Sachin Velankar scite author profile

Extracellular matrix (ECM) bioscaffolds prepared from decellularized tissues have been used to facilitate constructive and functional tissue remodeling in a variety of clinical applications. The discovery that these ECM materials could be solubilized and subsequently manipulated to form hydrogels expanded their potential in vitro and in vivo utility; i.e. as culture substrates comparable to collagen or Matrigel, and as injectable materials that fill irregularly-shaped defects. The mechanisms by which ECM hydrogels direct cell behavior and influence remodeling outcomes are only partially understood, but likely include structural and biological signals retained from the native source tissue. The present review describes the utility, formation, and physical and biological characterization of ECM hydrogels. Two examples of clinical application are presented to demonstrate in vivo utility of ECM hydrogels in different organ systems. Finally, new research directions and clinical translation of ECM hydrogels are discussed.

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Preparation and rheological characterization of a gel form of the porcine urinary bladder matrix

Freytes

et al. 2008

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A hydrogel derived from decellularized dermal extracellular matrix

et al. 2012

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The ECM of mammalian tissues has been used as a scaffold to facilitate the repair and reconstruction of numerous tissues. Such scaffolds are prepared in many forms including sheets, powders, and hydrogels. ECM hydrogels provide advantages such as injectability, the ability to fill an irregularly shaped space, and the inherent bioactivity of native matrix. However, material properties of ECM hydrogels and the effect of these properties upon cell behavior are neither well understood nor controlled. The objective of this study was to prepare and determine the structure, mechanics, and the cell response in vitro and in vivo of ECM hydrogels prepared from decellularized porcine dermis and urinary bladder tissues. Dermal ECM hydrogels were characterized by a more dense fiber architecture and greater mechanical integrity than urinary bladder ECM hydrogels, and showed a dose dependent increase in mechanical properties with ECM concentration. In vitro, dermal ECM hydrogels supported greater C2C12 myoblast fusion, and less fibroblast infiltration and less fibroblast mediated hydrogel contraction than urinary bladder ECM hydrogels. Both hydrogels were rapidly infiltrated by host cells, primarily macrophages, when implanted in a rat abdominal wall defect. Both ECM hydrogels degraded by 35 days in vivo, but UBM hydrogels degraded more quickly, and with greater amounts of myogenesis than dermal ECM. These results show that ECM hydrogel properties can be varied and partially controlled by the scaffold tissue source, and that these properties can markedly affect cell behavior.

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Hydrogels derived from central nervous system extracellular matrix

et al. 2013

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Biologic scaffolds composed of extracellular matrix (ECM) are commonly used repair devices in preclinical and clinical settings; however the use of these scaffolds for peripheral and central nervous system (CNS) repair has been limited. Biologic scaffolds developed from brain and spinal cord tissue have recently been described, yet the conformation of the harvested ECM limits therapeutic utility. An injectable CNS-ECM derived hydrogel capable of in vivo polymerization and conformation to irregular lesion geometries may aid in tissue reconstruction efforts following complex neurologic trauma. The objectives of the present study were to develop hydrogel forms of brain and spinal cord ECM and compare the resulting biochemical composition, mechanical properties, and neurotrophic potential of a brain derived cell line to a non-CNS-ECM hydrogel, urinary bladder matrix. Results showed distinct differences between compositions of brain ECM, spinal cord ECM, and urinary bladder matrix. The rheologic modulus of spinal cord ECM hydrogel was greater than that of brain ECM and urinary bladder matrix. All ECMs increased the number of cells expressing neurites, but only brain ECM increased neurite length, suggesting a possible tissue-specific effect. All hydrogels promoted three-dimensional uni- or bi-polar neurite outgrowth following 7 days in culture. These results suggest that CNS-ECM hydrogels may provide supportive scaffolding to promote in vivo axonal repair.

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Microphase Separation and Rheological Properties of Polyurethane Melts. 1. Effect of Block Length

1998

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A series of polyesterurethanes with differing block length and constant composition have been synthesized for rheological studies. Hard segments based on isophorone diisocyanate and 1,4-butanediol and soft segments based on polycaprolactone to ensure high thermal stability and to prevent high melting point crystallinity enabled long-duration rheological characterization at high temperatures. DSC and SAXS revealed that, at any fixed temperature above the polyester melting point, the degree of microphase separation increased with block length, with the shortest block lengths being almost single-phase. Temperature-resolved SAXS experiments demonstrated gradual microphase mixing of the microphase-separated materials as the temperature increased. In addition, the SAXS data for one material were shown to obey the predictions of the mean field theory, allowing a mean field estimate of the spinodal temperature to be calculated. Frequency sweep dynamic mechanical experiments show viscoelastic behavior characteristic of a homopolymer for all materials at high temperatures, and master curves can been constructed using the principle of time−temperature superposition. A failure of time−temperature superposition was observed at lower temperatures in materials with large block length. Temperature-resolved SAXS studies suggest that this failure is related to the onset of microphase separation in these materials at low temperatures. In the high-temperature regime, where master curves can be constructed, the WLF equation with universal parameters fits the experimental shift factors very well if an apparent single-phase glass transition temperature (T g) is used. In addition, the relaxation time and the Newtonian viscosity of the polyurethanes show a strong dependence on block length, with a power law exponent of about 5.

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Sachin Velankar

Extracellular matrix hydrogels from decellularized tissues: Structure and function

Preparation and rheological characterization of a gel form of the porcine urinary bladder matrix

A hydrogel derived from decellularized dermal extracellular matrix

Hydrogels derived from central nervous system extracellular matrix

Microphase Separation and Rheological Properties of Polyurethane Melts. 1. Effect of Block Length

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