TY - JOUR
T1 - Elastic serum-albumin based hydrogels
T2 - Mechanism of formation and application in cardiac tissue engineering
AU - Amdursky, Nadav
AU - Mazo, Manuel M.
AU - Thomas, Michael R.
AU - Humphrey, Eleanor J.
AU - Puetzer, Jennifer L.
AU - St-Pierre, Jean Philippe
AU - Skaalure, Stacey C.
AU - Richardson, Robert M.
AU - Terracciano, Cesare M.
AU - Stevens, Molly M.
PY - 2018/1/1
Y1 - 2018/1/1
N2 - Hydrogels are promising materials for mimicking the extra-cellular environment. Here, we present a simple methodology for the formation of a free-standing viscoelastic hydrogel from the abundant and low cost protein serum albumin. We show that the mechanical properties of the hydrogel exhibit a complicated behaviour as a function of the weight fraction of the protein component. We further use X-ray scattering to shed light on the mechanism of gelation from the formation of a fibrillary network at low weight fractions to interconnected aggregates at higher weight fractions. Given the match between our hydrogel elasticity and that of the myocardium, we investigated its potential for supporting cardiac cells in vitro. Interestingly, these hydrogels support the formation of several layers of myocytes and significantly promote the maintenance of a native-like gene expression profile compared to those cultured on glass. When confronted with a multicellular ventricular cell preparation, the hydrogels can support macroscopically contracting cardiac-like tissues with a distinct cell arrangement, and form mm-long vascular-like structures. We envisage that our simple approach for the formation of an elastic substrate from an abundant protein makes the hydrogel a compelling biomedical material candidate for a wide range of cell types.
AB - Hydrogels are promising materials for mimicking the extra-cellular environment. Here, we present a simple methodology for the formation of a free-standing viscoelastic hydrogel from the abundant and low cost protein serum albumin. We show that the mechanical properties of the hydrogel exhibit a complicated behaviour as a function of the weight fraction of the protein component. We further use X-ray scattering to shed light on the mechanism of gelation from the formation of a fibrillary network at low weight fractions to interconnected aggregates at higher weight fractions. Given the match between our hydrogel elasticity and that of the myocardium, we investigated its potential for supporting cardiac cells in vitro. Interestingly, these hydrogels support the formation of several layers of myocytes and significantly promote the maintenance of a native-like gene expression profile compared to those cultured on glass. When confronted with a multicellular ventricular cell preparation, the hydrogels can support macroscopically contracting cardiac-like tissues with a distinct cell arrangement, and form mm-long vascular-like structures. We envisage that our simple approach for the formation of an elastic substrate from an abundant protein makes the hydrogel a compelling biomedical material candidate for a wide range of cell types.
UR - http://www.scopus.com/inward/record.url?scp=85053466244&partnerID=8YFLogxK
U2 - 10.1039/c8tb01014e
DO - 10.1039/c8tb01014e
M3 - Article (Academic Journal)
AN - SCOPUS:85053466244
SN - 2050-7518
VL - 6
SP - 5604
EP - 5612
JO - Journal of Materials Chemistry B
JF - Journal of Materials Chemistry B
IS - 35
ER -