DOI QR코드

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Experimental In-Vivo Models Used in Fat Grafting Research for Volume Augmentation in Soft Tissue Reconstruction

  • Lujan-Hernandez, Jorge (Division of Plastic Surgery, University of Massachusetts Medical School) ;
  • Appasani, Raghu (Division of Plastic Surgery, University of Massachusetts Medical School) ;
  • Sullivan, Kylee (Division of Plastic Surgery, University of Massachusetts Medical School) ;
  • Siegel-Reamer, Leah (Division of Plastic Surgery, University of Massachusetts Medical School) ;
  • Lalikos, Janice F. (Division of Plastic Surgery, University of Massachusetts Medical School)
  • 투고 : 2017.03.10
  • 심사 : 2017.04.26
  • 발행 : 2017.09.15

초록

As the popularity of fat grafting research increases, animal models are being used as the source of pre-clinical experimental information for discovery and to enhance techniques. To date, animal models used in this research have not been compared to provide a standardized model. We analyzed publications from 1968-2015 to compare published accounts of animal models in fat grafting research. Data collected included: species used, graft characteristics (donor tissue, recipient area, amount injected, injection technique), time of sacrifice and quantification methods. Mice were most commonly used (56% of studies), with the "athymic nude" strain utilized most frequently (44%). Autologous fat was the most common source of grafted tissue (52%). Subcutaneous dorsum was the most common recipient site (51%). On average, $0.80{\pm}0.60mL$ of fat was grafted. A single bolus technique was used in 57% of studies. Fat volume assessment was typically completed at the end of the study, occurring at less than 1 week to one year. Graft volume was quantified by weight (63%), usually in conjunction with another analysis. The results demonstrate the current heterogeneity of animal models in this research. We propose that the research community reach a consensus to allow better comparison of techniques and results. One example is the model used in our laboratory and others; this model is described in detail. Eventually, larger animal models may better translate to the human condition but, given increased financial costs and animal facility capability, should be explored when data obtained from small animal studies is exhausted or inconclusive.

키워드

참고문헌

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피인용 문헌

  1. Short-term post-implantation dynamics of in vitro engineered human microvascularized adipose tissues vol.13, pp.6, 2017, https://doi.org/10.1088/1748-605x/aadff7
  2. Increasing Fat Graft Retention in Irradiated Tissue after Preconditioning with External Volume Expansion : vol.145, pp.1, 2020, https://doi.org/10.1097/prs.0000000000006372