Choi R S, Riegler M, Pothoulakis C, Kim B S, Mooney D, Vacanti M, Vacanti J P
Department of Surgery, Children's Hospital, Boston, Massachusetts 02115, USA.
J Pediatr Surg. 1998 Jul;33(7):991-6; discussion 996-7. doi: 10.1016/s0022-3468(98)90520-6.
BACKGROUND/PURPOSE: Previous studies have shown that intestinal crypt cell transplantation using biodegradable scaffolds can generate stratified epithelium reminiscent of embryonic gut. The authors propose to tissue engineer small intestine on biodegradable scaffolds by transplanting intestinal epithelial organoid units, which maintain the epithelial mesenchymal cell-cell interaction necessary for epithelial survival, proliferation, and differentiation.
Intestinal epithelial organoid units were isolated from neonatal Lewis rats by enzyme digestion and differential sedimentation. Organoid units were seeded on to tubular scaffolds made of nonwoven polyglycolic acid (PGA) sprayed with 5% polylactic acid (PLA). Polymers either were coated (28 constructs) or noncoated (33 constructs) with collagen type I. A total of 61 organoid unit polymer constructs were implanted into 61 animals. Animals were killed and constructs harvested at 2, 6, 7, 8, 9, 10, 12, and 14 weeks.
Histological analysis showed formation of neomucosa characterized by columnar epithelium with goblet, and paneth cells were evident in 47 of the 61 constructs. The outer walls were composed of fibrovascular tissue, degradable polymer, extracellular matrix, and smooth muscle-like cells. Immunofluorescent microscopy showed apical staining of brush border enzymes, sucrase and lactase, and basolateral staining for laminin, indicating the establishment of cell polarity. Electrophysiology of Ussing-chambered neomucosa and adult ileal mucosa exhibited similar transepithelial resistance.
These results suggest that intestinal crypt cells heterotopically transplanted as epithelial organoid units on PGA-PLA tubular scaffolds can survive, reorganize, and regenerate complex composite tissue resembling small intestine demonstrating organ morphogenesis, cytodifferentiation, and phenotypic maturation.
背景/目的:先前的研究表明,使用可生物降解支架进行肠隐窝细胞移植可生成类似于胚胎肠道的分层上皮。作者提议通过移植肠上皮类器官单元在可生物降解支架上组织工程化小肠,该单元维持上皮存活、增殖和分化所需的上皮间充质细胞间相互作用。
通过酶消化和差速沉降从新生Lewis大鼠中分离肠上皮类器官单元。将类器官单元接种到由喷涂有5%聚乳酸(PLA)的非织造聚乙醇酸(PGA)制成的管状支架上。聚合物用I型胶原包被(28个构建体)或未包被(33个构建体)。总共61个类器官单元聚合物构建体被植入61只动物体内。在第2、6、7、8、9、10、12和14周处死动物并收获构建体。
组织学分析显示形成了以柱状上皮伴有杯状细胞为特征的新黏膜,并且在61个构建体中的47个中可见潘氏细胞。外壁由纤维血管组织、可降解聚合物、细胞外基质和平滑肌样细胞组成。免疫荧光显微镜显示刷状缘酶、蔗糖酶和乳糖酶的顶端染色以及层粘连蛋白的基底外侧染色,表明细胞极性的建立。Ussing小室新黏膜和成年回肠黏膜的电生理学表现出相似的跨上皮电阻。
这些结果表明,作为上皮类器官单元异位移植到PGA-PLA管状支架上的肠隐窝细胞能够存活、重组并再生类似于小肠的复杂复合组织,表现出器官形态发生、细胞分化和表型成熟。
