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@article{1386073, author = {Streit, Libor and Jaroš, Josef and Sedláková, Veronika and Sedláčková, Miroslava and Dražan, Luboš and Svoboda, Michal and Pospíšil, Jakub and Výška, Tomáš and Veselý, Jiří and Hampl, Aleš}, article_location = {PHILADELPHIA}, article_number = {3}, doi = {http://dx.doi.org/10.1097/PRS.0000000000003124}, keywords = {reconstructive surgery}, language = {eng}, issn = {0032-1052}, journal = {PLASTIC AND RECONSTRUCTIVE SURGERY}, title = {A Comprehensive In Vitro Comparison of Preparation Techniques for Fat Grafting}, volume = {139}, year = {2017} }
TY - JOUR ID - 1386073 AU - Streit, Libor - Jaroš, Josef - Sedláková, Veronika - Sedláčková, Miroslava - Dražan, Luboš - Svoboda, Michal - Pospíšil, Jakub - Výška, Tomáš - Veselý, Jiří - Hampl, Aleš PY - 2017 TI - A Comprehensive In Vitro Comparison of Preparation Techniques for Fat Grafting JF - PLASTIC AND RECONSTRUCTIVE SURGERY VL - 139 IS - 3 SP - "670E"-"682E" EP - "670E"-"682E" PB - LIPPINCOTT WILLIAMS & WILKINS SN - 00321052 KW - reconstructive surgery N2 - Background: Lipomodeling is a technique that uses the patient's own fat for tissue regeneration and augmentation. The extent of regenerative effect is reported to be determined by the numbers of adipose-derived stem cells and the viability of cells in processed adipose tissue which, together with other factors, influence the degree of graft retention. This study addresses whether differences exist in properties of fat graft obtained by three commonly used techniques. Methods: Adipose tissue harvested from the hypogastric regions of 14 patients was processed by decantation, centrifugation, and membrane-based tissue filtration. The morphology of each preparation was assessed by electron microscopy and overall cell viability was assessed by live/dead assay. The number of adiposederived stem cells was determined and their stem cell character was assessed by the presence of cell surface molecules (i.e., CD105, CD90, CD31, and CD45) and by their capacity to differentiate into adipogenic and osteogenic lineages. Results: First, morphologies of processed fat samples obtained by individual procedures differed, but no preparation caused obvious damage to cellular or acellular components. Second, although the highest numbers of adiposederived stem cells were contained in the upper fraction of centrifuged lipoaspirates, the difference between preparations was marginal. Third, the maximal concentration of adipose fraction (removal of watery component) of lipoaspirate was achieved by membrane-based tissue filtration. Finally, no significant differences in overall viability were detected. Conclusions: Properties of processed lipoaspirate were influenced by the preparation procedure. However, the differences were not dramatic; both centrifugation and membrane-based filtration are methods of choice whose selection depends on other criteria (e.g., practicality) for individual surgical settings. ER -
STREIT, Libor, Josef JAROŠ, Veronika SEDLÁKOVÁ, Miroslava SEDLÁČKOVÁ, Luboš DRAŽAN, Michal SVOBODA, Jakub POSPÍŠIL, Tomáš VÝŠKA, Jiří VESELÝ and Aleš HAMPL. A Comprehensive In Vitro Comparison of Preparation Techniques for Fat Grafting. \textit{PLASTIC AND RECONSTRUCTIVE SURGERY}. PHILADELPHIA: LIPPINCOTT WILLIAMS \&{} WILKINS, 2017, vol.~139, No~3, p.~''670E''-''682E'', 13 pp. ISSN~0032-1052. Available from: https://dx.doi.org/10.1097/PRS.0000000000003124.
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