19 research outputs found
Protein modification by Amadori and Maillard reactions during seed storage: roles of sugar hydrolysis and lipid peroxidation
Process-induced extracellular matrix alterations affect the mechanisms of soft tissue repair and regeneration
Extracellular matrices derived from animal tissues for human tissue repairs are processed by various methods of physical, chemical, or enzymatic decellularization, viral inactivation, and terminal sterilization. The mechanisms of action in tissue repair vary among bioscaffolds and are suggested to be associated with process-induced extracellular matrix modifications. We compared three non-cross-linked, commercially available extracellular matrix scaffolds (Strattice, Veritas, and XenMatrix), and correlated extracellular matrix alterations to in vivo biological responses upon implantation in non-human primates. Structural evaluation showed significant differences in retaining native tissue extracellular matrix histology and ultrastructural features among bioscaffolds. Tissue processing may cause both the condensation of collagen fibers and fragmentation or separation of collagen bundles. Calorimetric analysis showed significant differences in the stability of bioscaffolds. The intrinsic denaturation temperature was measured to be 51°C, 38°C, and 44°C for Strattice, Veritas, and XenMatrix, respectively, demonstrating more extracellular matrix modifications in the Veritas and XenMatrix scaffolds. Consequently, the susceptibility to collagenase degradation was increased in Veritas and XenMatrix when compared to their respective source tissues. Using a non-human primate model, three bioscaffolds were found to elicit different biological responses, have distinct mechanisms of action, and yield various outcomes of tissue repair. Strattice permitted cell repopulation and was remodeled over 6 months. Veritas was unstable at body temperature, resulting in rapid absorption with moderate inflammation. XenMatrix caused severe inflammation and sustained immune reactions. This study demonstrates that extracellular matrix alterations significantly affect biological responses in soft tissue repair and regeneration. The data offer useful insights into the rational design of extracellular matrix products and bioscaffolds of tissue engineering
Desiccation sensitivity and activities of free radical-scavenging enzymes in recalcitrant Theobroma cacao seeds
Correlation of modified water sorption properties with the decline of storage stability of osmotically-primed seeds of Vigna radiata
Preferential accumulation of D-pinitol in Acrostichum aureum gametophytes in response to salt stress
10.1034/j.1399-3054.1999.105109.xPhysiologia Plantarum105151-57PHPL
Biopolymer volume change and water clustering function of primed Vigna radiata seeds
10.1079/SSR2003146Seed Science Research134287-302SESR
Aging of a Regenerative Biologic Scaffold (AlloDerm Native Tissue Matrix) During Storage at Elevated Humidity and Temperature
Up-regulation of sucrose metabolizing enzymes in Oncidium goldiana grown under elevated carbon dioxide
10.1034/j.1399-3054.2001.1130103.xPhysiologia Plantarum113115-22PHPL