Screening for Type 1 Diabetes Risk in Newborns: The Freder1k Pilot Study in Saxony.

An increased risk for type 1 diabetes can be identified using genetic and immune markers. The Freder1k study introduces genetic testing for type 1 diabetes risk within the context of the newborn screening in order to identify newborns with a high risk to develop type 1 diabetes for follow-up testing of early stage type 1 diabetes and for primary prevention trials. Consent for research-based genetic testing of type 1 diabetes risk is obtained with newborn screening. Increased risk is assessed using three single nucleotide polymorphisms for HLA DRB1*03 (DR3), HLA DRB1*04 (DR4), HLA DQB1*0302 (DQ8) alleles, and defined as 1. an HLA DR3/DR4-DQ8 or DR4-DQ8/DR4-DQ8 genotype or 2. an HLA DR4-DQ8 haplotype and a first-degree family history of type 1 diabetes. Families of infants with increased risk are asked to participate in follow-up visits at infant age 6 months, 2 years, and 4 years for autoantibody testing and early diagnosis of type 1 diabetes. After 8 months, the screening rate has reached 181 per week, with 63% coverage of newborns within Freder1k-clinics and 24% of all registered births in Saxony. Of 4178 screened, 2.6% were identified to have an increased risk, and around 80% of eligible infants were recruited to follow-up. Psychological assessment of eligible families is ongoing with none of 31 families demonstrating signs of excessive burden associated with knowledge of type 1 diabetes risk. This pilot study has shown that it is feasible to perform genetic risk testing for childhood disease within the context of newborn screening programs.

Favorable outcome of experimental islet xenotransplantation without immunosuppression in a nonhuman primate model of diabetes.

Transplantation of pancreatic islets for treating type 1 diabetes is restricted to patients with critical metabolic lability resulting from the need for immunosuppression and the shortage of donor organs. To overcome these barriers, we developed a strategy to macroencapsulate islets from different sources that allow their survival and function without immunosuppression. Here we report successful and safe transplantation of porcine islets with a bioartificial pancreas device in diabetic primates without any immune suppression. This strategy should lead to pioneering clinical trials with xenotransplantation for treatment of diabetes and, thereby, represents a previously unidentified approach to efficient cell replacement for a broad spectrum of endocrine disorders and other organ dysfunctions.

Production of high-quality islets from goettingen minipigs: Choice of organ preservation solution, donor pool, and optimal cold ischemia time.

BACKGROUND: The transplantation of porcine islets into man might soon become reality for patients with type 1 diabetes mellitus. Therefore, porcine islets of high quality and quantity, and a scalable isolation process with strict quality control will be an unconditional prerequisite to enable the best possible transplantation graft. In this study, we provide a comparative study evaluating islet isolation outcome and in vitro survival based upon donor age, organ preservation solution (OPS), and cold ischemia time (CIT). METHODS: Goettingen minipigs of younger age (1 year) and retired breeder animals (3.5 years) were studied. Pancreata were harvested according to the standards of human organ retrieval including in situ cold perfusion with either Custodiol® -HTK or Belzer® UW solution. Pancreatic tissue was characterized by quantification of apoptotic cells. Islet isolations were performed according to a modified Ricordi method, and isolation outcome was assessed by determining islet particle numbers (IP), islet equivalents (IEQ), and isolation factor (IF). Isolated islets were cultured for 24 and 48 h for the assessment of in vitro survival. RESULTS: Islet viability was significantly higher in Custodiol® -HTK preserved pancreas organs compared to Belzer® UW. Furthermore, organs harvested from retired breeder preserved in Custodiol® -HTK resulted in stable islet isolation yields even after prolonged CIT and showed superior survival rates of islets in vitro compared to the Belzer® UW group. Younger porcine donor organs resulted generally in lower islet yield and survival rates. CONCLUSIONS: In summary, Custodiol® -HTK solution should be preferred over Belzer® UW solution for the preservation of pancreata from porcine origin. Custodiol® -HTK allows for maintaining islet viability and promotes reproducible isolation outcome and survival even after longer CIT. The usage of retired breeder animals over young animals for islet isolation is highly advisable to yield high quality and quantity.

Diabetes induction by total pancreatectomy in minipigs with simultaneous splenectomy: a feasible approach for advanced diabetes research.

BACKGROUND: Safe and reliable diabetes models are a key prerequisite for advanced preclinical studies on diabetes. Chemical induction is the standard model of diabetes in rodents and also widely used in large animal models of non-human primates and minipigs. However, uncertain efficacy, the potential of beta-cell regeneration, and relevant side effects are debatable aspects particularly in large animals. Therefore, we aimed to evaluate a surgical approach of total pancreatectomy combined with splenectomy for diabetes induction in an exploratory study in Goettingen minipigs. METHODS: Total pancreatectomy was performed in Goettingen minipigs (n = 4) under general anesthesia and endotracheal intubation. Prior to surgery, a central venous line was established for drug application and blood sampling. After median laparotomy, splenectomy was performed and the lobular pancreas was carefully dissected with particular attention to the duodenal vascular arcade. Close monitoring of blood glucose was initiated immediately after surgery by standard glucometer measurement or continuous glucose monitoring systems (CGMS). Exogenous insulin was given by multiple daily subcutaneous (s.c.) injections or via insulin pump systems (CSII). Complete endogenous insulin deficiency was confirmed by intravenous glucose tolerance test (ivGTT) and measurement of c-peptide. For establishing a suitable regimen for diabetes management, the animals were followed for 4-6 weeks. RESULTS: Following pancreatectomy and splenectomy, the animals showed a quick recovery from surgery and initial analgetic medication and volume substitution could be terminated within 24 h. A rapid increase in blood glucose was observed immediately following pancreatectomy necessitating insulin therapy. The induced exocrine insufficiency did not cause any clinical symptoms. Complete insulin deficiency could be confirmed in all animals by determination of negative c-peptide during glucose challenge. The two regimen of insulin treatment (multiple daily injections (MDI) and continuous subcutaneous insulin infusion (CSII)) were both feasible with respect to acceptable glycemic control whereas CSII was considerably advantageous in comfort and popularity for both animals and care takers. CONCLUSIONS: Surgical pancreatectomy in combination with splenectomy to facilitate access to the pancreas is a feasible model for efficient diabetes induction in minipigs. The procedure itself and postoperative animal care could be performed without complications in this exploratory study. Nevertheless, this approach requires well-equipped infrastructure, experienced and skilled surgeons and anesthesiologists and dedicated animal care takers. The impact of total pancreatectomy in combination with splenectomy on the digestive and immune system must be considered in the design and definition of end points of experimental diabetes and transplantation studies.