4.8 Article

Direct comparison of angiogenesis in natural and synthetic biomaterials reveals that matrix porosity regulates endothelial cell invasion speed and sprout diameter

Journal

ACTA BIOMATERIALIA
Volume 135, Issue -, Pages 260-273

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.actbio.2021.08.038

Keywords

Angiogenesis; Cell migration; Cell proliferation; Microfluidics; ECM; Endothelial cells; Chemotaxis; Hydrogels; Microvasculature; Sprouting Morphogenesis; Matrix porosity

Funding

  1. National Institutes of Health [T32HL69768, HL124322, EB030474]
  2. Juvenile Diabetes Research Foundation [1-INO-2020-916-A-N]
  3. University of Michigan Rackham Merit Fellowship the National Science Foundation Graduate Research Fellowship Program [DGE1256260]
  4. Ruth L. Kirschstein National Research Service Award [F31HL152501]
  5. National Science Foundation Graduate Research Fellowship Program [DGE1256260]

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This research compares the angiogenic potential of commonly used natural and synthetic hydrogels, finding that matrix permeability significantly correlates with endothelial cell invasion depth and sprout diameter. Microporous hydrogels produced lumenized sprouts in vitro and enhanced cell invasion in vivo.
Vascularization of large, diffusion-hindered biomaterial implants requires an understanding of how ex-tracellular matrix (ECM) properties regulate angiogenesis. Sundry biomaterials assessed across many dis-parate angiogenesis assays have highlighted ECM determinants that influence this complex multicellular process. However, the abundance of material platforms, each with unique parameters to model endothe-lial cell (EC) sprouting presents additional challenges of interpretation and comparison between studies. In this work we directly compared the angiogenic potential of commonly utilized natural (collagen and fibrin) and synthetic dextran vinyl sulfone (DexVS) hydrogels in a multiplexed angiogenesis-on-a-chip platform. Modulating matrix density of collagen and fibrin hydrogels confirmed prior findings that in-creases in matrix density correspond to increased EC invasion as connected, multicellular sprouts, but with decreased invasion speeds. Angiogenesis in synthetic DexVS hydrogels, however, resulted in fewer multicellular sprouts. Characterizing hydrogel Young's modulus and permeability (a measure of matrix porosity), we identified matrix permeability to significantly correlate with EC invasion depth and sprout diameter. Although microporous collagen and fibrin hydrogels produced lumenized sprouts in vitro , they rapidly resorbed post-implantation into the murine epididymal fat pad. In contrast, DexVS hydrogels proved comparatively stable. To enhance angiogenesis within DexVS hydrogels, we incorporated sacrificial microgels to generate cell-scale pores throughout the hydrogel. Microporous DexVS hydrogels resulted in lumenized sprouts in vitro and enhanced cell invasion in vivo. Towards the design of vascularized bioma-terials for long-term regenerative therapies, this work suggests that synthetic biomaterials offer improved size and shape control following implantation and that tuning matrix porosity may better support host angiogenesis. Statement of significance Understanding how extracellular matrix properties govern angiogenesis will inform biomaterial design for engineering vascularized implantable grafts. Here, we utilized a multiplexed angiogenesis-on-a-chip platform to compare the angiogenic potential of natural (collagen and fibrin) and synthetic dextran vinyl sulfone (DexVS) hydrogels. Characterization of matrix properties and sprout morphometrics across these materials points to matrix porosity as a critical regulator of sprout invasion speed and diameter, supported by the observation that nanoporous DexVS hydrogels yielded endothelial cell sprouts that were not perfusable. To enhance angiogenesis into synthetic hydrogels, we incorporated sacrificial microgels to generate microporosity. We find that microporosity increased sprout diameter in vitro and cell invasion in vivo . This work establishes a composite materials approach to enhance the vascularization of synthetic hydrogels. (c) 2021 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

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