Levy Mark M, Ketchum Robert J, Tomaszewski John E, Naji Ali, Barker Clyde F, Brayman Kenneth L
Department of Surgery, Medical College of Virginia, Virginia Commonwealth University, Richmond, VA 23298, USA.
Transplantation. 2002 Mar 27;73(6):842-52. doi: 10.1097/00007890-200203270-00004.
Although an attractive alternative to daily insulin therapy, allogeneic pancreatic islet transplantation has yielded suboptimal results in clinical trials, in contrast to islet allotransplantation in animal models, which have demonstrated consistent success. The successful transplantation of isolated islets to the thymus, with a single concomitant dose of antilymphocyte serum, has been demonstrated in rodents, and more significantly, such intrathymic islet allografts have been shown to induce recipient tolerance toward subsequent extrathymic donor strain islet allografts. Intrathymic islet autotransplantation has been pursued, as a prelude to studies of allogeneic IT islet transplantation and tolerance induction, in canine, porcine, and non-human primate models, to assess the large animal thymus as a site capable of supporting a viable islet graft. However, little functional or histological evidence has established definitive survival of islets transplanted within the thymus of a phylogenetically advanced species, which may be requisite to tolerance induction. This study describes the successful intrathymic autotransplantation of isolated islets using a canine model.
Purpose-bred juvenile dogs, aged 4-6 months, underwent partial (n=4), or total pancreatectomy (n=11), and transplantation of autologous islets. The pancreas (or pancreatic limb) was distended with collagenase solution, and digested using a modification of the semiautomated system of Ricordi. Islets were purified by discontinuous gradient centrifugation, using Euroficoll (ficoll in Euro-Collin's kidney preservation solution). Partially pancreatectomized canines underwent IT transplantation of purified autologous islets (8000+/-4000 IEs), and were killed 8 weeks posttransplant. Totally pancreatectomized canines underwent transplantation of autologous islets to the liver (via portal vein embolization, n=5, IPO group) or the thymus (via direct IT injection, n=6, IT group), and were serially evaluated for a period of 8 weeks posttransplant to assess fasting blood glucose (FBG), serum insulin (SI) levels, and i.v. glucose tolerance (IVGTTs). K values (defined as the %-decrease/minute of the log(e) of blood glucose values) were calculated from IVGTT results.
After autotransplantation in this cohort of animals, five of five IPO, and three of six IT islet recipients, remained normoglycemic (mean FBG< or =250 mg%) immediately posttransplant, and all recipients exhibited significantly elevated SI levels compared to apancreatic controls (n=10, followed 72 hr postpancreatectomy). Normal k values (=-1.1) were observed in two of five IPO, and in one of six IT recipients, 8 weeks after transplantation, and thymic tissue insulin content was increased compared to non-islet-bearing thymi (93.7+/-48.6 ng/g tissue vs. 0.7+/-0.4 ng/g tissue). At 8 weeks posttransplantation thymi from both partially and totally pancreatectomized animals were resected and processed for histological examination. Microscopic analysis of islet-bearing thymi revealed positive staining for islet-specific hormones (insulin and glucagon) within all IT recipients., Identification of islets within thymi of hyperglycemic IT recipients was problematic as islet beta cells were highly degranulated as a result of the recipients glycemic state.
These results indicate that autologous islets, transplanted to the canine thymus, engraft, function, and survive for up to 8 weeks after islet autotransplantation to the canine thymus and establish the feasibility of intrathymic islet transplantation in a phylogenetically advanced animal model. The ability of islets to survive within the thymic environment for a period of at least 8 weeks after transplantation suggests that the successful induction of specific unresponsiveness secondary to intrathymic transplantation will not be impaired or limited by the inability of a viable islet mass to survive within the thymus for a sufficient period.
尽管同种异体胰岛移植是每日胰岛素治疗的一种有吸引力的替代方法,但与动物模型中的胰岛同种异体移植相比,临床试验结果并不理想,动物模型中的胰岛同种异体移植已证明一直很成功。在啮齿动物中已证明,将分离的胰岛与单剂量抗淋巴细胞血清同时移植到胸腺中是成功的,更重要的是,这种胸腺内胰岛同种异体移植已显示可诱导受体对随后的胸腺外供体菌株胰岛同种异体移植产生耐受性。在犬、猪和非人类灵长类动物模型中,已经进行了胸腺内胰岛自体移植,作为同种异体胸腺内胰岛移植和耐受性诱导研究的前奏,以评估大型动物的胸腺是否能够支持有活力的胰岛移植。然而,几乎没有功能或组织学证据能确定在系统发育较高级物种的胸腺内移植的胰岛能否存活,而这可能是诱导耐受性所必需的。本研究描述了使用犬模型成功进行胸腺内胰岛自体移植的过程。
选用4至6个月大的纯种幼龄犬,进行部分胰腺切除术(n = 4)或全胰腺切除术(n = 11),然后进行自体胰岛移植。用胶原酶溶液充盈胰腺(或胰腺肢体),并使用改良的Ricordi半自动系统进行消化。使用欧洲聚蔗糖(欧洲柯林氏肾保存溶液中的聚蔗糖)通过不连续梯度离心法纯化胰岛。部分胰腺切除的犬接受纯化的自体胰岛(8000±4000 IE)的胸腺内移植,并在移植后8周处死。全胰腺切除的犬将自体胰岛移植到肝脏(通过门静脉栓塞,n = 5,IPO组)或胸腺(通过直接胸腺内注射,n = 6,IT组),并在移植后8周内进行连续评估,以评估空腹血糖(FBG)、血清胰岛素(SI)水平和静脉葡萄糖耐量(IVGTT)。根据IVGTT结果计算K值(定义为血糖值对数(e)的每分钟下降百分比)。
在这群动物中进行自体移植后,IPO组的5只犬和IT组的6只犬中的3只在移植后立即保持血糖正常(平均FBG≤250 mg%),并且与胰腺切除对照犬(n = 10,胰腺切除后72小时随访)相比,所有受体的SI水平均显著升高。移植后8周,IPO组的5只犬中有2只、IT组的6只犬中有1只观察到正常的K值(=-1.1),并且与不含胰岛的胸腺相比,胸腺组织中的胰岛素含量增加(93.7±48.6 ng/g组织对0.7±0.4 ng/g组织)。移植后8周,切除部分和全胰腺切除动物的胸腺并进行组织学检查。对含有胰岛的胸腺进行显微镜分析,发现所有IT受体的胰岛特异性激素(胰岛素和胰高血糖素)呈阳性染色。在高血糖IT受体的胸腺中识别胰岛存在问题,因为由于受体的血糖状态,胰岛β细胞高度脱颗粒。
这些结果表明,自体胰岛移植到犬胸腺后能够植入、发挥功能并存活长达8周,并证明了在系统发育较高级的动物模型中进行胸腺内胰岛移植的可行性。胰岛在移植后至少8周内在胸腺环境中存活的能力表明,胸腺内移植继发的特异性无反应性的成功诱导不会因有活力的胰岛团无法在胸腺内存活足够长的时间而受到损害或限制。
