Literature DB >> 19709740

The effects of heparin releasing hydrogels on vascular smooth muscle cell phenotype.

Jeffrey A Beamish1, Leah C Geyer, Nada A Haq-Siddiqi, Kandice Kottke-Marchant, Roger E Marchant.   

Abstract

Poly(ethylene glycol) diacrylate (PEGDA) hydrogel scaffolds were engineered to promote contractile smooth muscle cell (SMC) phenotype via controlled release of heparin. The scaffold design was evaluated by quantifying the effects of free heparin on SMC phenotype, engineering hydrogels to provide controlled release of heparin, and synthesizing cell-adhesive, heparin releasing hydrogels to promote contractile SMC phenotype. Heparin inhibited SMC proliferation and up-regulated expression of contractile SMC phenotype markers, including smooth muscle alpha-actin, calponin, and SM-22alpha, in a dose-dependent fashion (6 microg/ml to 3.2mg/ml). Heparin release from PEGDA hydrogels was controlled by altering PEGDA molecular weight (MW 1000-6000) and concentration at polymerization (10-30% w/w), yielding release profiles ranging from hours to weeks in duration. Heparin released from PEGDA gels, formulated for optimized heparin loading and release kinetics (30% w/w PEGDA, MW 3000), stimulated SMCs to up-regulate contractile marker mRNA. A cell-instructive scaffold construct was prepared by polymerizing a thin hydrogel film, with pendant RGD peptides for cell attachment, over the optimized hydrogel depots. SMCs seeded on these constructs had elevated levels of contractile marker mRNA after 3 d of culture compared with SMCs on control constructs. These results indicate that RGD-modified, heparin releasing PEGDA gels can act as cell-instructive scaffolds that promote contractile SMC phenotype.

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Year:  2009        PMID: 19709740      PMCID: PMC2772992          DOI: 10.1016/j.biomaterials.2009.08.004

Source DB:  PubMed          Journal:  Biomaterials        ISSN: 0142-9612            Impact factor:   12.479


  51 in total

1.  Smooth muscle-specific SM22 protein is expressed in the adventitial cells of balloon-injured rabbit carotid artery.

Authors:  E Faggin; M Puato; L Zardo; R Franch; C Millino; F Sarinella; P Pauletto; S Sartore; A Chiavegato
Journal:  Arterioscler Thromb Vasc Biol       Date:  1999-06       Impact factor: 8.311

2.  Cyclic mechanical strain regulates the development of engineered smooth muscle tissue.

Authors:  B S Kim; J Nikolovski; J Bonadio; D J Mooney
Journal:  Nat Biotechnol       Date:  1999-10       Impact factor: 54.908

3.  Arterial heparan sulfate proteoglycans inhibit vascular smooth muscle cell proliferation and phenotype change in vitro and neointimal formation in vivo.

Authors:  J A Bingley; I P Hayward; J H Campbell; G R Campbell
Journal:  J Vasc Surg       Date:  1998-08       Impact factor: 4.268

4.  Differentiated phenotype of smooth muscle cells depends on signaling pathways through insulin-like growth factors and phosphatidylinositol 3-kinase.

Authors:  K Hayashi; H Saga; Y Chimori; K Kimura; Y Yamanaka; K Sobue
Journal:  J Biol Chem       Date:  1998-10-30       Impact factor: 5.157

Review 5.  Mechanical influences on vascular smooth muscle cell function.

Authors:  B Williams
Journal:  J Hypertens       Date:  1998-12       Impact factor: 4.844

6.  Characterization of permeability and network structure of interfacially photopolymerized poly(ethylene glycol) diacrylate hydrogels.

Authors:  G M Cruise; D S Scharp; J A Hubbell
Journal:  Biomaterials       Date:  1998-07       Impact factor: 12.479

7.  Platelet-derived growth factor-BB, insulin-like growth factor-I, and phorbol ester activate different signaling pathways for stimulation of vascular smooth muscle cell migration.

Authors:  L Pukac; J Huangpu; M J Karnovsky
Journal:  Exp Cell Res       Date:  1998-08-01       Impact factor: 3.905

8.  Forced expression of myocardin is not sufficient for induction of smooth muscle differentiation in multipotential embryonic cells.

Authors:  Tadashi Yoshida; Keiko Kawai-Kowase; Gary K Owens
Journal:  Arterioscler Thromb Vasc Biol       Date:  2004-07-01       Impact factor: 8.311

9.  Binding and internalization of heparin by vascular smooth muscle cells.

Authors:  J J Castellot; K Wong; B Herman; R L Hoover; D F Albertini; T C Wright; B L Caleb; M J Karnovsky
Journal:  J Cell Physiol       Date:  1985-07       Impact factor: 6.384

10.  In vitro osteogenic differentiation of human mesenchymal stem cells photoencapsulated in PEG hydrogels.

Authors:  Charles R Nuttelman; Margaret C Tripodi; Kristi S Anseth
Journal:  J Biomed Mater Res A       Date:  2004-03-15       Impact factor: 4.396
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  13 in total

Review 1.  Molecular regulation of contractile smooth muscle cell phenotype: implications for vascular tissue engineering.

Authors:  Jeffrey A Beamish; Ping He; Kandice Kottke-Marchant; Roger E Marchant
Journal:  Tissue Eng Part B Rev       Date:  2010-10       Impact factor: 6.389

Review 2.  Tissue Engineering at the Blood-Contacting Surface: A Review of Challenges and Strategies in Vascular Graft Development.

Authors:  Daniel Radke; Wenkai Jia; Dhavan Sharma; Kemin Fena; Guifang Wang; Jeremy Goldman; Feng Zhao
Journal:  Adv Healthc Mater       Date:  2018-05-07       Impact factor: 9.933

3.  Effect of heparin oligomer chain length on the activation of valvular interstitial cells.

Authors:  Sara Pedron; Andrea M Kasko; Carmen Peinado; Kristi S Anseth
Journal:  Biomacromolecules       Date:  2010-06-14       Impact factor: 6.988

4.  Multilayered heparin hydrogel microwells for cultivation of primary hepatocytes.

Authors:  Jungmok You; Dong-Sik Shin; Dipali Patel; Yandong Gao; Alexander Revzin
Journal:  Adv Healthc Mater       Date:  2013-07-05       Impact factor: 9.933

5.  Enhancing angiogenesis alleviates hypoxia and improves engraftment of enteric cells in polycaprolactone scaffolds.

Authors:  Shivani Singh; Benjamin M Wu; James C Y Dunn
Journal:  J Tissue Eng Regen Med       Date:  2012-04-18       Impact factor: 3.963

6.  Biomimetic-engineered poly (ethylene glycol) hydrogel for smooth muscle cell migration.

Authors:  Lin Lin; Junmin Zhu; Kandice Kottke-Marchant; Roger E Marchant
Journal:  Tissue Eng Part A       Date:  2014-01-09       Impact factor: 3.845

7.  Effects of recipient age, heparin release and allogeneic bone marrow-derived stromal cells on vascular graft remodeling.

Authors:  Richard Johnson; Michael Rafuse; Prakash Parthiban Selvakumar; Wei Tan
Journal:  Acta Biomater       Date:  2021-02-24       Impact factor: 8.947

8.  Addressing the Inflammatory Response to Clinically Relevant Polymers by Manipulating the Host Response Using ITIM Domain-Containing Receptors.

Authors:  Joshua B Slee; Abigail J Christian; Robert J Levy; Stanley J Stachelek
Journal:  Polymers (Basel)       Date:  2014-09-29       Impact factor: 4.329

9.  Heparin nanomodification improves biocompatibility and biomechanical stability of decellularized vascular scaffolds.

Authors:  Yunming Tao; Tiehui Hu; Zhongshi Wu; Hao Tang; Yerong Hu; Qi Tan; Chunlin Wu
Journal:  Int J Nanomedicine       Date:  2012-11-26

Review 10.  Biomaterials in cardiovascular research: applications and clinical implications.

Authors:  Saravana Kumar Jaganathan; Eko Supriyanto; Selvakumar Murugesan; Arunpandian Balaji; Manjeesh Kumar Asokan
Journal:  Biomed Res Int       Date:  2014-05-08       Impact factor: 3.411
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