Biofunctionalized Microfiber-Assisted Formation of Intrinsic Three-Dimensional Capillary-Like Structures

Weinandy, Stefan; Laffar, Simone; Unger, Ronald E.; Flanagan, Thomas R.; Loesel, Robert; Kirkpatrick, Charles James; Zandvoort, Marc van; Hermanns-Sachweh, Benita; Dreier, Agnieszka; Klee, Doris; Jockenhoevel, Stefan

doi:10.1089/ten.tea.2013.0330

Cited by 25 publications

(24 citation statements)

References 44 publications

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“…In order to successfully construct smooth muscle layer, smooth muscle cell's (SMC) penetration into the scaffold and its phenotype modulation within the scaffold are two prerequisites. The former confirms the cells can enter the scaffold to initiate the regeneration, and the latter ensured the cells could play the correct roles within the scaffold in the different periods to finalize regeneration and endow psychological functions . Cell penetration and phenotype modulation are thought to be heavily depending on the scaffold's property because it provides the main environment for cell attachment, immigration, growth and proliferation.…”

Section: Introductionmentioning

confidence: 84%

“…The former confirms the cells can enter the scaffold to initiate the regeneration, and the latter ensured the cells could play the correct roles within the scaffold in the different periods to finalize regeneration and endow psychological functions. [12][13][14] Cell penetration and phenotype modulation are thought to be heavily depending on the scaffold's property because it provides the main environment for cell attachment, immigration, growth and proliferation. Although some methods such as adding growth factors can be used to modulate cell penetration and phenotype expression in vitro, the feasible method becomes very few in vivo.…”

Section: Introductionmentioning

confidence: 99%

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The penetration and phenotype modulation of smooth muscle cells on surface heparin modified poly(ɛ‐caprolactone) vascular scaffold

Cao

Geng

Wen

et al. 2017

J Biomedical Materials Res

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The tubular porous poly(ɛ-caprolactone) (PCL) scaffold was fabricated by electrospinning. After then, the scaffold's surface was firstly eroded by hexyldiamine to endow amine group, and heparin was covalently grafted to the surface to get surface heparin modified scaffold (ShPCL scaffold). It was found that ShPCL scaffold can induce smooth muscle cells (SMCs) to penetrate the scaffold surface, while the SMCs cannot penetrate the surface of PCL scaffold. Subsequently, the rabbit SMCs were seeded on the ShPCL scaffold and cultured for 14 days. It was found the expression of α-smooth muscle actin in ShPCL scaffold maintained much higher level than that in culture plate, which implied the SMC differentiation in ShPCL scaffold. Furthermore, the immunefluorescence staining of the cross-sections of ShPCL scaffold exhibited the expression of calponin in ShPCL scaffold can be detected after 7 and 14 days, whereas the expression of smooth muscle myosin heavy chain can also be detected at 14 days. These results proved that penetrated SMCs preferably differentiated in to contractile phenotype. The successful SMC penetration and the contractile phenotype expression implied ShPCL scaffold is a suitable candidate for regenerating smooth muscle layer in vascular tissue engineering. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 2806-2815, 2017.

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Section: Introductionmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

The penetration and phenotype modulation of smooth muscle cells on surface heparin modified poly(ɛ‐caprolactone) vascular scaffold

Cao

Geng

Wen

et al. 2017

J Biomedical Materials Res

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“…Over 7 days in unconstrained culture, the dimensions of the FCG scaffold did not change, showing an ability to resist cellular-induced contraction, while still maintaining cell viability. As collagen also forms the main component of a range of other tissue types within the body, the FCG scaffold presented has potential for applications in areas such as cartilage repair, wound healing and in applications where angiogenesis is important (Weinandy et al 2014) due to its mechanical properties and unique biological framework. We are currently focussing on cardiovascular applications for this material, specifically as a heart valve scaffold.…”

Section: Discussionmentioning

confidence: 99%

“…Fibrin is a naturally-occurring polymer involved in the wound-healing response. It can be extracted from the blood of a potential patient, creating a biocompatible, autologous material, whose peptide chains and integrin binding sites encourage cell adhesion, migration, proliferation, and angiogenesis (Haisch et al 2000;Jockenhoevel et al 2001;Weinandy et al 2014). Fibrin can be used to encapsulate cells, creating a construct with a homogenous cell distribution and has been used in a range of applications including neural regeneration, wound healing, bone grafts, cartilage repair and cardiovascular applications (Ahmed et al 2008).…”

Section: Introductionmentioning

confidence: 99%

Incorporation of fibrin into a collagen–glycosaminoglycan matrix results in a scaffold with improved mechanical properties and enhanced capacity to resist cell-mediated contraction

et al. 2015

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Fibrin is a versatile scaffold for tissue engineering applications, but its weak mechanical properties leave it susceptible to cell-mediated contraction, meaning the dimensions of the fibrin construct will change over time. We have reinforced fibrin with a collagen glycosaminoglycan matrix and characterised the mechanical properties and bioactivity of the reinforced fibrin (FCG). This is the first scaffold manufactured from all naturally derived materials that resists cell-mediated contraction. In fact, over 7 days, the FCG scaffold fully resisted cell-mediated contraction of vascular smooth muscle cells. This FCG scaffold has many potential applications where natural scaffold materials can encourage regeneration.

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“…Although those scaffolds possessed excellent affinity toward the vascular cells including endothelial, smooth muscle, and fibroblast cells, and could promote the cells to attach, grow, and proliferate on the surface with good morphology, they can hardly perform as 3D scaffold to induce the seeded cells to infiltrate into the interior of the scaffold and proliferate inside the scaffold. As pointed out in literatures, in general TEVG cannot be successfully constructed without 3D scaffold because the regeneration of TEVG cannot be effectively carried out as the cells cannot penetrate the scaffold and take the responsibility of vessel regeneration inside the scaffold. For instance, a TEVG may fail due to the loss of mechanical property resulting from the scaffold degradation if SMCs cannot enter the scaffold wall and regenerate the necessary ECM to provide mechanical strength and keep integrity for the regenerating TEVG.…”

Section: Introductionmentioning

confidence: 99%

The fabrication of double layer tubular vascular tissue engineering scaffold via coaxial electrospinning and its 3D cell coculture

Cao

Chen

et al. 2015

J Biomedical Materials Res

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A continuous electrospinning technique was applied to fabricate double layer tubular tissue engineering vascular graft (TEVG) scaffold. The luminal layer was made from poly(ɛ-caprolac-tone)(PCL) ultrafine fibers via common single axial electrospinning followed by the outer layer of core-shell structured nanofibers via coaxial electrospinning. For preparing the outer layernano-fibers, the PCL was electrospun into the shell and both bovine serum albumin (BSA) and tetrapeptide val-gal-pro-gly (VAPG) were encapsulated into the core. The core-shell structure in the outer layer fibers was observed by transmission electron microscope (TEM). The in vitro release tests exhibited the sustainable release behavior of BSA and VAPG so that they provided a better cell growth environment in the interior of tubular scaffold wall. The in vitro culture of smooth muscle cells (SMCs) demonstrated their potential to penetrate into the scaffold wall for the 3D cell culture. Subsequently, 3D cell coculture was conducted. First, SMCs were seeded on the luminal surface of the scaffold and cultured for 5 days, and then endothelial cells (ECs) were also seeded on the luminal surface and cocultured with SMCs for another 2 days. After stained with antibodies, 3D cell distribution on the scaffold was revealed by confocal laser scanning microscopy (CLSM) where ECs were mainly located on the luminal surface whereas SMCs penetrated into the surface and distributed inside the scaffold wall. This double layer tubular scaffold with 3D cell distribution showed the promise to develop it into a novel TEVG for clinical trials in the near future.

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Biofunctionalized Microfiber-Assisted Formation of Intrinsic Three-Dimensional Capillary-Like Structures

Abstract: The guidance of vessel growth within tissue-engineered constructs can be achieved using biofunctionalized PLLA microfibers. Further methods are warranted to perform specified spatial positioning of fibers within 3D formative scaffolds to enhance the applicability of the concept.

Cited by 25 publications

References 44 publications

The penetration and phenotype modulation of smooth muscle cells on surface heparin modified poly(ɛ‐caprolactone) vascular scaffold

The penetration and phenotype modulation of smooth muscle cells on surface heparin modified poly(ɛ‐caprolactone) vascular scaffold

Incorporation of fibrin into a collagen–glycosaminoglycan matrix results in a scaffold with improved mechanical properties and enhanced capacity to resist cell-mediated contraction

The fabrication of double layer tubular vascular tissue engineering scaffold via coaxial electrospinning and its 3D cell coculture

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