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设计可 3D 打印的生物可吸收组织工程室以促进脂肪组织生长的原理。

Rationale for the design of 3D-printable bioresorbable tissue-engineering chambers to promote the growth of adipose tissue.

机构信息

Hôpital Salengro -Service de Chirurgie Plastique, CHU Lille, 59000, Lille, France.

CHU Lille, IRCL, CNRS, Inserm UMR9020-UMR-S 1277 Canther, Univ. Lille, 59000, Lille, France.

出版信息

Sci Rep. 2020 Jul 16;10(1):11779. doi: 10.1038/s41598-020-68776-8.

DOI:10.1038/s41598-020-68776-8
PMID:32678237
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7367309/
Abstract

Tissue engineering chambers (TECs) bring great hope in regenerative medicine as they allow the growth of adipose tissue for soft tissue reconstruction. To date, a wide range of TEC prototypes are available with different conceptions and volumes. Here, we addressed the influence of TEC design on fat flap growth in vivo as well as the possibility of using bioresorbable polymers for optimum TEC conception. In rats, adipose tissue growth is quicker under perforated TEC printed in polylactic acid than non-perforated ones (growth difference 3 to 5 times greater within 90 days). Histological analysis reveals the presence of viable adipocytes under a moderate (less than 15% of the flap volume) fibrous capsule infiltrated with CD68 inflammatory cells. CD31-positive vascular cells are more abundant at the peripheral zone than in the central part of the fat flap. Cells in the TEC exhibit a specific metabolic profile of functional adipocytes identified by H-NMR. Regardless of the percentage of TEC porosity, the presence of a flat base allowed the growth of a larger fat volume (p < 0.05) as evidenced by MRI images. In pigs, bioresorbable TEC in poly[1,4-dioxane-2,5-dione] (polyglycolic acid) PURASORB PGS allows fat flap growth up to 75 000 mm at day 90, (corresponding to more than a 140% volume increase) while at the same time the TEC is largely resorbed. No systemic inflammatory response was observed. Histologically, the expansion of adipose tissue resulted mainly from an increase in the number of adipocytes rather than cell hypertrophy. Adipose tissue is surrounded by perfused blood vessels and encased in a thin fibrous connective tissue containing patches of CD163 inflammatory cells. Our large preclinical evaluation defined the appropriate design for 3D-printable bioresorbable TECs and thus opens perspectives for further clinical applications.

摘要

组织工程室(TEC)在再生医学中带来了很大的希望,因为它们允许脂肪组织生长,用于软组织重建。迄今为止,已经有多种 TEC 原型,具有不同的概念和体积。在这里,我们研究了 TEC 设计对体内脂肪皮瓣生长的影响,以及使用生物可吸收聚合物来优化 TEC 设计的可能性。在大鼠中,聚乳酸(PLA)打印的多孔 TEC 中的脂肪组织生长速度比非多孔 TEC 快(90 天内生长差异高达 3 到 5 倍)。组织学分析显示,在纤维囊(体积的 15%以下)适度浸润的情况下存在有活力的脂肪细胞,该纤维囊浸润有 CD68 炎性细胞。CD31 阳性血管细胞在脂肪皮瓣的外周区比中央区更丰富。TEC 中的细胞表现出通过 H-NMR 鉴定的功能性脂肪细胞的特定代谢谱。无论 TEC 孔隙率的百分比如何,平坦基底的存在都允许更大的脂肪体积生长(p<0.05),这可以通过 MRI 图像证明。在猪中,聚[1,4-二恶烷-2,5-二酮](PGA)聚乙二醇酸 PURASORB PGS 生物可吸收 TEC 允许脂肪皮瓣在第 90 天生长到 75000mm(体积增加超过 140%),同时 TEC 大量吸收。未观察到全身炎症反应。组织学上,脂肪组织的扩张主要是由于脂肪细胞数量的增加,而不是细胞肥大。脂肪组织被充满血液的血管包围,并被包含 CD163 炎性细胞斑块的薄纤维结缔组织包裹。我们的大型临床前评估定义了 3D 可打印生物可吸收 TEC 的适当设计,从而为进一步的临床应用开辟了前景。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0ea4/7367309/949d3bafb362/41598_2020_68776_Fig8_HTML.jpg
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Hypoxic preconditioning of myoblasts implanted in a tissue engineering chamber significantly increases local angiogenesis via upregulation of myoblast vascular endothelial growth factor-A expression and downregulation of miRNA-1, miRNA-206 and angiopoietin-1.将成肌细胞植入组织工程室进行低氧预处理,可通过上调成肌细胞血管内皮生长因子 A 的表达和下调 miRNA-1、miRNA-206 和血管生成素 1 的表达,显著增加局部血管生成。
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