The robustness of the weak selection approximation for the evolution of altruism against strong selection.

The weak selection approximation of population genetics has made possible the analysis of social evolution under a considerable variety of biological scenarios. Despite its extensive usage, the accuracy of weak selection in predicting the emergence of altruism under limited dispersal when selection intensity increases remains unclear. Here, we derive the condition for the spread of an altruistic mutant in the infinite island model of dispersal under a Moran reproductive process and arbitrary strength of selection. The simplicity of the model allows us to compare weak and strong selection regimes analytically. Our results demonstrate that the weak selection approximation is robust to moderate increases in selection intensity and therefore provides a good approximation to understand the invasion of altruism in spatially structured population. In particular, we find that the weak selection approximation is excellent even if selection is very strong, when either migration is much stronger than selection or when patches are large. Importantly, we emphasize that the weak selection approximation provides the ideal condition for the invasion of altruism, and increasing selection intensity will impede the emergence of altruism. We discuss that this should also hold for more complicated life cycles and for culturally transmitted altruism. Using the weak selection approximation is therefore unlikely to miss out on any demographic scenario that lead to the evolution of altruism under limited dispersal.

Treatment of diabetes by xenogeneic islets without immunosuppression. Use of a vascularized bioartificial pancreas.

Tight glycemic control by intensive insulin therapy effectively delays the onset and slows the progression of diabetic complications but is associated with frequent dose adjustments and a high incidence of hypoglycemia. Successful pancreas transplantation corrects abnormal glucose metabolism but subjects patients to morbidity and mortality associated with chronic immunosuppression. A vascularized artificial pancreas device containing pancreatic islets is designed to provide glycemic control without immunosuppression. We report here that devices seeded with porcine islets implanted into pancreatectomized severely diabetic dogs maintained a marked improvement in glycemic control with reduced exogenous insulin requirements for up to 9 months with improved glucose tolerance and a reduction in glycosylated hemoglobin levels. No immunosuppression was used. Thus, use of a vascularized artificial pancreas containing xenogeneic porcine islets could be an alternative to intensive insulin therapy and pancreatic transplantation in treating diabetic patients before the development of severe diabetic complications.

Porcine islets for xenotransplantation.

Long-term function of isolated porcine islets was investigated in diabetic nude mice. Seven of eight mice that received transplants of porcine islets remained normoglycemic for 1 year with progressive weight gain. Circulating porcine C-peptide was detected throughout the study period. Intravenous glucose tolerance tests showed a rapid glucose clearance rate. Together with our recent finding that porcine islets contained within an immunoexclusion device achieved glycemic control in a totally pancreatectomized dog, these results clearly demonstrate that isolated porcine islets are capable of functioning for prolonged periods in xenogeneic hosts and are suitable for long-term use in an immunoexclusion device in a discordant host.

Novel delivery of pancreatic islet cells to treat insulin-dependent diabetes mellitus.

Immune protective devices containing pancreatic islets are designed to treat insulin-dependent diabetes mellitus by providing glycaemic control without immunosuppression. The immune protection is achieved by separating allogeneic or xenogeneic islets from the host by semipermeable membranes that allow only small molecules such as glucose, insulin and nutrients to pass through. Lymphocytes and immunoglobulins are excluded by the membrane and unable to cause rejection of the islets. Three types of immune protective devices, i.e. microcapsules, diffusion chambers and perfusion devices (vascularised artificial pancreas), have been studied. Microcapsules injected into the abdominal cavity in a large quantity achieved glycaemic control, but required a small amount of immunosuppression to prevent fibrosis around the the capsules. A clinical attempt to use microcapsulated human islets in a diabetic patient who has maintained functional kidney allografts has been reported. Intra-abdominal placement of diffusion chambers containing allogeneic islets achieved excellent glycaemic control without immunosuppression in diabetic dogs. However, their use was limited by the eventual breakage of tubular chambers. We have extensively used the vascularized artificial pancreas for treatment of experimental diabetes mellitus. Excellent biocompatibility of the device was evidenced by the extraordinary longevity of the patency of the device in healthy dogs. Long term control of severe diabetes mellitus was achieved in totally pancreatectomised dogs without immunosuppression by devices seeded with allogeneic (canine) and xenogeneic (porcine) islets. The vascularised artificial pancreas could be an excellent alternative to Diabetes Control and Complication Trial (DCCT)-type intensive insulin therapy or pancreatic transplantation by providing tight glycaemic control with minimal exogenous insulin therapy without immunosuppression.

Evaluation of anti-AIDS drugs in conventional mice implanted with a permeable membrane device containing human T cells infected with HIV.

We now report the confirmation of the work of Hollingshead et al. (1995) on development of a cell based hollow fiber (HF) system for evaluating potential anti-AIDS drugs in vivo using conventional mice rather than SCID mice. CD4 +, CEM-SS cells infected with HIV/1, strain RF, at a multiplicity of infection of 0.1 were placed into HFs. The fibers were implanted into the peritoneal cavity of outbred Swiss mice. Using this model, the antiviral activity of azidothymidine (AZT) at doses of approximately 150, 75 and 37.5 mg/kg/day was evaluated by administering AZT to the mice in drinking water. Upon fiber removal on day 6, AZT treatment was shown to significantly increase CEM cell viability over the untreated, virus control group and significantly reduced the levels of HIV p24 and HIV RT activity.

Early treatment of diabetes with porcine islets in a bioartificial pancreas.

Successful pancreas transplantation is an effective therapy for insulin-dependent diabetes mellitus (IDDM) but subjects patients to morbidity and mortality associated with chronic immunosuppression. Bioartificial pancreas devices containing pancreatic islets provide glycemic control without immunosuppression by physically separating the islet grafts from immune lymphocytes and immunoglobulins. Because immunosuppression is not required, the bioartificial pancreas may offer early treatment of IDDM prior to the development of debilitating diabetic complications. Use of xenogeneic islets (i.e., porcine islets) in the device also provides a solution to the limited availability of human donor organs. This report provides a brief summary of our experience with vascularized bioartificial pancreas devices containing xenogeneic porcine islets used for treatment of experimental diabetes in dogs and describes our plans for a clinical phase I/II trial of the vascularized bioartificial pancreas in patients with IDDM.

Comparison of analytical methods for quantitation of isolated porcine hepatocyte yields.

As cell-based therapies receive approval for clinical evaluation and use, the development of reliable methods to quantify cell number and control the dose of therapy delivered is becoming increasingly important. An example is the determination of the number and volume of primary porcine hepatocytes used in an extracorporeal treatment for patients with liver disease. Conventional cell counting using optical microscopy was compared against two alternate methods to quantify isolated porcine hepatocytes: (1) automated cell counting using a commercially available particle characterization instrument, and (2) quantitation by cell mass. Methods were compared based on accuracy, precision, specificity, linear range, and ruggedness. The automated method delivered substantially improved accuracy, precision, and ruggedness when compared to the conventional optical method. It also provided valuable information about the size distribution of cell preparations, which often contained clumps of cells, and showed that processing steps such as cryopreservation can alter the size characteristics of a cell population. The automated method was also faster, and was well suited to use in a commercial manufacturing process. The mass-based method was simple and inexpensive, but suffered from nonlinearity at low cell concentrations. Automated cell quantitation using a commercially available particle characterization instrument proved to be the preferred method for obtaining accurate and consistent porcine hepatocyte counts in a timely manner.

Overview of extracorporeal liver support systems and clinical results.

Patients with acute liver failure (ALF) continue to have an almost 50% mortality rate despite improvements associated with the use of orthotopic liver transplantation (OLT). Numerous ex vivo methods have been developed in attempts to improve patient survival. These methods can be divided into three groups: detoxification (e.g., dialysis, charcoal adsorption, plasma exchange), which only provides excretory function; ex vivo liver perfusion (e.g., whole organ or tissue perfusion), which provides some metabolic function; and bioartificial or cell-based systems, which combine elements of the first two methods. Clinical trials have shown minimal efficacy of the various detoxification methods in terms of ALF patient survival, while the relative success of OLT has shown the importance of providing metabolic as well as excretory functions. Attempts to provide those additional functions with ex vivo tissue perfusion have been fraught with complications such as clotting and acute tissue rejection, leading to the conceptual development of cell-based bioreactor systems. A number of these bioartificial systems have been clinically evaluated, and the preliminary patient survival rates have encouraged further work in this area.

Treatment of severe liver failure with a bioartificial liver.

Orthotopic liver transplantation (OLT) is the definitive therapy for severe liver failure. However, many patients die before an organ becomes available, mostly from cerebral edema. To provide temporary liver support, we developed a bioartificial liver (BAL) based on porcine hepatocytes and a charcoal column. Fifty-four consecutive BAL treatments were carried out in three groups of patients: Group I (n = 15) patients presented with FHF were listed for emergent OLT, Group II (n = 3) patients with primary non-function (PNF) of their liver grafts required urgent re-transplantation and Group III (n = 10) patients with acute exacerbation of chronic liver disease were not candidates for OLT. Patients were managed in a critical care unit receiving maximal standard support. Each BAL treatment was conducted for 6 hours. In Group I, all patients showed significant neurologic improvement, intracranial pressure (ICP) decreased and cerebral perfusion pressure (CPP) increased; other significant improvements, included lowered plasma ammonia and liver enzymes and increased glucose. One patient recovered spontaneously without OLT, all other patients were "bridged" to OLT, and recovered. Group II: PNF patients showed similar benefits. Group III: Chronic liver patients demonstrated transient beneficial effects after BAL treatment(s), however, most (n = 8) eventually succumbed to sepsis and multiple organ failure as they were not candidates for OLT; two patients, recovered, later were successfully transplanted and survived. Our clinical experience demonstrates that the BAL can serve as a bridge to OLT in patients with acute liver failure.

Improved assessment of isolated islet tissue volume using digital image analysis.

Accurate and consistent measurement of tissue volume is critical to performing many types of islet research; however, conventional visual determination of isolated islet yields through a microscope is heavily operator dependent. An improved method of islet volume determination using digital image analysis (DIA) was developed to remove operator bias and automate the islet counting process. A series of 140 porcine islet isolations were used to evaluate the DIA method in three separate stages. In Stage 1 (n = 29 isolations), the conventional and DIA methods were correlated with two other independent islet quantitation methods: insulin extraction, and DNA extraction. It was found that volumes determined by DIA correlated more closely with insulin content and DNA content than did conventionally determined volumes. In Stages 2 and 3 (n = 54 and 57 isolations, respectively), it was shown that an increase in the number of fields analyzed by DIA did not significantly improve the quality of the correlations. Inclusion of very small tissue (<50 microm in diameter), which is ignored in the conventional protocol affected yields by less than 10% and did not significantly improve the correlation with insulin or DNA content. Quantitation of isolated islet tissue volume using DIA has been shown to be rapid, consistent, and objective. In the laboratory, use of this method as the standard for islet volume measurement will allow more meaningful comparison of experimental results between centers. In the clinic, its use will allow more accurate dosing of transplanted tissue.

Functional recovery of porcine hepatocytes after hypothermic or cryogenic preservation for liver support systems.

The provision of an immediate supply of isolated porcine hepatocytes for artificial liver support requires preservation techniques that will allow maintenance of cell viability and detoxification functions. By means of a simple and cost-effective cryopreservation system, porcine hepatocytes can be available for both local and distant medical treatment facilities. Additionally, cryopreservation provides an adequate period for quality control testing to be completed prior to use of any specific cell lot. We are reporting a dual approach, namely the preservation of porcine hepatocytes, at 4 degrees C and at -196 degrees C in liquid nitrogen (LN2). Using a combination of cryoprotectant agents with Chee's modified Eagle's culture media (CEM), collagenase isolated hepatocytes stored at 4 degrees C for 24 h maintained 80% of the initial diazepam metabolism measured in freshly isolated cells and nearly 100% of initial function was preserved in hepatocytes stored up to 6 mo at -196 degrees C. University of Wisconsin solution (UW) was also tested and while adequate for 4 degrees C storage, it certainly did not match the performance of the CEM formulations for preservation of metabolic function of cells stored in liquid nitrogen. Based on our results of viability and detoxification function the combination of CEM with DMSO, polyethylene glycol and serum provided optimal protection for LN2 frozen cells. Other findings in these studies underlined the importance of the gradual introduction of DMSO in the prefreezing process, the period of osmotic equilibration, and the rapid postthaw withdrawal of this agent to minimize cytotoxic effects at these critical stages. Our freezing methodology provides the foundation for further technological developments in the cryopreservation of the large numbers of cells (billions) that are necessary for extracorporeal liver assist devices.

The isolation and function of porcine islets from market weight pigs.

The efficacy of clinical islet transplantation has been demonstrated with autografts, and although islet allografts have established insulin independence in a small number of IDDM patients, the treatment is confounded by the necessity of immunosuppression. the lack of donor tissue, and recurring islet immunogenicity. These limitations underscore a need to develop therapies to serve the large population of diabetic patients. Porcine islet xenotransplantation, together with a successful immune intervention strategy, may provide the necessary clinical alternative. However, a major obstacle in evaluating this approach has been the difficulty of obtaining adequate volumes of functional islet tissue from pigs. Donors of market weight are preferable to retired breeders due to their abundance, lower animal and husbandry costs. and are more suitable to meet regulatory guidelines for donor tissue for xenotransplantation. We describe a simple isolation procedure that following purification yields a mean of 350,000 IE, corresponding to 179 units of insulin and 1.8 mg of DNA with an islet purity and viability in excess of 85% (n = 317 isolations). In both short- and long-term cell cultures, porcine islets demonstrated glucose-responsive insulin secretion. However, this secretion is density dependent, which may have significant consequences in the development of immunoisolation technologies to support porcine islet xenotransplantation. Following implantation into diabetic nude mice, porcine islets remained functional in excess of 1 year. Implantation of a bioartificial pancreas containing porcine islets into pancreatectomized dogs provided significant clinical benefit with an improved diabetic condition. Finally, secretagogue-induced insulin release was demonstrated in vitro from these devices after removal from immunocompetent recipients. Immunohistochemical staining identified well-granulated islets following long-term implantation in both the rodent and canine models. This study demonstrates the ability to isolate porcine islets in clinically relevant numbers from market animals, which survive and remain functional for prolonged periods of time in an immune-deficient or immunoprotected environment.

Transplantation of hepatocytes for prevention of intracranial hypertension in pigs with ischemic liver failure.

Intracranial hypertension leading to brain stem herniation is a major cause of death in fulminant hepatic failure (FHF). Mannitol, barbiturates, and hyperventilation have been used to treat brain swelling, but most patients are either refractory to medical management or cannot be treated because of concurrent medical problems or side effects. In this study, we examined whether allogeneic hepatocellular transplantation may prevent development of intracranial hypertension in pigs with experimentally induced liver failure. Of the two preparations tested--total hepatectomy (n = 47), and liver devascularization (n = 16)--only pigs with liver ischemia developed brain edema provided, however, that animals were maintained normothermic throughout the postoperative period. This model was then used in transplantation studies, in which six pigs received intrasplenic injection of allogeneic hepatocytes (2.5 x 10(9) cells/pig) and 3 days later acute liver failure was induced. In both models (anhepatic state, liver devascularization), pigs allowed to become hypothermic had significantly longer survival compared to those maintained normothermic. Normothermic pigs with liver ischemia had, at all time points studied, ICP greater than 20 mmHg. Pigs that received hepatocellular transplants had ICP below 15 mmHg until death; at the same time, cerebral perfusion pressure (CPP) in transplanted pigs was consistently higher than in controls (45 +/- 11 mmHg vs. 16 +/- 18 mmHg; p < 0.05). Spleens of transplanted pigs contained clusters of viable hepatocytes (hematoxylin-eosin, CAM 5.2). It was concluded that removal of the liver does not result in intracranial hypertension; hypothermia prolongs survival time in both anhepatic pigs and pigs with liver devascularization, and intrasplenic transplantation of allogeneic hepatocytes prevents development of intracranial hypertension in pigs with acute ischemic liver failure.

Primary cultures of rat hepatocytes in hollow fiber chambers.

Hepatocyte culture may represent an alternative to the use of animals to study drug detoxification by the liver. An ideal in vitro system should closely mimic the in vivo environment by providing continuous media perfusion and oxygenation, and should facilitate sampling of cells and culture media. To meet these criteria, a hollow fiber bioreactor seeded with isolated rat hepatocytes was developed and tested by measuring the formation of three products of the oxidative metabolism of diazepam and the glucuronidation of phenolsulfonphthalein (PSP). To compare the performance of conventional monolayer culture to that of the bioreactor system, diazepam metabolism was studied for 45 days in both systems. The oxygen dependency of diazepam metabolism was evaluated by perfusing the bioreactor in an oxygen-rich atmosphere (30%). Total diazepam metabolism was twofold higher in the O2-rich perfused hollow fiber cultures than in the cultures perfused under normal conditions, reflecting an increase in temazepam and oxazepam production. Diazepam detoxification activity was significantly enhanced by oxygen (P < or = 0.001) over the life of the perfused cultures. PSP metabolism was similar in all three culture systems. By Day 10, diazepam metabolism in the oxygenated bioreactor system was 44% of the in vivo activity of rat hepatocytes. This activity dropped to 30% by Day 25 of culture. These results justify the use of perfused culture systems for in vitro detoxification studies as an alternative to animal use and emphasize the capacity of a culture device perfused under O2-enriched conditions to maintain long-term P450 activity of rat hepatocytes.

Oxygen delivery to and use by primary porcine hepatocytes in the HepatAssist 2000 system for extracorporeal treatment of patients in end-stage liver failure.

A system for the extracorporeal treatment of end-stage liver failure patients has been developed and is now in clinical studies. This HepatAssist 2000 system consists of perfusing the plasma of the patient through a hollow-fiber bioreactor containing primary porcine hepatocytes. The goal of the system is to assist the patient while the liver regenerates or a suitable liver is found for transplantation. During the development of this system in the laboratory, an experimental protocol has been developed to simulate patient treatments. The protocol substitutes donor calf serum for patient plasma, but is otherwise similar to clinical conditions. The protocol uses a blood gas analyzer to monitor dissolved oxygen and carbon dioxide tensions at the entrance to and exit from the bioreactor. Samples are withdrawn using a standard 1-ml syringe and analyzed off-line immediately. The blood gas measurements have been used to verify that the oxygenator, placed immediately prior to the bioreactor in the plasma circuit, is properly sized to allow complete equilibration with feed gas and to maintain a physiologic level of carbon dioxide. The measurements were also used to calculate overall bioreactor oxygen consumption rates under various conditions. In one set of studies, composition of the feed gas to the oxygenator was varied from 20% to 70% oxygen, while maintaining 5% carbon dioxide and balance nitrogen. Rates of oxygen consumption and liver cell function (metabolism of diazepam) were unchanged, and no signs of oxygen toxicity were observed. In another set of studies, oxygen consumption increased linearly with number of hepatocytes used in the clinically used range of 5-10 billion hepatocytes, whether all hepatocytes were placed in one device or split between two devices operating in series or in parallel. In a third set of studies, oxygen consumption was a weak function of flowrate through the bioreactor but was highest at the clinically used recirculation rate of 400 ml/min. These data indicate that blood gas meters--readily available in hospital clinical laboratories--can be used to assist in the design of extracorporeal cell therapies, to monitor the effectiveness of system components, and to assess the effects of system modifications. These same measurements can be made noninvasively in the clinical setting to monitor oxygen consumption rates during patient treatment.

Extracorporeal enzymatic removal of low density lipoproteins in rabbits: efficacy and safety.

An extracorporeal circuit incorporating a plasma separator reactor (PSR) was designed to modify low density lipoproteins (LDL). The PSR was tested in vivo with hypercholesterolemic New Zealand White rabbits. The bioreactor enzymatically converts LDL to a form that can be removed by the body at an enhanced rate. The physiological response of hypercholesterolemic New Zealand White rabbits to 90 minute extracorporeal treatments was monitored. The total plasma cholesterol concentration in the treated rabbits fell sharply (up to 40% decrease) during and following the treatment. Results of safety tests indicate no significant enzyme leaching from the device, no disruption or damage to erythrocytes, no increase in white blood cell count and no liver damage as indicated by five enzyme assays. All safety measurements suggest that the treatment is safe.

Evidence of absence of porcine endogenous retrovirus (PERV) infection in patients treated with a bioartificial liver support system.

Porcine endogenous retrovirus (PERV) genomes are present in all pig cells. In this retrospective study, we assessed PERV infectivity in 28 patients treated with an extracorporeal bioartificial liver (HepatAssist system) that includes a membrane device containing porcine hepatocytes. All patients tested negative for PERV using polymerase chain reaction analysis of peripheral blood mononuclear cells (PBMC) collected up to 5 years after treatment. In vitro results showed that the membrane decreased the risk of PERV transmission by a factor of 105, and porcine hepatocytes did not produce infectious PERV in co-cultures with human cell line 293. Our results do not support the presence of PERV infection in patients treated with this porcine hepatocyte-based bioartificial liver.