Natural Biomaterials for Cardiac Tissue Engineering: A Highly Biocompatible Solution

Majid, Qasim A.; Fricker, Annabelle T. R.; Gregory, David A.; Davidenko, Natalia; Cruz, Olivia Hernandez; Jabbour, Richard J.; Owen, Thomas J.; Basnett, Pooja; Lukasiewicz, Barbara; Stevens, Molly M.; Best, Serena M.; Cameron, Ruth E.; Sinha, Sanjay; Harding, Siân E.; Roy, Ipsita

doi:10.3389/fcvm.2020.554597

Cited by 91 publications

(74 citation statements)

References 288 publications

(305 reference statements)

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“…It is also inexpensive compared to many other biomaterials [ 149 ]. However, alginate-based constructs show a weak cell adhesion, which may cause unfavorable tissue interactions and insufficient regenerative behavior [ 150 ]. The functionalization of alginate with cell adhesion-promoting ligands, such as arginine–glycine–asparagine RGD can support the interaction of the cells with the alginate matrix [ 151 ].…”

Section: Biomaterials For the Transplantation Of Striated Muscle Cellsmentioning

confidence: 99%

Current Strategies for the Regeneration of Skeletal Muscle Tissue

Alarçin

Bal‐Öztürk

Avcı

et al. 2021

IJMS

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Traumatic injuries, tumor resections, and degenerative diseases can damage skeletal muscle and lead to functional impairment and severe disability. Skeletal muscle regeneration is a complex process that depends on various cell types, signaling molecules, architectural cues, and physicochemical properties to be successful. To promote muscle repair and regeneration, various strategies for skeletal muscle tissue engineering have been developed in the last decades. However, there is still a high demand for the development of new methods and materials that promote skeletal muscle repair and functional regeneration to bring approaches closer to therapies in the clinic that structurally and functionally repair muscle. The combination of stem cells, biomaterials, and biomolecules is used to induce skeletal muscle regeneration. In this review, we provide an overview of different cell types used to treat skeletal muscle injury, highlight current strategies in biomaterial-based approaches, the importance of topography for the successful creation of functional striated muscle fibers, and discuss novel methods for muscle regeneration and challenges for their future clinical implementation.

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Section: Biomaterials For the Transplantation Of Striated Muscle Cellsmentioning

confidence: 99%

Current Strategies for the Regeneration of Skeletal Muscle Tissue

Alarçin

Bal‐Öztürk

Avcı

et al. 2021

IJMS

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“…Secondly, owing to their diminutive size, retaining them at a certain site or target tissue is challenging as they are easily flushed by circulation. Therefore, for indications that require the direct application of EVs to localized areas (e.g., ischemic injury), patches of various hydrogels have been developed as scaffolds to provide consistent retention and release [ 104 , 105 ]. More specific EV delivery-enhancement efforts have focused on altering the EV surface for improved tissue retention, including the use of chemically-embedded targeting antibodies or homing peptides [ 106 ].…”

Section: Therapeutic Roles Of Extracellular Vesiclesmentioning

confidence: 99%

Diagnostic and Therapeutic Applications of Extracellular Vesicles in Interstitial Lung Diseases

Ibrahim¹,

Ibrahim

Parimon

2021

Diagnostics

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Interstitial lung diseases (ILDs) are chronic irreversible pulmonary conditions with significant morbidity and mortality. Diagnostic approaches to ILDs are complex and multifactorial. Effective therapeutic interventions are continuously investigated and explored with substantial progress, thanks to advances in basic understanding and translational efforts. Extracellular vesicles (EVs) offer a new paradigm in diagnosis and treatment. This leads to two significant implications: new disease biomarker discovery that enables reliable diagnosis and disease assessment and the development of regenerative medicine therapeutics that target fibroproliferative processes in diseased lung tissue. In this review, we discuss the current understanding of the role of diseased tissue-derived EVs in the development of interstitial lung diseases, the utility of these EVs as diagnostic and prognostic tools, and the existing therapeutic utility of EVs. Furthermore, we review the potential therapeutic application of EVs derived from various cellular sources.

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“…Prosthetic or biological materials used for PA reconstruction are not ideal substitutes due to their thrombogenicity, limited durability, and inadequate growth and regeneration potential ( Manavitehrani et al, 2019 ). Tissue engineering aims to create advanced therapy medicinal products (ATMPs) endowed with normal tissue function including capacity for growth and self-repair ( Cheema et al, 2012 ; Durko et al, 2020 ; Majid et al, 2020 ). Cellularized vascular grafts can potentially overcome the shortcomings of currently used materials, and, if successfully passing all the development phases required for a marketing authorization, they might provide a better solution for the pediatric population.…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of the Swine Pulmonary Artery Using a Graft Engineered With Syngeneic Cardiac Pericytes

Alvino

Thomas

Ghorbel

et al. 2021

Front. Bioeng. Biotechnol.

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The neonatal heart represents an attractive source of regenerative cells. Here, we report the results of a randomized, controlled, investigator-blinded preclinical study, which assessed the safety and effectiveness of a matrix graft cellularized with cardiac pericytes (CPs) in a piglet model of pulmonary artery (PA) reconstruction. Within each of five trios formed by 4-week-old female littermate piglets, one element (the donor) was sacrificed to provide a source of CPs, while the other two elements (the graft recipients) were allowed to reach the age of 10 weeks. During this time interval, culture-expanded donor CPs were seeded onto swine small intestinal submucosa (SIS) grafts, which were then shaped into conduits and conditioned in a flow bioreactor. Control unseeded SIS conduits were subjected to the same procedure. Then, recipient piglets were randomized to surgical reconstruction of the left PA (LPA) with unseeded or CP-seeded SIS conduits. Doppler echocardiography and cardiac magnetic resonance imaging (CMRI) were performed at baseline and 4-months post-implantation. Vascular explants were examined using histology and immunohistochemistry. All animals completed the scheduled follow-up. No group difference was observed in baseline imaging data. The final Doppler assessment showed that the LPA’s blood flow velocity was similar in the treatment groups. CMRI revealed a mismatch in the average growth of the grafted LPA and contralateral branch in both treatment groups. Histology of explanted arteries demonstrated that the CP-seeded grafts had a thicker luminal cell layer, more intraparietal arterioles, and a higher expression of endothelial nitric oxide synthase (eNOS) compared with unseeded grafts. Moreover, the LPA stump adjacent to the seeded graft contained more elastin and less collagen than the unseeded control. Syngeneic CP engineering did not accomplish the primary goal of supporting the graft’s growth but was able to improve secondary outcomes, such as the luminal cellularization and intraparietal vascularization of the graft, and elastic remodeling of the recipient artery. The beneficial properties of neonatal CPs may be considered in future bioengineering applications aiming to reproduce the cellular composition of native arteries.

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Natural Biomaterials for Cardiac Tissue Engineering: A Highly Biocompatible Solution

Cited by 91 publications

References 288 publications

Current Strategies for the Regeneration of Skeletal Muscle Tissue

Current Strategies for the Regeneration of Skeletal Muscle Tissue

Diagnostic and Therapeutic Applications of Extracellular Vesicles in Interstitial Lung Diseases

Reconstruction of the Swine Pulmonary Artery Using a Graft Engineered With Syngeneic Cardiac Pericytes

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