Bioactive Electrospun Fibers of Poly(glycerol sebacate) and Poly(ε‐caprolactone) for Cardiac Patch Application

Rai, Ranjana; Tallawi, Marwa; Frati, Caterina; Falco, Angela; Gervasi, A.; Quaini, Federico; Roether, Judith A.; Hochburger, Tobias; Schubert, Dirk; Seik, Lothar; Barbani, Niccoletta; Lazzeri, Luigi; Rosellini, Elisabetta; Boccaccını, Aldo R.

doi:10.1002/adhm.201500154

Cited by 72 publications

(65 citation statements)

References 54 publications

(55 reference statements)

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“…Recently, 3D microporous PCL scaffolds with pore sizes of 40–100 μm have been fabricated by selective laser sintering for cardiac tissue engineering (Yeong et al, ); others, with complex geometries, have been fabricated by electrodynamic jetting to potentially improve cell migration (Rai et al, ) during cell cultivation. Although cells proliferated in the 3D scaffolds, hardly any 3D cell aggregates or microtissues formed in the scaffolds.…”

Section: Introductionmentioning

confidence: 99%

Morphological transformation of h BMSC from 2 D monolayer to 3 D microtissue on low‐crystallinity SF‐PCL patch with promotion of cardiomyogenesis

Huang

Lee

et al. 2017

J Tissue Eng Regen Med

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The effects of the stiffness of substrates on the cell behaviours of human bone marrow-derived mesenchymal stem cells (hBMSC) have been investigated, but the effects of the secondary structures of proteins in the substrates on the morphological transformation and differentiation of hBMSC have yet been elucidated. To investigate these issues, silk fibroin-poly(ε-caprolactone) SP cardiac patches of poly(ε-caprolactone; P), on which is grafted by silk fibroin (SF) with various β-sheet contents (or crystallinity) to provide various degrees of stiffness, were produced to examine the in vitro behaviours of hBMSC during proliferation, and cardiomyogenesis on the SP patches. β-sheet contents of SF from 20% to 44% (SP20 to SP44, respectively) were induced on patches, which were examined by attenuated total reflection Fourier-transform infrared (ATR-FTIR) spectroscopy, and analysed using the Fourier self-deconvolution method. The stiffness of the SP patches, quantified by their Young's moduli and elasticities, increased with the crystallinity of the SF. During 3 days of proliferation, hBMSC migrated and morphologically transformed into 3D microtissues with diameters of approximately 150-200 μm on low-stiffness SP20 and SP30 patches, whereas 2D monolayers were observed on the SP37 and SP44 patches. The 3D microtissues/patch yielded more extensive in vitro cardiomyogenesis of hBMSC than the 2D cell monolayer with significantly higher expressions of all examined cardiac-specific proteins after induction by 5-aza. Notably, in vivo subcutaneously growing 3D microtissues on SP20 patches and a 2D monolayer on SP44 patches were preliminarily demonstrated in a rat model. Morphological transformations of hBMSC from a 2D monolayer to a 3D microtissue by low-stiffness SP cardiac patches, promoting cardiomyogenesis, provide a new opportunity for cardiac tissue engineering.

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Section: Introductionmentioning

confidence: 99%

Morphological transformation of h BMSC from 2 D monolayer to 3 D microtissue on low‐crystallinity SF‐PCL patch with promotion of cardiomyogenesis

Huang

Lee

et al. 2017

J Tissue Eng Regen Med

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“…The following years brought many publications in which electrospun PCL-PGS blends were investigated within fundamental and utilitarian scopes, starting from studies of structure and mechanical properties of nonwovens and fibers, through cell guidance and corneal tissues, until materials for heart valves and cardiac patches [10,[13][14][15][16][17]. Such approaches, where PGS prepolymer without subsequent crosslinking is reinforced by much tougher polyester with very good mechanical properties, and at the same time is carried by that polymer during the electrospinning process, may provoke thoughts that the elastomeric potential of PGS is wasted.…”

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confidence: 99%

Poly(Glycerol Sebacate)–Poly(l-Lactide) Nonwovens. Towards Attractive Electrospun Material for Tissue Engineering

2019

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Two types of poly(glycerol sebacate) (PGS) prepolymers were synthesized and electrospun with poly(l-lactic acid) (PLA), resulting in bicomponent nonwovens. The obtained materials were pre-heated in a vacuum, at different times, to crosslink PGS and investigate morphological and structural dependencies in that polymeric, electrospun system. As both PGS and PLA are sensitive to pre-heating (crosslinking) conditions, research concerns both components. More interest is focused on the properties of PGS, considering further research for mechanical properties and subsequent experiments with PGS synthesis. Electrospinning of PGS blended with PLA does not bring difficulties, but obtaining elastomeric properties of nonwovens is problematic. Even though PGS has many potential advantages over other polyesters when soft tissue engineering is considered, its full utilization via the electrospinning process is much harder in practice. Further investigations are ongoing, especially with the promising PGS prepolymer with a higher esterification degree and its variations.

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“…Based on the biomimetic concept, we employed 3D printing to fabricate a multilayered hierarchical porous scaffold composed of the synthetic polymers PGS and PCL (Figure A,B). Although electrospun PGS‐PCL fibers have been reported for cardiac patch applications, the PGS component of PGS‐PCL nanofibers in the previous study were still un‐crosslinked, and the electrospun patches lacked precisely controlled microstructures. This approach was designed to impart the polymer scaffolds with hierarchical structures in multiple levels (Figure L–O).…”

Section: Discussionmentioning

confidence: 86%

Elastic 3D‐Printed Hybrid Polymeric Scaffold Improves Cardiac Remodeling after Myocardial Infarction

Yang

Lei

Huang

et al. 2019

Adv Healthcare Materials

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Myocardial remodeling, including ventricular dilation and wall thinning, is an important pathological process caused by myocardial infarction (MI). To intervene in this pathological process, a new type of cardiac scaffold composed of a thermoset (poly‐[glycerol sebacate], PGS) and a thermoplastic (poly‐[ε‐caprolactone], PCL) is directly printed by employing fused deposition modeling 3D‐printing technology. The PGS‐PCL scaffold possesses stacked construction with regular crisscrossed filaments and interconnected micropores and exhibits superior mechanical properties. In vitro studies demonstrate favorable biodegradability and biocompatibility of the PGS‐PCL scaffold. When implanted onto the infarcted myocardium, this scaffold improves and preserves heart function. Furthermore, the scaffold improves several vital aspects of myocardial remodeling. On the morphological level, the scaffold reduces ventricular wall thinning and attenuated infarct size, and on the cellular level, it enhances vascular density and increases M2 macrophage infiltration, which might further contribute to the mitigated myocardial apoptosis rate. Moreover, the flexible PGS‐PCL scaffold can be tailored to any desired shape, showing promise for annular‐shaped restraint device application and meeting the demands for minimal invasive operation. Overall, this study demonstrates the therapeutic effects and versatile applications of a novel 3D‐printed, biodegradable and biocompatible cardiac scaffold, which represents a promising strategy for improving myocardial remodeling after MI.

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Bioactive Electrospun Fibers of Poly(glycerol sebacate) and Poly(ε‐caprolactone) for Cardiac Patch Application

Cited by 72 publications

References 54 publications

Morphological transformation of h BMSC from 2 D monolayer to 3 D microtissue on low‐crystallinity SF‐PCL patch with promotion of cardiomyogenesis

Morphological transformation of h BMSC from 2 D monolayer to 3 D microtissue on low‐crystallinity SF‐PCL patch with promotion of cardiomyogenesis

Poly(Glycerol Sebacate)–Poly(l-Lactide) Nonwovens. Towards Attractive Electrospun Material for Tissue Engineering

Elastic 3D‐Printed Hybrid Polymeric Scaffold Improves Cardiac Remodeling after Myocardial Infarction

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