Islet cell transplantation

Islet cell transplantation
Intervention

Microscopic image of an islet of Langerhans (lighter area) surrounded by exocrine pancreas tissue (darker staining).
MeSH D016381

Islet transplantation is the transplantation of isolated islets from a donor pancreas into another person. It is an experimental treatment for type 1 diabetes mellitus. Once transplanted, the islets begin to produce insulin, actively regulating the level of glucose in the blood.

Islets are usually infused into the patient's liver.[1] If the cells are not from a genetically identical donor the patient's body will recognize them as foreign and the immune system will begin to attack them as with any transplant rejection. To prevent this immunosuppressant drugs are used. Recent studies have shown that islet transplantation has progressed to the point that 58% of the patients in one study were insulin independent one year after the operation.[2]

In the period from 1999 to 2004, 471 patients with type 1 diabetes have received islet transplants at 43 institutions worldwide.[3]

History

The concept of islet transplantation is not new.[4] Investigators as early as the English surgeon Charles Pybus (1882–1975) attempted to graft pancreatic tissue to cure diabetes. Most, however, credit the recent era of islet transplantation research to Paul Lacy's studies dating back more than three decades. In 1967, Lacy's group described a novel collagenase-based method (later modified by Dr. Camillo Ricordi, then working with Dr. Lacy) to isolate islets, paving the way for future in vitro and in vivo islet experiments.[5] Subsequent studies showed that transplanted islets could reverse diabetes in both rodents and non-human primates.[6][7] In a summary of the 1977 Workshop on Pancreatic Islet Cell Transplantation in Diabetes, Lacy commented on the feasibility of “islet cell transplantation as a therapeutic approach [for] the possible prevention of the complications of diabetes in man”.[8] Improvements in isolation techniques and immunosuppressive regimens ushered in the first human islet transplantation clinical trials in the mid-1980s. The first successful trial of human islet allotransplantation resulting in long-term reversal of diabetes was performed at the University of Pittsburgh in 1990.[9] Yet despite continued procedural improvements, only about 10% of islet recipients in the late 1990s achieved euglycemia (normal blood glucose). In 2000, Dr. James Shapiro and colleagues published a report describing seven consecutive patients who achieved euglycemia following islet transplantation using a steroid-free protocol and large numbers of donor islets, since referred to as the Edmonton protocol.[10] This protocol has been adapted by islet transplant centers around the world and has greatly increased islet transplant success.

Goals

The goal of islet transplantation is to infuse enough islets to control the blood glucose level removing the need for insulin injections. For an average-size person (70 kg), a typical transplant requires about one million islets, isolated from two donor pancreases. Because good control of blood glucose can slow or prevent the progression of complications associated with diabetes, such as nerve or eye damage, a successful transplant may reduce the risk of these complications. But a transplant recipient will need to take immunosuppressive drugs that stop the immune system from rejecting the transplanted islets.

Procedure

The process of islet transplantation (illustration by Giovanni Maki).

Researchers use a mixture of highly purified enzymes (Collagenase) to isolate islets from the pancreas of a deceased donor. Collagenase solution is injected into the pancreatic duct which runs through the head, body and tail of the pancreas. Delivered this way, the enzyme solution causes distension of the pancreas, which is subsequently cut into small chunks and transferred into so-called Ricordi's chamber, where digestion takes place until the islets are liberated and removed from the solution. Isolated islets are then separated from the exocrine tissue and debris in a process called purification.

During the transplant, a radiologist uses ultrasound and radiography to guide placement of a catheter through the upper abdomen and into the portal vein of the liver. The islets are then infused through the catheter into the liver. The patient will receive a local anesthetic. If a patient cannot tolerate local anesthesia, the surgeon may use general anesthesia and do the transplant through a small incision. Possible risks of the procedure include bleeding or blood clots.

It takes time for the islets to attach to new blood vessels and begin releasing insulin. The doctor will order many tests to check blood glucose levels after the transplant, and insulin may be needed until control is achieved.

Immunosuppression

The Edmonton protocol uses a combination of immunosuppressive drugs, including daclizumab (Zenapax), sirolimus (Rapamune) and tacrolimus (Prograf). Daclizumab is given intravenously right after the transplant and then discontinued. Sirolimus and tacrolimus, the two main drugs that keep the immune system from destroying the transplanted islets, must be taken for life.

Limitations

While significant progress has been made in the islet transplantation field,[11] many obstacles remain that currently preclude its widespread application. Two of the most important limitations are the currently inadequate means for preventing islet rejection, and the limited supply of islets for transplantation. Current immunosuppressive regimens are capable of preventing islet failure for months to years, but the agents used in these treatments are expensive and may increase the risk for specific malignancies and opportunistic infections. In addition, and somewhat ironically, the most commonly used agents (like calcineurin inhibitors and rapamycin) are also known to impair normal islet function and/or insulin action. Further, like all medications, the agents have other associated toxicities, with side effects such as oral ulcers, peripheral edema, anemia, weight loss, hypertension, hyperlipidemia, diarrhea and fatigue.[12] Perhaps of greatest concern to the patient and physician is the harmful effect of certain widely employed immunosuppressive agents on renal function. For the patient with diabetes, renal function is a crucial factor in determining long-term outcome, and calcineurin inhibitors (tacrolimus and ciclosporin) are significantly nephrotoxic. Thus, while some patients with a pancreas transplant tolerate the immunosuppressive agents well, and for such patients diabetic nephropathy can gradually improve, in other patients the net effect (decreased risk due to the improved blood glucose control, increased risk from the immunosuppressive agents) may worsen kidney function. Indeed, Ojo et al. have published an analysis indicating that among patients receiving other-than-kidney allografts, 7%–21% end up with renal failure as a result of the transplant and/or subsequent immunosuppression.[13]

Seen another way, patients with heart, liver, lung, or kidney failure have a dismal prognosis for survival, so the toxicity associated with immunosuppression is warranted (the benefits of graft survival outweigh the risks associated with the medications). But for the subset of patients with diabetes and preserved kidney function, even those with long-standing and difficult-to-control disease, the prognosis for survival is comparatively much better. In addition to the immunosuppressive toxicities, other risks are associated with the islet transplant procedure itself, including intra-abdominal hemorrhage following the transplant, and portal vein thrombosis. The fact that there is already a good alternative to islet transplantation (i.e. the modern intensive insulin regimen) forces us to regard any newer, riskier interventions with a critical eye.

Like all transplantation therapies, islet transplantation is also handicapped by the limited donor pool. The numbers are striking; at least 1 million Americans have type 1 diabetes mellitus, and only a few thousand donor pancreata are available each year. To circumvent this organ shortage problem, researchers continue to look for ways to "grow" islets—or at least cells capable of physiologically regulated insulin secretion—in vitro, but currently only islets from cadaveric donors can be used to restore euglycemia. Further exacerbating the problem (and unlike kidney, liver, and heart transplants, where only one donor is needed for each recipient) most islet transplant patients require islets from two or more donors to achieve euglycemia. Lastly, the current methods for islet isolation need improvement, since only about half of attempted isolations produce transplant-ready islets.

While islet transplantation research has made important progress and the success stories are encouraging, the long-term safety and efficacy of the procedure remain unclear. Other concerns relating to the field include questions about the impact of having insulin-producing foreign cells within the hepatic parenchyma, the long-term consequences of elevated portal pressures resulting from the islet infusion, and the fact that islet recipients can be sensitized against donor tissue types, making it more difficult to find a suitable donor should another life-saving transplant be required in the future. Also, very few islet transplant recipients have remained euglycemic without the use of any exogenous insulin beyond four years post-transplant. Thus, while most islet recipients achieve better glycemia control and suffer less serious hypoglycemia, islet transplantation continues to fall short of the definitive diabetes cure.

Future

Just as early studies showed islet transplantation's promise, research must now overcome the hurdles revealed by the recent islet transplant experience. New immunomodulatory agents offer the greatest hope of revolutionizing the field. New drug regimens capable of inducing tolerance to the transplanted islets would allow recipients to maintain their grafts without general immunosuppression and its associated toxicities. While many targets are currently under investigation, none are ready for clinical use.

Islet cells can also be encapsulated with a coating that protects them from the immune system, while still allowing the release of insulin. This is reported to be done in the "bioreactor" ßAir, a "proprietary implantable bioartificial pancreas"[14] developed by Israel-based medtech company Beta-O2 Technologies Ltd. The company was founded in 2004. The first implantation to a human patient was carried out in 2012 with a medical follow-up in Dresden's Technical University (Germany) for 10 month, and ßAir's Phase I Safety/Efficacy Study (clinical trial) started in 2014 at Uppsala University Hospital in Sweden.[15] Reportedly free from having to check blood glucose level and inject insulin, the ßAir-implanted patient will still have to enter with a needle from a separate device daily doses of oxygen into the implant to sustain the cells there.[16]

A multidisciplinary group of researchers led by Prof. Amy Shen, developed a novel cryopreservation method that helps to protect pancreatic islets from ice damage, and facilitates real-time assessments of cell viability. The novel technique employs a droplet microfluidic device to encapsulate pancreatic islets in hydrogel made of alginate, a natural polymer extracted from seaweed. These capsules have a unique microstructure: a porous network and considerable amount of non-freezable water. Non-freezable bound water does not form ice due to the strong association between water molecules and the hydrogel networks. Hydrogel capsules with large amounts of non-freezable bound water protect the cells from the ice damage and reduce the need for cryoprotectants—special substances that minimise or prevent freezing damage and can be toxic in high concentrations. The hydrogel capsule allows small molecules, e.g. nutrients and islet secretions, to pass through the membrane easily, but prevents direct contact between implanted cells and host cells and so prevent an attack on transplants by the autoimmune response.[17] The use of a real-time single-islet oxygen sensor - a fluorescent oxygen-sensitive dye in hydrogel capsules allows to use a simple and cheap yet reliable individual-islet-based quality control of viability for the entire islet processing procedure prior to transplantation. Fluorescence indicates whether cells are consuming oxygen and, therefore, are alive and healthy.

References

  1. Lakey J, Burridge P, Shapiro A (2003). "Technical aspects of islet preparation and transplantation". Transpl Int. 16 (9): 613–632. doi:10.1111/j.1432-2277.2003.tb00361.x. PMID 12928769.
  2. Close N, Hering B, Eggerman T (2005). "Results from the inaugural year of the Collaborative Islet Transplant Registry". Transplant Proc. 37 (2): 1305–1308. doi:10.1016/j.transproceed.2004.12.117. PMID 15848704.
  3. Shapiro A, Lakey J, Paty B, Senior P, Bigam D, Ryan E (2005). "Strategic opportunities in clinical islet transplantation". Transplantation. 79 (10): 1304–1307. doi:10.1097/01.TP.0000157300.53976.2A. PMID 15912095.
  4. Piemonti L, Pileggi A (2013). "25 Years of the Ricordi Automated Method for Islet Isolation". CellR4. 1 (1): 8–22.
  5. Lacy P, Kostianovsky M (1967). "Method for the isolation of intact islets of Langerhans from the rat pancreas". Diabetes. 16 (1): 35–39. doi:10.2337/diab.16.1.35. PMID 5333500.
  6. Kemp C, Knight M, Scharp D, Lacy P, Ballinger W (1973). "Transplantation of isolated pancreatic islets into the portal vein of diabetic rats". Nature. 244 (5416): 447. doi:10.1038/244447a0. PMID 4200461.
  7. Scharp D, Murphy J, Newton W, Ballinger W, Lacy P (1975). "Transplantation of islets of Langerhans in diabetic rhesus monkeys". Surgery. 77 (1): 100–105. PMID 122797.
  8. Lacy P (1978). "Workshop on Pancreatic Islet Cell Transplantation in Diabetes sponsored by the National Institute of Arthritis, Metabolism, and Digestive Diseases and held at the National Institutes of Health in Bethesda, Maryland, on November 29 and 30, 1977". Diabetes. 27 (4): 427–429. doi:10.2337/diab.27.4.427. PMID 416985.
  9. Tzakis A, Ricordi C, Alejandro R, Zeng Y, Fung J, Todo S, Demetris A, Mintz D, Starzl T (1990). "Pancreatic islet transplantation after upper abdominal exenteration and liver replacement". Lancet. 336 (8712): 402–405. doi:10.1016/0140-6736(90)91946-8. PMC 2972674Freely accessible. PMID 1974944.
  10. Shapiro A, Lakey J, Ryan E, Korbutt G, Toth E, Warnock G, Kneteman N, Rajotte R (2000). "Islet transplantation in seven patients with type 1 diabetes mellitus using a glucocorticoid-free immunosuppressive regimen". N Engl J Med. 343 (4): 230–238. doi:10.1056/NEJM200007273430401. PMID 10911004.
  11. Robertson R (2004). "Islet transplantation as a treatment for diabetes - a work in progress". N Engl J Med. 350 (7): 694–705. doi:10.1056/NEJMra032425. PMID 14960745.
  12. Hirshberg B, Rother K, Digon B, Lee J, Gaglia J, Hines K, Read E, Chang R, Wood B, Harlan D (2003). "Benefits and risks of solitary islet transplantation for type 1 diabetes using steroid-sparing immunosuppression: the National Institutes of Health experience". Diabetes Care. 26 (12): 3288–3295. doi:10.2337/diacare.26.12.3288. PMID 14633816. Full text
  13. Ojo A, Held P, Port F, Wolfe R, Leichtman A, Young E, Arndorfer J, Christensen L, Merion R (2003). "Chronic renal failure after transplantation of a nonrenal organ". N Engl J Med. 349 (10): 931–940. doi:10.1056/NEJMoa021744. PMID 12954741.
  14. "Beta-o2 Technologies Company - About". Beta-o2 Technologies Company. Beta-o2 Technologies Company. Retrieved Feb 20, 2015.
  15. "Clinical trials". Beta-O2 Technologies. Retrieved Feb 20, 2915. Check date values in: |access-date= (help)
  16. "Living with ßAir". Beta-o2 Technologies Ltd. Beta-o2 Technologies Ltd. Retrieved Feb 20, 2015.
  17. Wanyu Chen, Zhiquan Shu, Dayong Gao, Amy Q. Shen (2015). Sensing and Sensibility: Single-Islet-based Quality Control Assay of Cryopreserved Pancreatic Islets with Functionalized Hydrogel Microcapsules. Advanced Healthcare Materials, doi:10.1002/adhm.201500515


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