Heterogeneity of Scaffold Biomaterials in Tissue Engineering

Edgar, Lauren; McNamara, K.; Wong, Theresa; Tamburrini, Riccardo; Katari, Ravi; Orlando, Giuseppe

doi:10.3390/ma9050332

Cited by 74 publications

(49 citation statements)

References 150 publications

(191 reference statements)

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“…Decellularization is a process in which an acellular extracellular matrix (aECM) scaffold can be obtained by using chemical or physical means to remove cellular components of living tissue 20 . The product of decellularization is a three‐dimensional (3D) ultrastructure of ECM that may be used as a natural scaffold for application in tissue engineering and RM 21 . Ideally, the aECM scaffold retains both structural integrity and existing biochemical properties of the native tissue nanostructure.…”

Section: State‐of‐the‐art Regenerative Medicine Technologiesmentioning

confidence: 99%

Regenerative medicine, organ bioengineering and transplantation

Edgar

Porter

et al. 2020

British Journal of Surgery

112

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Background Organ transplantation is predicted to increase as life expectancy and the incidence of chronic diseases rises. Regenerative medicine‐inspired technologies challenge the efficacy of the current allograft transplantation model. Methods A literature review was conducted using the PubMed interface of MEDLINE from the National Library of Medicine. Results were examined for relevance to innovations of organ bioengineering to inform analysis of advances in regenerative medicine affecting organ transplantation. Data reports from the Scientific Registry of Transplant Recipient and Organ Procurement Transplantation Network from 2008 to 2019 of kidney, pancreas, liver, heart, lung and intestine transplants performed, and patients currently on waiting lists for respective organs, were reviewed to demonstrate the shortage and need for transplantable organs. Results Regenerative medicine technologies aim to repair and regenerate poorly functioning organs. One goal is to achieve an immunosuppression‐free state to improve quality of life, reduce complications and toxicities, and eliminate the cost of lifelong antirejection therapy. Innovative strategies include decellularization to fabricate acellular scaffolds that will be used as a template for organ manufacturing, three‐dimensional printing and interspecies blastocyst complementation. Induced pluripotent stem cells are an innovation in stem cell technology which mitigate both the ethical concerns associated with embryonic stem cells and the limitation of other progenitor cells, which lack pluripotency. Regenerative medicine technologies hold promise in a wide array of fields and applications, such as promoting regeneration of native cell lines, growth of new tissue or organs, modelling of disease states, and augmenting the viability of existing ex vivo transplanted organs. Conclusion The future of organ bioengineering relies on furthering understanding of organogenesis, in vivo regeneration, regenerative immunology and long‐term monitoring of implanted bioengineered organs.

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Section: State‐of‐the‐art Regenerative Medicine Technologiesmentioning

confidence: 99%

Regenerative medicine, organ bioengineering and transplantation

Edgar

Porter

et al. 2020

British Journal of Surgery

112

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“…An advantage of this system is that the native extracellular matrix is preserved. Yet this approach is also limited in the number of layers, that is, the size of the tissue graft that can be constructed fabrication include ceramics (e.g., for bone regeneration), synthetic polymers, or natural polymers, which have all been reviewed elsewhere (Bassas-Galia, Follonier, Pusnik, et al, 2017;Edgar et al, 2016;Moroni, Nandakumar, de Groot, van Blitterswijk, & Habibovic, 2015). Another method to obtain a 3D scaffold is tissue decellularization, a process in which all cells are removed from a donor tissue, after which (stem) cells are reimplanted into the remaining matrix.…”

Section: In Vitro Prevascularization Strategiesmentioning

confidence: 99%

Oxygen and nutrient delivery in tissue engineering: Approaches to graft vascularization

Rademakers

Horvath

Blitterswijk

et al. 2019

J Tissue Eng Regen Med

100

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The field of tissue engineering is making great strides in developing replacement tissue grafts for clinical use, marked by the rapid development of novel biomaterials, their improved integration with cells, better‐directed growth and differentiation of cells, and improved three‐dimensional tissue mass culturing. One major obstacle that remains, however, is the lack of graft vascularization, which in turn renders many grafts to fail upon clinical application. With that, graft vascularization has turned into one of the holy grails of tissue engineering, and for the majority of tissues, it will be imperative to achieve adequate vascularization if tissue graft implantation is to succeed. Many different approaches have been developed to induce or augment graft vascularization, both in vitro and in vivo. In this review, we highlight the importance of vascularization in tissue engineering and outline various approaches inspired by both biology and engineering to achieve and augment graft vascularization.

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“…Silk protein is commonly used in the textile industry; it is produced by silk worms and spiders. The fibrous protein in it native form consists of a component (sericin) which can elicit an inflammatory response [80]. However, this component can be removed by the process of alkali-or enzymebased "degumming".…”

Section: Silkmentioning

confidence: 99%

Polymeric Scaffolds for Pancreatic Tissue Engineering: A Review

2017

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In recent years, there has been an alarming increase in the incidence of diabetes, with one in every eleven individuals worldwide suffering from this debilitating disease. As the available treatment options fail to reduce disease progression, novel avenues such as the bioartificial pancreas are being given serious consideration. In the past decade, the research focus has shifted towards the field of tissue engineering, which helps to design biological substitutes for repair and replacement of non-functional or damaged organs. Scaffolds constitute an integral part of tissue engineering; they have been shown to mimic the native extracellular matrix, thereby supporting cell viability and proliferation. This review offers a novel compilation of the recent advances in polymeric scaffolds, which are used for pancreatic tissue engineering. Furthermore, in this article, the design strategies for bioartificial pancreatic constructs and their future applications in cell-based therapy are discussed.

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Heterogeneity of Scaffold Biomaterials in Tissue Engineering

Cited by 74 publications

References 150 publications

Regenerative medicine, organ bioengineering and transplantation

Regenerative medicine, organ bioengineering and transplantation

Oxygen and nutrient delivery in tissue engineering: Approaches to graft vascularization

Polymeric Scaffolds for Pancreatic Tissue Engineering: A Review

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