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Journal of Education, Health and Sport

A state of the “heart”: application of bioengineered materials for cardiac surgery
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A state of the “heart”: application of bioengineered materials for cardiac surgery

Authors

  • A. A. Sokol Ukrainian Children’s Cardiac Centre
  • D. A. Grekov Ukrainian Children’s Cardiac Centre
  • G. I. Yemets Ukrainian Children’s Cardiac Centre
  • A. Y. Galkin National Technical University of Ukraine "Igor Sikorsky Kyiv Institute"
  • N. V. Shchotkina Ukrainian Children’s Cardiac Centre
  • A. A. Dovghaliuk Ukrainian Children’s Cardiac Centre
  • N. M. Rudenko Ukrainian Children’s Cardiac Centre
  • O. V. Telehuzova Ukrainian Children’s Cardiac Centre
  • I. M. Yemets Ukrainian Children’s Cardiac Centre

DOI:

https://doi.org/10.12775/JEHS.2020.10.09.113

Keywords

cardiovascular disease, cardiovascular biomaterials, decellularization, xenogenous valves

Abstract

Introduction. Cardiovascular diseases have become the leading mortality cause, requiring a novel technologies and techniques for the treatment. Cardiovascular biomaterials play a vital role as the potentially eligible alternative modality for an operation, covering the gap between facilities and patients in need of medical devices and procedures.

Purpose. The aim of this essay is to explore and analyze the currently used biomaterials for cardiac surgery as tools to repair or replace the damaged tissues. This study seeks to obtain data which will help to address research gaps and to stimuli the manufacturing process.

Description of the state of knowledge. We conduct the systematic literature review, based on the information found in PubMed, Research Gate and Google Scholar databases using the eligible parameters. Obtained data in form of descriptive information were analyzed.

Summary. This study has identified a wide area of cardiovascular biomaterials use in the modern clinical and scientific practice. The most obvious finding to emerge from this study is that decellularization of xenogenous heart valves is a crucial feature to obtain the optimal matrix for a tissue-engineered valve substitute. This information can be used to develop targetted interventions aimed at cardiac surgery.

References

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Collatusso, Claudinei & Roderjan, João Gabriel & Vieira, Eduardo & Myague, Nelson & Noronha, Lúcia & Costa, Francisco. (2011). Decellularization as an anticalcification method in stentless bovine pericardium valve prosthesis: A study in sheep. Revista brasileira de cirurgia cardiovascular : órgão oficial da Sociedade Brasileira de Cirurgia Cardiovascular. 26. 419-26. 10.5935/1678-9741.20110017.

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Published

2020-09-30

How to Cite

1.
SOKOL, A. A., GREKOV, D. A., YEMETS, G. I., GALKIN, A. Y., SHCHOTKINA, N. V., DOVGHALIUK, A. A., RUDENKO, N. M., TELEHUZOVA, O. V. and YEMETS, I. M. A state of the “heart”: application of bioengineered materials for cardiac surgery. Journal of Education, Health and Sport. Online. 30 September 2020. Vol. 10, no. 9, pp. 927-936. [Accessed 3 July 2025]. DOI 10.12775/JEHS.2020.10.09.113.
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Vol. 10 No. 9 (2020)

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Review Articles

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