Grikscheit Tracy C, Ochoa Erin R, Ramsanahie Anthony, Alsberg Eben, Mooney David, Whang Edward E, Vacanti Joseph P
Department of Surgery, Center for the Integration of Medicine and Innovation in Technology, Massachusetts General Hospital, 55 Fruit Street, Boston, MA 02114, USA.
Ann Surg. 2003 Jul;238(1):35-41. doi: 10.1097/01.SLA.0000074964.77367.4a.
Novel production and in vitro characterization of tissue engineered colon.
The colon provides important functions of short chain fatty acid production, sodium and water absorption, and storage. We report the first instance of tissue-engineered colon (TEC) production from autologous cells and its in vitro characterization.
Organoid units, mesenchymal cell cores surrounded by a polarized epithelia derived from full thickness sigmoid colon dissection from neonatal Lewis rats, adult rats, and tissue engineered colon itself, were implanted on a polymer scaffold into the omentum of syngeneic hosts. TEC was either anastomosed at 4 weeks or excised for Ussing chamber studies or histology, immunohistochemistry, and terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate-digoxigenin nick end labeling assay.
TEC was generated by 100% of all animals without regard to tissue source, the first instance of engineered intestine from adult cells or an engineered tissue. TEC architecture is identical to native with muscularis propria staining for actin, acetylcholinesterase detected in a linear distribution in the lamina propria, S100-positive cells, ganglion cells, and a terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate-digoxigenin nick end labeling assay similar to native colon. Ussing chamber data indicated in vitro function consistent with mature colonocytes, and a positive short circuit current response to theophylline indicating intact ion transfer. TEM showed normal microarchitecture. Colon architecture was maintained in anastomosis with gross visualization of fluid uptake.
TEC can be successfully produced with fidelity to native architecture and in vitro function from neonatal syngeneic tissue, adult tissue, and TEC itself.
新型组织工程化结肠的构建及其体外特性研究。
结肠具有产生短链脂肪酸、吸收钠和水以及储存等重要功能。我们报道了首例利用自体细胞构建组织工程化结肠(TEC)及其体外特性研究。
将类器官单元(由新生Lewis大鼠、成年大鼠全层乙状结肠解剖获得的极化上皮细胞围绕的间充质细胞核心以及组织工程化结肠自身构建而成)植入聚合物支架,再植入同基因宿主的大网膜。4周后对TEC进行吻合,或切除用于Ussing chamber实验、组织学、免疫组织化学以及末端脱氧核苷酸转移酶介导的脱氧尿苷三磷酸-地高辛标记法检测。
所有动物均成功构建出TEC,与组织来源无关,这是首例利用成年细胞构建的工程化肠道或工程化组织。TEC的结构与天然结肠相同,肌层肌动蛋白染色阳性,固有层呈线性分布的乙酰胆碱酯酶、S100阳性细胞、神经节细胞以及末端脱氧核苷酸转移酶介导的脱氧尿苷三磷酸-地高辛标记法检测结果均与天然结肠相似。Ussing chamber实验数据表明其体外功能与成熟结肠细胞一致,对茶碱的短路电流反应呈阳性,表明离子转运完整。透射电镜显示微观结构正常。吻合后的结肠结构得以维持,肉眼可见液体吸收。
利用新生同基因组织、成年组织以及TEC自身能够成功构建出结构和体外功能与天然结肠高度一致的TEC。