David M.J. Ernst scite author profile

The impact of peracetic acid (PAA), lyophilization, and ethylene oxide (EO) sterilization on the composition and three dimensional matrix structure of small intestinal submucosa (SIS), a biologic scaffold used to stimulate the repair of damaged tissues and organs, was examined. Fibronectin and glycosaminoglycans are retained in SIS following oxidation by peracetic acid and alkylation using ethylene oxide gas. Significant amounts of FGF-2 are also retained, but VEGF is susceptible to the effects of PAA and is dramatically reduced following processing. Further, matrix oxidation, lyophilization, and sterilization with EO can be performed without irreversibly collapsing the three dimensional structure of the native SIS. These structural features and growth promoting extracellular matrix constituents are likely to be important variables underlying cellular attachment, infiltration and eventual incorporation of SIS into healing host tissues.

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An investigation of the long-term bioactivity of endogenous growth factor in OASIS Wound Matrix

Hodde

2005

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The results demonstrate that wound-care products can be developed to retain their bioactivity over time and that inherently unstable purified growth factors are preserved if stored as bound factors within their natural extracellular matrix. The results also suggest that use of acellular matrices containing active growth factors would have advantages in terms of simplicity and cost over purified recombinant growth factor therapies.

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Tensile Strength Comparison of Small Intestinal Submucosa Body Wall Repair

Kazacos

Snyder

et al. 2006

Journal of Surgical Research

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Structural Characteristics of Small Intestinal Submucosa Constructs Dictate In Vivo Incorporation and Angiogenic Response

et al. 2011

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The rate of angiogenesis and cellular infiltration into degradable biomaterials determines scaffold persistence in vivo. The ability to tune the degradation properties of naturally derived biomaterials has been a popular goal in tissue engineering, yet has often depended on chemical crosslinking. Small intestinal submucosa (SIS) is a naturally derived, collagen-based, bioactive scaffold that has broad clinical success in many therapeutic applications. Two methods for producing multilayer, non-crosslinked SIS constructs were compared in vitro and in vivo. Traditional and cryo SEM, mercury intrusion porosimetry, and a novel enzymatic degradation assay determined that lyophilization produced an open, porous scaffold, in contrast to the collapsed, denser structure of SIS constructs produced using a vacuum press process. The angiogenic responses to lyophilized and vacuum-pressed SIS constructs were evaluated in vivo using a subcutaneous implant assay in mice. Explanted samples were compared after 7 and 21 days using fluorescence microangiography and light microscopy. Capacity of the implant neovasculature was also determined. These experiments revealed that the lyophilized SIS was infiltrated and vascularized more rapidly than the vacuum pressed. These data demonstrate the tunable incorporation of a non-crosslinked ECM-based biomaterial, which may have implications for the persistence of this degradable scaffold in tissue engineering.

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Absorption of Bioactive Molecules into OASIS Wound Matrix

Nihsen

Zopf

Ernst

et al. 2007

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David M.J. Ernst

Effects of sterilization on an extracellular matrix scaffold: Part I. Composition and matrix architecture

An investigation of the long-term bioactivity of endogenous growth factor in OASIS Wound Matrix

Tensile Strength Comparison of Small Intestinal Submucosa Body Wall Repair

Structural Characteristics of Small Intestinal Submucosa Constructs Dictate In Vivo Incorporation and Angiogenic Response

Absorption of Bioactive Molecules into OASIS Wound Matrix

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