral injuries are challenging to repair due to their complex tissue anatomy and restricted self-repairing ability associated with a limited blood supply. Osteochondral tissue engineering is an important clinical aspect of the management and treatment of cartilage and underlying bone. In the present study, we fabricated human placenta-derived extracellular matrix sponges (PEMS) for repair of osteochondral tissue through a decellularization process. There were no significant cellular components present in the PEMS; hematoxylin & eosin/DAPI staining, DNA quantification and agarose gel electrophoresis were used to evaluate the extent of decellularization. Moreover, no significant alteration to the collagen and glycosaminoglycan (native extracellular matrix) content of the PEMS was observed. PEMS in vitro provided a non-cytotoxic environment rich in bioactive cues for human amniotic membrane-derived stem cells (HAMSCs) to proliferate in and differentiate into chondrogenic and osteogenic lineages under induction. Histological analysis at 28 days after the PEMS were subcutaneously implanted demonstrated no severe immune response in the host and supported the formation of blood vessels. To assess the osteochondral tissue repair ability of PEMS, cell-free PEMS (CFP) and cell-seeded PEMS (CSP) were implanted at osteochondral defect sites in a rabbit model. Histological scores indicated that osteochondral regeneration was more successful in the defects filled with CSP compared to those filled with CFP and empty defects (ED) after 60 days of implantation. In summary, a naturally derived biocompatible scaffold composed of extracellular matrix from human placenta has been successfully developed for osteochondral tissue engineering.