A Prospective Comparison of Discontinuous Euroficoll and Eurodextran Gradients for Islet Purification

Density gradient separation of islets from exocrine tissue is usually performed with Ficoll. However, this reagent adds significantly to the cost of the isolation. The aim of this study was to evaluate the performance of Dextran as a potential low-cost substitute for Ficoll and to evaluate the effects of cold storage of the pancreatic digest prior to purification. Pancreases were procured from mongrel dogs, loaded with collagenase and mechanically dissociated. Washed pancreatic digest was collected and divided into two fractions that were purified using discontinuous gradients on the Cobe 2991 processor using identically prepared EuroFicoll (EF) or EuroDextran (ED) gradients. Alternate groups were suspended in EC and stored on ice, while the other fraction were resuspended in the 1.108-g/mL gradient layer (either EF or ED) and loaded into the COBE. This tissue layer was overlaid with layers of densities 1.096 and 1.037 g/mL and a HBSS cap, and centrifuged for 5 min at 800 × g. Purified islets were collected from the interface between the 1.037 and 1.096 layers and islet recovery, purity, and function were assessed. From a series of eight isolations, 72.9 ± 8.2% (mean ± SEM) of the islets were recovered from the EF purified gradients compared with 62.6 ± 8.3% from ED gradients ( p = NS, paired t-test). Gradients of ED that were run following hypothermic storage of the digest in cold EC solution (stored ED) had reduced islet recovery when compared with islet recovery from gradients prepared in EF(stored EF) (51.6 ± 9.6% for ED stored vs. 72.9 ± 11.9 for EF stored, p < 0.05). Islet recovery from EF gradients was equivalent between the stored and nonstored groups. The purity of preparations from the stored ED gradients was also reduced (71.3 ± 4.3%) when compared with islets that were immediately purified after dissociation (82.5 ± 4.8%, p < 0.05). Static glucose stimulation assay showed equivalence between the islets from ED and EF gradients. The stimulation index (SI) was 9.3 ± 0.9 for EF islets compared with 7.9 ± 1.4 for ED islets for digest purified immediately. However, if the digest was hypothermically stored in EC solution, a decrease in functional viability was observed in both the EF and the ED groups (7.7 ± 1.4 and 5.9 ± 0.8, respectively). Out of five alloxan-induced diabetic nude mice transplanted under the kidney capsule with 2000 islets isolated from the nonstored groups, three remained euglycemic >50 days posttrans-plant with either EF or ED islets. These experiments demonstrate effective recovery of equivalent numbers of canine islets using discontinuous gradients of ED or EF immediately following enzymatic digestion. However, following storage of the digest in cold EC solution results in a reduction in both islet recovery and function when gradients of ED are utilized. © 1998 Elsevier Science Inc.

Evaluation of a Purified Enzyme Blend for the Recovery and Function of Canine Pancreatic Islets

Recently developed technologies enabling the production of a reproducible, purified enzyme blend for optimal human pancreatic islet isolation has renewed interest in clinical islet transplantation. The canine model has been an ideal preclinical model for the development of islet transplantation protocols. As seen in other species, the application of crude collagenase for isolating canine islets resulted in highly variable islet yields, extensive islet fragmentation, and variable islet functionality. We compared the function of commercially available crude collagenases with that of Liberase™-CI purified enzyme blend for canine islet isolation. We also compared two manufacturing runs of Liberase-CI enzyme (lots 1 and 2) to demonstrate reproducibility of islet recovery and function. We report on the improved recovery and function of islets isolated using Liberase-CI enzyme. No difference in dog age, mean body weight, or pancreas weight were observed between the experimental groups. We observed a significantly higher postpurification recovery of islet equivalent number (IE) from pancreases processed using two lots of Liberase-CI enzyme (189 ± 20 × 103 IE, n = 4) and lot 2 (234 ± 39 × 103 IE, n = 7) than that obtained from pancreases processed with Sigma Type V (116.8 ± 27 × 103 IE, n = 5), Serva collagenase (49 ± 11.6 × 103 IE, n = 5, p < 0.05) or Boehringer–Mannheim (BM) Type P collagenase (85.4 ± 25 × 103 IE, n = 5, p < 0.05, ANOVA). No significant differences were observed in islet yield recovery from pancreases processed using the two production lots of Liberase-CI enzyme. Islet survival after 48 h in culture at 37°C was significantly higher from islets isolated using Liberase-CI enzyme (88 ± 3.7% survival) when compared to Sigma Type V (81.8 ± 3.3%), Serva (71.7 ± 2.8%), and BM Type P (77 ± 7.2%) (p < 0.05). Islet functional testing in vitro demonstrated islets isolated using crude collagenase had an increased insulin basal release and a reduced insulin stimulated response when compared with islets isolated using the two lots of Liberase-CI enzyme. The calculated stimulation index was 7.8 ± 1.7, 3.1 ± 0.6, and 4.8 ± 1.1 for Sigma Type V, Serva, and BM Type P isolated islets, respectively, compared to 15.7 ± 1.6 and 16.2 ± 1.9 for islets isolated with Liberase-CI enzyme production lots 1 and 2, respectively (p < 0.05). This evaluation demonstrates that a purified enzyme blend can significantly improve islet recovery and function. It also demonstrates the manufacturing reproducibility of Liberase-CI enzyme lots resulting in the isolation of canine islets with the same degree of efficacy. A blend of purified enzymes, specifically formulated for canine islet isolation, can consistently yield large numbers of islets that survive longer in culture and demonstrate an improved insulin response in vitro.

Hypoosmotic Exposure of Canine Pancreatic Digest as a Means to Purify Islet Tissue

The development of more effective means to separate pancreatic islets from the unwanted exocrine tissue would greatly advance the field of clinical islet allotransplantation in the treatment of insulin-dependent diabetes mellitus. Recent experiments with hamster islets have demonstrated a selective destruction of dissociated single exocrine cells when exposed to hypotonic conditions. It was the aim of this study to extend these observations to the canine model with collagenase dissociated pancreatic tissue and to evaluate the treatment's effect on islet function. Pancreases from five mongrel dogs were digested using an automated protocol of intraductal delivery of collagenase, and gentle dissociation. Duplicate samples of pancreatic digest were removed for insulin and amylase determination prior to and immediately following exposure to 50 mOsm/kg salt solution for a period of 30, 60, or 300 s before returning the digest to isoosmotic conditions. The remaining digest was cultured for a period of 48 h at 37°C before the tissue was recombined, washed, and a third sample removed for insulin and amylase. In vitro viability was then assessed using a static incubation assay with insulin content measured using a double-antibody radioimmunoassay, and amylase was determined using a colorimetric assay system. No difference in the insulin or amylase levels between the experimental groups was observed immediately following the hypotonic exposure; however, a significant decrease in the amylase content was observed following the 48-h culture period in digest that had been hypoosmotically exposed for 60 or 300 s compared with the pretreatment group (2.83 ± 0.41 IU amylase/mg pancreas vs. 1.29 ± 0.21 and 0.83 ± 0.12, mean ± SEM, p < 0.05). Insulin content was also significantly reduced in the 300-s exposure group compared with nontreated controls (3.2 ± 0.6 mU insulin/mg pancreas vs. 2.0 ± 0.2). The insulin/amylase ratio (I/A), a measure of islet and exocrine content, was 1.1 ± 0.13 following pancreas dissociation and 1.34 ± 0.21 for control tissue cultured for 48 h. The I/A ratio increased following hypoosmotic exposure to 1.50 ± 0.31 for tissue exposed for 30 s, 1.77 ± 0.19 for 60-s exposure, and 2.54 ± 0.13 for tissue exposed for 300 s (p < 0.05, vs. pretreatment group). In vitro insulin secretion was equivalent with the exception of the tissue exposed for 300 s, which had an increased basal level of insulin resulting in a significantly decreased stimulation index (3.8 ± 0.5 vs. 8.1 ± 1.2 for the purified islet control group, p < 0.05). These results suggest that a brief hypotonic exposure to pancreatic digest can alter the insulin/amylase ratio; however, there is a functional impairment on subsequent islet function after a period of in vitro tissue culture.

Improved islet survival and in vitro function using solubilized small intestinal submucosa

In vitro proliferation of isolated pancreatic islets has become an area of great interest given the scarcity of clinical islet donors and the islet mass requirements for clinical islet transplantation. Small intestinal submucosa (SIS), a naturally occurring extracellular matrix, has been investigated to promote wound healing, tissue remodeling and cell growth. This study evaluated recovery and function of isolated canine pancreatic islets following in vitro tissue culture. Pancreatic islets were isolated from mongrel dogs using standard surgical procurement followed by intraductal collagenase distension, mechanical dissociation and EuroFicoll purification. Groups of purified islets were cultured in a humidified atmosphere of 95% air and 5% CO(2) for 48 hours in standard islet culture conditions of CMRL 1066 tissue culture media (Gibco) which had been supplemented with 25microM HEPES, penicillin/streptomycin and either 10% heat inactivated fetal calf serum (FCS, Gibco) or solubilized SIS solution (Cook Biotech, Inc., West Lafayette, IN). The mean recovery of islets following the culture period was determined by sizing duplicate counts of a known volume and viability was assessed by static incubation with low glucose (2.8 mM), high glucose (20 mM) and high glucose solution supplemented with 50 microm IBMX solution. Remaining islets were embedded histologically. From a consecutive series of six culture experiments, a significantly higher (p < 0.05) recovery of islets co-cultured with SIS was observed when compared to controls. Mean islet recovery was 84.5 +/- 2.9% (mean +/- SEM) from the SIS cultured group compared with 64.7 +/- 4.5% from the control group cultured in FCS (p < 0.05, n=6). Islets from the SIS treated group exhibited a significantly higher (p <, 0.05) insulin response to the high glucose stimulus than islets cultured in the standard FCS cultured solution. The calculated stimulation index was 12.3 +/- 3.4 for the SIS-treated group compared with 5.6 +/- 1.8 for the standard cultured group (p < 0.05). The overall mean numbers of islets recovered following in vitro culture was also higher in the SIS-treated group. The proportion of islets with a mean diameter >150 microm increased from 24% to 31% in the SIS-treated group, whereas the same proportion decreased to 18% from 22% in the control (FCS-treated) group. Histological evaluation of fixed tissue samples collected following the culture period identified insulin and glucagon-secreting cells in the SIS and FCS treated groups, however a higher frequency of insulin positive cells were detected consistently in the SIS treated group. A proliferation marker (PCNA) identified positive cells within both groups as well. This study suggests that co-culture of freshly isolated canine islets in medium supplemented with solubilized SIS can improve the post-culture recovery and in vitro islet function. Future investigations will focus on the cellular interactions of SIS, both in vitro and in vivo.

The effects of microencapsulation on pancreatic islet osmotically induced volumetric response

Microencapsulation of pancreatic islets has been proposed as a means to prevent allograft rejection and to protect islets during cryopreservation. The aim of this study was to investigate: 1) the effects of the cryoprotectants (CPAs) dimethyl sulfoxide (DMSO) and ethylene glycol (EG) on the volume of Ca2+ alginate microcapsules, and 2) the effects of microencapsulation on the volumetric response of human and canine pancreatic islets during CPA equilibration. Stock sodium alginate with a high mannuronic acid content (HM) or a high guluronic acid content (HG) was used to generate empty capsules (mean diameter 200 microm) with an electrostatic generator. The capsules were held in place by a holding pipette system and videotaped during the addition of 2 or 3 M CPA at 22 degrees C. Islets (isolated from human cadaveric donors and mongrel dogs and then cultured overnight at 37 degrees C) were encapsulated in alginate (HM), loaded into a microperfusion chamber, and the change in islet volume was videotaped after exposure to the same CPAs and concentrations. These were compared to the volume responses of nonencapsulated islets. Images were analyzed using a computerized image analysis system and the data were analyzed using ANOVA. HG microcapsules showed a significant (p < 0.05) increase in volume following exposure to EG but not to DMSO. HM microcapsule volume did not change significantly following exposure to either EG or DMSO and was therefore chosen as the substrate for islet encapsulation. Free, nonencapsulated canine and human islets responded to the osmotic challenge of the 2 M DMSO by shrinking to 70.00 +/- 1.04% (mean +/- SEM) and 70.11 +/- 1.05%, and in 2 M EG to 72.89 +/- 1.93% and 69.33 +/- 1.38%, respectively, of the isotonic volume before returning to the original cell volume. Exposure to 3 M DMSO or EG resulted in a further dehydration to 65.89 +/- 0.91% and 67.67 +/- 1.91% for canine and 62.22 +/- 0.66.% or 65.89 +/- 1.30% for human islets. Minimum volumes were reached within 30-40 s after exposure to the cryoprotectant. Encapsulated human islets reached 86.88 +/- 1.47% of their original volume in 2 M and 80.33 +/- 0.89% in 3 M DMSO, and 87.33 +/- 1.86% in 2 M and 82.80 +/- 1.57% in 3 M EG. This volume change was significantly less (p < 0.01) than that observed in corresponding free islets. Encapsulated canine islets reached 83.67 +/- 2.13% of their original volume in 2 M and 78.22 +/- 0.95% in 3 M DMSO, and 85.44 +/- 1.92% in 2 M and 78.11 +/- 2.01% in 3 M EG. As with human islets, this was significantly different than free islets (p < 0.01). These minimal volumes were reached within 30-50 s. These results demonstrate that there are cryoprotectant and alginate-specific interactions and that microencapsulation modulates the degree of osmotically induced shrinkage of islets. The development or modification of existing cryopreservation protocols to improve postcryopreservation recovery or function must account for these factors.

Water and cryoprotectant permeability characteristics of isolated human and canine pancreatic islets

Cryopreservation allows accumulation of the necessary islet transplantable mass as well as adequate time for tissue typing and infectious disease screening. Cryopreservation protocols may be optimized by modeling the osmotically induced volume excursions that occur during the addition and removal of cryoprotective agents (CPAs). To that end, three transport parameters were measured at 22 degrees C in canine and human islets isolated by collagenase digestion and euroficoll purification: (i) the apparent hydraulic conductivity (Lp), (ii) the permeability coefficient of the CPA (Ps), and (iii) the associated reflection coefficient (sigma). The parameters were determined by volumetric analysis of islets upon abrupt exposure to 1, 2, and 3 M dimethyl sulfoxide (DMSO), ethylene glycol (EG), glycerol (GLY), and propylene glycol (PG). The parameters were calculated using the Kedem-Katchalsky theory to describe islet volume excursion kinetics (assuming islets to be single equivalent osmotic units with the same volume and surface area of the actual islet) and a three-parameter curve fit was performed using the Marquardt-Levenberg method. It was determined that the permeability characteristics of pancreatic islets are species specific, and based upon the measured parameters, the highest Ps values for canine islets were observed following exposure to 2 M EG, and the highest Ps values for human islets were observed following exposure to 2 M PG. The permeability parameters were analyzed adjusting for islet radius using ANCOVA procedures to acquire least square means. For canine islets exposed to 2 M EG these values were determined to be 0.936 microm/min/atm, 2.47 microm/s, and 0.90 (for Lp, Ps, and phi, respectively) and for human islets exposed to 2 M PG the values were determined to be 1.56 microm/min/atm, 3.48 microm/s, and 0.85 (for Lp, Ps, and sigma, respectively). These parameters were used in a model to calculate osmotically induced islet volumetric response upon addition/dilution of the optimum CPAs, taking into consideration critical volume excursion limits at which irreversible damage occurs.

Equations for obtaining melting points for the ternary system ethylene glycol/sodium chloride/water and their application to cryopreservation

The present study describes the H(2)O-NaCl-ethylene glycol ternary system by using a differential scanning calorimeter to measure melting points (T(m)) of four different ratios (R) of ethylene glycol to NaCl and then devising equations to fit the experimental measurements. Ultimately an equation is derived which characterizes the liquidus surface above the eutectic for any R value in the system. This study focuses on ethylene glycol in part because of recent evidence indicating it may be less toxic to pancreatic islets than Me(2)SO, which is currently used routinely for islet cryopreservation. The resulting physical data and previously determined information regarding the osmotic characteristics of canine pancreatic islets are combined in a mathematical model to describe the volumetric response to equilibrium-rate freezing in varying initial concentrations of ethylene glycol.

Osmotic tolerance limits of canine pancreatic islets

Future improvements in the recovery and function of pancreatic islets following cryopreservation will require a more precise quantification of the stresses that occur at each stage of the cryopreservation protocol. Changes in solution osmolality during the addition and dilution of cryoprotectants and during freezing and thawing induce changes in islet volume that may exceed tolerable limits. The aim of this study was to determine the range of solution osmolalities that results in significant changes in islet function. Islets were isolated from canine pancreases by collagenase digestion and Euro-Ficoll purification. Following 12-h culture at 37 degrees C, islets were counted and dispensed into multiwell plate inserts. Islet function was assessed in each well immediately before and 24 h following a 10-min osmotic challenge with hypo- or hyperosmotic solutions of PBS (0, 75, 150, 300, 600, 1200, or 2300 mOsm/kg) at 22 degrees C. Canine islets reached their osmotic equilibrium within 10 min. Duplicate wells were used for each osmolality treatment for each of six donors (n = 12). No significant differences in basal or glucose-stimulated insulin secretion were found between wells prior to the osmotic challenge (3.35 +/- 0.45 and 20.98 +/- 3.36 microIU/IE/h, respectively). Following the osmotic challenge and 24-h in vitro tissue culture, a significant increase in basal secretion was observed for islets exposed to 0 and 75 mOsm/kg solutions and a significant decrease for islets exposed to 2300 mOsm/kg solution. Islets exposed to 0 and 2300 mOsm/kg solutions showed significant decreases in the stimulated insulin secretion when compared to controls. Solution osmolalities of 150-1200 mOsm/kg appear to be tolerated by canine islets with no significant deviations in insulin secretion. The corresponding tolerable volume range was 152.6 +/- 6.8% to 60 +/- 5.1% of the isotonic islet volume. The minimum critical volume was used in a theoretical analysis of the islet volumes that would result from equilibrium freezing in dimethyl sulfoxide (DMSO). The calculations show that 1.5 mol/l DMSO is sufficient to prevent damage to islets due to excessive shrinkage. Further refinement of cryoprotectant addition and dilution protocols, and cooling and warming protocols for canine islets, are now possible.

A prospective comparison of discontinuous EuroFicoll and EuroDextran gradients for islet purification

Density gradient separation of islets from exocrine tissue is usually performed with Ficoll. However, this reagent adds significantly to the cost of the isolation. The aim of this study was to evaluate the performance of Dextran as a potential low-cost substitute for Ficoll and to evaluate the effects of cold storage of the pancreatic digest prior to purification. Pancreases were procured from mongrel dogs, loaded with collagenase and mechanically dissociated. Washed pancreatic digest was collected and divided into two fractions that were purified using discontinuous gradients on the Cobe 2991 processor using identically prepared EuroFicoll (EF) or EuroDextran (ED) gradients. Alternate groups were suspended in EC and stored on ice, while the other fraction were resuspended in the 1.108-g/mL gradient layer (either EF or ED) and loaded into the COBE. This tissue layer was overlaid with layers of densities 1.096 and 1.037 g/mL and a HBSS cap, and centrifuged for 5 min at 800 x g. Purified islets were collected from the interface between the 1.037 and 1.096 layers and islet recovery, purity, and function were assessed. From a series of eight isolations, 72.9 +/- 8.2% (mean +/- SEM) of the islets were recovered from the EF purified gradients compared with 62.6 +/- 8.3% from ED gradients (p = NS, paired t-test). Gradients of ED that were run following hypothermic storage of the digest in cold EC solution (stored ED) had reduced islet recovery when compared with islet recovery from gradients prepared in EF(stored EF) (51.6 +/- 9.6% for ED stored vs. 72.9 +/- 11.9 for EF stored, p < 0.05). Islet recovery from EF gradients was equivalent between the stored and nonstored groups. The purity of preparations from the stored ED gradients was also reduced (71.3 +/- 4.3%) when compared with islets that were immediately purified after dissociation (82.5 +/- 4.8%, p < 0.05). Static glucose stimulation assay showed equivalence between the islets from ED and EF gradients. The stimulation index (SI) was 9.3 +/- 0.9 for EF islets compared with 7.9 +/- 1.4 for ED islets for digest purified immediately. However, if the digest was hypothermically stored in EC solution, a decrease in functional viability was observed in both the EF and the ED groups (7.7 +/- 1.4 and 5.9 +/- 0.8, respectively). Out of five alloxan-induced diabetic nude mice transplanted under the kidney capsule with 2000 islets isolated from the nonstored groups, three remained euglycemic >50 days posttransplant with either EF or ED islets. These experiments demonstrate effective recovery of equivalent numbers of canine islets using discontinuous gradients of ED or EF immediately following enzymatic digestion. However, following storage of the digest in cold EC solution results in a reduction in both islet recovery and function when gradients of ED are utilized.

Evaluation of a purified enzyme blend for the recovery and function of canine pancreatic islets

Recently developed technologies enabling the production of a reproducible, purified enzyme blend for optimal human pancreatic islet isolation has renewed interest in clinical islet transplantation. The canine model has been an ideal preclinical model for the development of islet transplantation protocols. As seen in other species, the application of crude collagenase for isolating canine islets resulted in highly variable islet yields, extensive islet fragmentation, and variable islet functionality. We compared the function of commercially available crude collagenases with that of Liberase-CI purified enzyme blend for canine islet isolation. We also compared two manufacturing runs of Liberase-CI enzyme (lots 1 and 2) to demonstrate reproducibility of islet recovery and function. We report on the improved recovery and function of islets isolated using Liberase-CI enzyme. No difference in dog age, mean body weight, or pancreas weight were observed between the experimental groups. We observed a significantly higher postpurification recovery of islet equivalent number (IE) from pancreases processed using two lots of Liberase-CI enzyme (189 +/- 20 x 10(3) IE, n = 4) and lot 2 (234 +/- 39 x 10(3) IE, n = 7) than that obtained from pancreases processed with Sigma Type V (116.8 +/- 27 x 10(3) IE, n = 5), Serva collagenase (49 +/- 11.6 x 10(3) IE, n = 5, p < 0.05) or Boehringer-Mannheim (BM) Type P collagenase (85.4 +/- 25 x 10(3) IE, n = 5, p < 0.05, ANOVA). No significant differences were observed in islet yield recovery from pancreases processed using the two production lots of Liberase-CI enzyme. Islet survival after 48 h in culture at 37 degrees C was significantly higher from islets isolated using Liberase-CI enzyme (88 +/- 3.7% survival) when compared to Sigma Type V (81.8 +/- 3.3%), Serva (71.7 +/- 2.8%), and BM Type P (77 +/- 7.2%) (p < 0.05). Islet functional testing in vitro demonstrated islets isolated using crude collagenase had an increased insulin basal release and a reduced insulin stimulated response when compared with islets isolated using the two lots of Liberase-CI enzyme. The calculated stimulation index was 7.8 +/- 1.7, 3.1 +/- 0.6, and 4.8 +/- 1.1 for Sigma Type V, Serva, and BM Type P isolated islets, respectively, compared to 15.7 +/- 1.6 and 16.2 +/- 1.9 for islets isolated with Liberase-CI enzyme production lots 1 and 2, respectively (p < 0.05). This evaluation demonstrates that a purified enzyme blend can significantly improve islet recovery and function. It also demonstrates the manufacturing reproducibility of Liberase-CI enzyme lots resulting in the isolation of canine islets with the same degree of efficacy. A blend of purified enzymes, specifically formulated for canine islet isolation, can consistently yield large numbers of islets that survive longer in culture and demonstrate an improved insulin response in vitro.

Osmotic characteristics of isolated human and canine pancreatic islets

Cryopreservation protocols for pancreatic islets may be optimized by modeling the changes in volume that occur during cryoprotectant addition/dilution and cooling/warming. Modeling may be facilitated if it can be demonstrated that isolated islets behave as ideal osmometers where the equilibrium volume is a linear function of the reciprocal of the osmolality of the extracellular medium (the Boyle van't Hoff relationship). The present study was performed to test the hypotheses that: (i) human and canine islets exhibit a linear osmotic response during exposure to hypo-, iso-, and hyperosmotic solutions and to determine the human and canine islets osmotically inactive fraction (Vbp); (ii) to determine if the ionic properties of a concentrated electrolyte solution have an effect on the osmotic response; and (iii) to determine if the osmotic response of pancreatic islets varies between species (human and canine). Islets were isolated from four human and four canine pancreases using standard collagenase digestion and EuroFicoll purification. After 12 h incubation at 37 degrees C, islets (n = 4 from each isolation) were exposed to varying salt or sucrose concentrations (75-1200 mOsm/kg). Islets were held by a micropipette system attached to an inverted microscope, and solutions were exchanged while videotaping. An imaging system was used to determine the cross-sectional area of the islet which was then used to estimate the spherical volume. The results of linear regression analysis indicated that both human and canine islets respond ideally to osmotic conditions within a range of 150-1200 mOsm/kg in both the electrolyte (salt) and the nonelectrolyte (sucrose) solutions. The Vbp value (mean +/- SD) of the four donors was 0.513 +/- 0.068 for canine islets in sucrose solutions, 0.474 +/- 0.068 for canine islets in salt solutions, 0. 425 +/- 0.073 for human islets in sucrose solutions, and 0.39 +/- 0. 073 for human islets in salt solutions. There was a significant difference between human and canine islets (P < 0.05) but not between experimental solutes (NaCl or sucrose) (P < 0.05). These data may be used in conjunction with osmotic tolerance data to develop improved methods for the cryopreservation of isolated islets.

Injury and protection in split-thickness skin after very rapid cooling and warming

The ability of low glycerol concentrations and high cooling and warming rates to optimize the survival of frozen/thawed split-thickness porcine skin was investigated. 1H nuclear magnetic resonance spectroscopy was used to measure the diffusion kinetics of glycerol in skin at 4, 12, and 22 degrees C. Equilibrium concentrations were 44 to 69% of the external bathing medium. Rate constants for glycerol diffusion (D/l2) were calculated from the uptake data using a plane sheet model and a least squares method and were independent of external glycerol concentrations: D/l2 = 3.84 x 10(-4) 8-1 at 4 degrees C with an activation energy of 11.2 +/- 4.3 kcal/mol. Skin was cooled rapidly (-5100 degrees C/min) after different times of glycerol permeation at 4 or 22 degrees C, and survival was assessed after warming (+5400 degrees C/min) by an oxygen consumption assay. Recovery of aerobic activity increased in a concentration-dependent manner, and reached 100% after a 10-min exposure to 2 M glycerol at 4 degrees C or 3 min at 22 degrees C, for an uptake of 1.1 M glycerol. Light micrographs of freeze-substituted skin showed a glycerol-dependent decrease in the nucleation and growth of ice in the dermis and epidermis after rapid cooling. A 5-mm exposure to 2 M glycerol at 22 degrees C resulted in the elimination of all observable epidermal ice, except for extremely small ice crystals (< or = 0.5 micron diameter) in the intercellular spaces and in few nuclei, and complete preservation of the fibrous structure of dermal collagen bundles. This cryoprotective mechanism has the potential to offer complete protection of both dermal and viable epidermal targets of freeze/thaw injury and may be applicable to other thin, membranous tissues.

The determination of membrane permeability coefficients of canine pancreatic islet cells and their application to islet cryopreservation

Sufficient numbers of pancreatic islets for successful allotransplantation can be achieved by storing and then pooling islets from several donors. Optimal MHC matching and infectious disease screening also require long-term storage of islets, and cryopreservation is currently the only practical approach. Cryopreservation protocols may be optimized by modeling the changes in cell volume and the associated damage incurred during cryoprotectant addition and dilution and during cooling and warming. The objective of the present work was to determine the following biophysical parameters of canine islet cells; the osmotically inactive cell volume (Vb), hydraulic conductivity (Lp), cryoprotectant permeability coefficient (Ps), and the reflection coefficient sigma. A determination of these parameters allows the simulation of cell responses using computer models. Islets were isolated by collagenase digestion and Euro-Ficoll purification. After 24 h culture, islets were dissociated into single cells using trypsin and 2 mM EGTA. The kinetic change in cell volume as a function of time after exposure to 2 M dimethyl sulfoxide (Me2SO) was measured using an electronic particle counter at 22, 5, and -3 degrees C. At -11 degrees C, cells were preloaded with 1 M Me2SO and exposed to 4 M Me2SO to prevent the formation of ice in the working solution. Kedem-Katchalsky theory was used to describe the cell volume change kinetics, and a three-parameter curve fitting was performed using the Marquardt-Levenberg method to determine Lp, Ps, and sigma values. The Lp was determined to be 0.19 +/- 0.05, 0.037 +/- 0.005, 0.020 +/- 0.003, and 0.013 +/- 0.005 micron.min-1.atm-1 (mean +/- SD) at 22, 5, -3, and -11 degrees C, respectively. The Ps values were 1.05 +/- 0.50, 0.15 +/- 0.04, 0.096 +/- 0.028, and 0.067 +/- 0.029 x 10(-3) cm.min-1 at 22, 5, -3, and -11 degrees C, respectively. The sigma values were 0.81 +/- 0.16, 0.91 +/- 0.09, 0.80 +/- 0.21, and 0.98 +/- 0.04 at 22, 5, -3, and -11 degrees C, respectively. The temperature dependence or activation energy of Lp and Ps was calculated, using the Arrhenius equation, to be 12.7 and 13.5 kcal.mol-1, respectively. These permeability parameters were used to calculate cell water loss and the likelihood of lethal intracellular freezing during cooling, as well as both water flux and solute concentration gradients across the cell membrane during warming.

Hypoosmotic exposure of canine pancreatic digest as a means to purify islet tissue

The development of more effective means to separate pancreatic islets from the unwanted exocrine tissue would greatly advance the field of clinical islet allotransplantation in the treatment of insulin-dependent diabetes mellitus. Recent experiments with hamster islets have demonstrated a selective destruction of dissociated single exocrine cells when exposed to hypotonic conditions. It was the aim of this study to extend these observations to the canine model with collagenase dissociated pancreatic tissue and to evaluate the treatment's effect on islet function. Pancreases from five mongrel dogs were digested using an automated protocol of intraductal delivery of collagenase, and gentle dissociation. Duplicate samples of pancreatic digest were removed for insulin and amylase determination prior to and immediately following exposure to 50 mOsm/kg salt solution for a period of 30, 60, or 300 s before returning the digest to isoosmotic conditions. The remaining digest was cultured for a period of 48 h at 37 degrees C before the tissue was recombined, washed, and a third sample removed for insulin and amylase. In vitro viability was then assessed using a static incubation assay with insulin content measured using a double-antibody radioimmunoassay, and amylase was determined using a colorimetric assay system. No difference in the insulin or amylase levels between the experimental groups was observed immediately following the hypotonic exposure; however, a significant decrease in the amylase content was observed following the 48-h culture period in digest that had been hypoosmotically exposed for 60 or 300 s compared with the pretreatment group (2.83 +/- 0.41 IU amylase/mg pancreas vs. 1.29 +/- 0.21 and 0.83 +/- 0.12, mean +/- SEM, p < 0.05). Insulin content was also significantly reduced in the 300-s exposure group compared with nontreated controls (3.2 +/- 0.6 mU insulin/mg pancreas vs. 2.0 +/- 0.2). The insulin/ amylase ratio (I/A), a measure of islet and exocrine content, was 1.1 +/- 0.13 following pancreas dissociation and 1.34 +/- 0.21 for control tissue cultured for 48 h. The I/A ratio increased following hypoosmotic exposure to 1.50 +/- 0.31 for tissue exposed for 30 s, 1.77 +/- 0.19 for 60-s exposure, and 2.54 +/- 0.13 for tissue exposed for 300 s (p < 0.05, vs. pretreatment group). In vitro insulin secretion was equivalent with the exception of the tissue exposed for 300 s, which had an increased basal level of insulin resulting in a significantly decreased stimulation index (3.8 +/- 0.5 vs. 8.1 +/- 1.2 for the purified islet control group, p < 0.05). These results suggest that a brief hypotonic exposure to pancreatic digest can alter the insulin/amylase ratio; however, there is a functional impairment on subsequent islet function after a period of in vitro tissue culture.

Mechanisms of cryoinjury and cryoprotection in split-thickness skin

Successful cryopreservation of tissues will ultimately require a more detailed understanding of how the in situ environment modifies cell responses during cooling and warming. Low-temperature responses of porcine split-thickness skin and isolated basal keratinocytes were compared after various cooling protocols and in the presence and absence of cryoprotectants. Recovery was assessed by measuring oxygen consumption kinetics in skin and tetrazolium reduction in isolated cells. Freeze substitution was used to visualize ice nucleation and growth in skin. The results indicated that the time required for diffusion of water in split-thickness skin delayed osmotic responses in the basal keratinocytes and resulted in increased intracellular and intercellular ice formation. Rapid cooling (-200 degrees C/min) in the presence of cryoprotectants resulted in a reduction in the number of cells containing ice and the size of the intercellular ice crystals and an increase in tissue recovery. These observations support other reports which suggest that cell-to-cell and cell-to-substrate interactions are sensitive sites for cryoinjury. A practical recommendation from this study is that high recovery of split-thickness skin may be achieved with protocols using high cooling rates.

A simple, effective system for assessing viability in split-thickness skin with the use of oxygen consumption

To address the recognized need for better viability-assessment techniques in the banking of allograft skin, we have developed a simple, effective, and easily constructed system for measuring the aerobic activity in small skin samples. The system consists of a microcomputer interfaced to a Clark-type polarographic oxygen electrode to measure oxygen concentrations in discs (5 mm diameter) of split-thickness skin. The system allows simultaneous data acquisition and an on-screen display of oxygen readings on a linear or logarithmic scale. The computer program quantifies the rate of oxygen consumption by calculating a linear regression of oxygen measurements between 100 and 600 seconds. Data are stored in a standard format for easy transfer to commercial software packages for further analysis. The kinetics of oxygen consumption by porcine split-thickness skin stored at 4 degrees C for up to 21 days was assessed with this technique and showed a gradual decline in rate as function of storage time, reaching 50% recovery after 6 days. This assay is a simple and inexpensive method to establish and perform, thus making it suitable as a routine assay for use in the banking of skin and other tissues.

Factors influencing survival of mammalian cells exposed to hypothermia. V. Effects of hepes, free radicals, and H2O2 under light and dark conditions

Cytotoxicity resulting from the interaction of fluorescent light from a flow hood with Hepes-buffered cell culture medium at room temperature was demonstrated. Toxicity was prevented by keeping both cells (V79 Chinese hamster) and medium shielded from direct fluorescent light ("dark conditions") or by supplementing the medium with 10 micrograms/ml catalase; this suggests that extracellular hydrogen peroxide is a major cause of the lethal effect under "lighted conditions." No sensitization resulted from the exposure of cells in a sodium bicarbonate (SBC)-buffered medium to fluorescent light, nor in a catalase supplemented SBC-buffered medium. The Hepes/light reaction during routine cell manipulations presensitized cells to hypothermia damage in the dark with the presensitization being more severe for 5 than for 10 degrees C hypothermic exposure. Presensitization was prevented by performing the complete experiment under dark conditions or by supplementing the medium with 10 micrograms/ml catalase. However, catalase did not improve the hypothermic survival when experiments were performed under dark conditions. Hence, 10 micrograms/ml catalase does not protect cells from hypothermic (5 and 10 degrees C) damage per se, but rather from Hepes/light sublethal damage which interacts with hypothermic sublethal damage to result in lethal lesions. Additionally, under dark conditions, superoxide dismutase (SOD), allopurinol, catalase plus SOD, DMSO, or mannitol did not improve survival when present during hypothermic storage, suggesting that extracellular superoxide anion, hydrogen peroxide, or hydroxyl radicals are not the cause of cell killing under conditions of pure hypothermia uncomplicated by prehypothermic ischemia or hypoxia.

Factors influencing survival of mammalian cells exposed to hypothermia. IV. Effects of iron chelation

Survival of V-79 Chinese hamster cells was assessed by colony growth assay after hypothermic exposure in the presence of iron chelators. At 5 degrees C, maximum protection from hypothermic damage was achieved with a 50 microM concentration of the intracellular ferric iron chelator Desferal. A 3-hr prehypothermic incubation with 50 microM Desferal followed by replacement with chelator-free medium at 5 degrees C also provided some protection. This was not observed when the extracellular chelator DETA-PAC (50 microM) was used prior to cold storage. Treating 5 degrees C-stored cells with Desferal just prior to rewarming was ineffective, but treating cells with Desferal during hypothermia exposure after a significant period of unprotected cold exposure ultimately increased the surviving fraction. Submaximal protection during hypothermia was achieved to various degrees with extracellular chelators at 5 degrees C, including 50 microM DETAPAC and 110 microM EDTA. EGTA (110 microM) had little effect. The sensitization of cells at 5 degrees C with 200 microM FeCl3 could be reduced or eliminated with Desferal in accordance with a 1:1 binding ratio. At 10 degrees C, 50 microM Desferal, 50 microM DETAPAC, and 110 microM EDTA were as or less effective in protecting cells than at 5 degrees C. An Arrhenius plot of cell inactivation rates shows a break at 7-8 degrees C, corresponding to maximum survival for control cells and cells in 50 microM Desferal; however, the amount of protection offered by the chelator increases with decreasing temperature below about 19 degrees C, and sensitization increases above that point. It has not previously been shown that iron chelators protect against cellular hypothermia damage which is uncomplicated by previous or simultaneous ischemia. This may be relevant to the low-temperature storage of transplant organs, in which iron of intracellular origin and in the perfusate may be active and damaging.