Preparation of gradient-type biological tissue-polymer complex for interlinking device.

The aim of this study was to investigate the monomer absorption behavior of decellularized dermis and prepare a gradient-type decellularized dermis-polymer complex. Decellularized dermis was prepared using sodium dodecyl sulfate, and its monomer absorption behavior was investigated using three types of hydrophobic monomer with different surface free energies. The results show that monomer absorption depends strongly on the tissue structure, regardless of the surface free energy, and the amount of absorbed monomer can be increased by sonication. Based on these results, we prepared a gradient-type decellularized dermis-poly(methyl methacrylate) complex by controlling the permeation time of the methyl methacrylate monomer and polymerization initiator into the decellularized dermis. The mechanical strength of this complex gradually increased from the dermis side to the polymer side, and combined the physical characteristics of the dermis and the polymer.

Biodegradable and elastomeric vascular grafts enable vascular remodeling.

Implanted grafts, including vascular substitutes, inevitably experience remodeling by host cells. The design of grafts capable of promoting constructive remodeling remains a challenge within regenerative medicine. Here, we used a biodegradable elastic polymer, poly (l-lactide-co-ε-caprolactone) (PLCL), to develop a vascular graft with circumferentially aligned microfibers. The grafts exhibited excellent handling properties and resistance to deformation. Upon implantation in rat abdominal aorta, graft-guided neoartery regeneration was achieved in a short period (4 weeks) as evidenced by rapid cell infiltration and alignment, and complete endothelialization. During vascular remodeling, a high ratio of M2/M1 macrophage was detected, and the expression of pro-inflammatory and anti-inflammatory cytokines first increased and then decreased to normal level for the follow-up period. By 12 months, the PLCL grafts were almost completely degraded and a well-integrated neoartery was formed with characteristics comparable to native arteries, such as transparent appearance, synchronous pulsation, dense and orderly extracellular matrix (ECM) arrangement, strong and compliant mechanical properties, and vasomotor response to pharmacologic agents. Taken together, our strategy represents a new avenue for guided tissue regeneration by designing the grafts to promote tissue remodeling via controlling structure, degradation and mechanical properties of the scaffolds.

Decellularized porcine aortic intima-media as a potential cardiovascular biomaterial.

OBJECTIVES: The aim of this research is to investigate the histological and mechanical properties of decellularized aortic intima-media, a promising cardiovascular biomaterial. METHODS: Porcine aortic intima-media was decellularized using two methods: high hydrostatic pressurization (HHP) and sodium dodecyl sulphate (SDS). The histological properties were characterized using haematoxylin and eosin staining and Elastica van Gieson staining. The mechanical properties were evaluated using a tensile strength test. RESULTS: The structure of the HHP-treated samples was unchanged histologically, whereas that of the SDS-treated samples appeared structurally loose. Consequently, with regard to the mechanical properties of SDS-decellularized intima-media, elastic modulus and tensile strength were significantly decreased. CONCLUSIONS: The decellularization method affected the structure and the mechanical properties of the biomaterial. The HHP-treated sample was structurally and mechanically similar to the untreated control. Its mechanical properties were similar to those of human heart valves and the iliac artery and vein. Our results imply that porcine aortic intima-media that is decellularized with HHP is a potential cardiovascular biomaterial.