Significant progress in porcine islet mass isolation utilizing liberase HI for enzymatic low-temperature pancreas digestion.

BACKGROUND: Frequent success in human islet isolation is prevented by the large variability of scarce organ donors; this favors the future utilization of pigs as donors for clinical islet xenotransplantation. Porcine-specific difficulties of islet isolation are attributed to the intrinsic fragility of islets during pancreas digestion. METHODS: To preserve islet integrity during efficient pancreas dissociation, porcine pancreata (n=48) were distended after cold storage with cold University of Wisconsin solution containing Liberase HI and digested at 24-28 degrees C using digestion-filtration. Pancreata distended with University of Wisconsin solution containing well-proven crude collagenase and digested at 32-34 degrees C served as controls (n=46). Monolayer Ficolldiatrizoate gradient purification was performed in a Cobe 2991. RESULTS: Purified yield of islet equivalents per pancreas (mean+/-SEM) was almost doubled by Liberase HI compared with crude collagenase (526,480+/-46,560 vs. 270,270+/-19,420; P < 0.0001) and also significantly increased comparing islet equivalents per gram of pancreas (4,210+/-320 vs. 2,640+/-245; P=0.0004). Islet integrity was better preserved during Liberase HI digestion compared with crude collagenase digestion as indicated by isolation index (2.1+/-0.1 vs. 1.4+/-0.1; P<0.0001). Purity, viability, and in vitro function of islets did not differ between experimental groups. Preserved in vivo function of islets isolated by Liberase HI was demonstrated after subcapsular transplantation into 16 diabetic nude rats. CONCLUSIONS: If the problems related to xenograft rejection and xenosis could be solved, low-temperature digestion of porcine pancreata using Liberase HI could serve as an essential prerequisite for successful 1:1 xenotransplantation of pig islets into type 1 diabetic human recipients.     

Multi-lot analysis of custom collagenase enzyme blend in human islet isolations

INTRODUCTION: Variability currently in Liberase HI from lot to lot limits the ability to effectively isolate islets with consistency. Roche Diagnostics Inc (Indianapolis, Ind, USA) has developed a Custom Collagenase enzyme blend in hopes that producing collagenase II and I and thermolysin separately will eliminate variability. In this study we examined the variability in Custom Collagenase lots in respect to isolation results and isolation success rates and compared those to Liberase HI. METHODS: We retrospectively analyzed records from 68 islet isolations where either Liberase HI (lot A: n = 23, Lot B: n = 20) or Custom Collagenase blend (Lot C: n = 10, Lot D: n = 15) was employed. Human islets were isolated from cadaveric pancreata using standardized methods performed in a controlled islet isolation facility. RESULTS: Analysis of Liberase HI and Custom Collagenase using Student t test showed no difference between the two groups. Comparison of the two Custom Collagenase lots using the t test showed a statistical difference between undigested pancreas weight and pancreas digestion times. Using chi-square test, no statistical significance was found in isolation success rates from lot to lot. CONCLUSION: Although the Custom Collagenase blend is comparable to Liberase HI in its ability to isolate human islets, variability still exists from lot to lot when used conventionally as Liberase HI is. The ability to predetermine doses is beneficial, and as techniques to manipulate the activity levels prior to isolations improve so to will the enzymes' ability to isolate islets on a consistent basis.     

Assessment of a novel two-component enzyme preparation for human islet isolation and transplantation

BACKGROUND: Biologic characteristics of enzyme products used for islet isolation are critical for the success of islet transplantation. In particular, lot-to-lot variability significantly affects the yields of the isolation procedure. In this study, we have evaluated a new enzyme preparation in which highly purified collagenase can be blended with separately supplied neutral protease in a predetermined ratio. METHODS: We compared the results of human-islet isolations performed either with Collagenase NB1 supplemented with Neutral Protease NB (group I, n=9) or with Liberase (group II, n=9). RESULTS: Endotoxin contents of the enzyme preparations were lower in group I. Total islet yields were similar in both groups, but islet equivalents per gram of pancreas was higher in group I (4,020+/-1,240 vs. 2,360+/-1,350; P<0.05). Islet morphology was improved in group I with significantly higher proportion of free and intact islets (71+/-9% vs. 52+/-14%; P<0.01). In vitro function was improved and apoptosis rate was lower in group I. CONCLUSIONS: This new enzyme blend was as efficient as Liberase in terms of islet yields and showed improvements in islet morphology, viability, and in vitro function. The possibility to control lot-to-lot variability and the low endotoxin contents make Collagenase NB1 a promising product for human-islet isolation.     

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.     

Evaluation of viable β-cell mass is useful for selecting collagenase for human islet isolation: comparison of collagenase NB1 and liberase HI

The selection of enzyme blend is critical for the success of human islet isolations. Liberase HI collagenase (Roche) was introduced in the 1990s and had been widely used for clinical islet transplantation. More recently, a blend collagenase NB1 has been rendered available. The aim of this study was to evaluate the isolation outcomes and islet quality comparing human islet cells processed using NB1 and Liberase HI. A total of 90 isolations processed using NB1 (n = 40) or Liberase HI (n = 50) was retrospectively analyzed. Islet yield, function in vitro and in vivo, cellular (including β-cell-specific) viability and content, as well as isolation-related factors were compared. No significant differences in donor-related factors were found between the groups. There were also no significant differences in islet yields (NB1 vs. Liberase: 263,389 ± 21,550 vs. 324,256 ± 27,192 IEQ; p = n.s., respectively). The pancreata processed with NB1 showed a significantly longer digestion time (18.6 ± 0.7 vs. 14.5 ± 0.5 min, p < 0.01), lower β-cell viability (54.3 ± 3.4% vs. 72.0 ± 2.1%, p < 0.01), β-cell mass (93,671 ± 11,150 vs. 148,961 ± 12,812 IEQ, p < 0.01), and viable β-cell mass (47,317 ± 6,486 vs. 106,631 ± 10,228 VβIEQ, p < 0.01) than Liberase HI. In addition, islets obtained with Liberase showed significantly better graft function in in vivo assessment of islet potency. The utilization of collagenase NB1 in human islet isolation was associated with significantly lower β-cell viability, mass, and islet potency in vivo in our series when compared to Liberase HI, even though there was no significant difference in islet yields between the groups. Evaluation of viable β-cell mass contained in human islet preparations will be useful for selecting enzyme blends.     

Serva collagenase NB1: a new enzyme preparation for human islet isolation

INTRODUCTION: Advances in the rate of success of human islet isolation are due in part to the availability of new purified enzyme blends. In this study we evaluated a new enzyme preparation composed of a highly purified collagenase that can be reproducibly blended with predetermined amounts of separately packaged neutral protease. METHODS: Nine human islet isolations were performed with collagenase NB1 supplemented with neutral protease (Serva Electrophoresis GMbH, group I). Yields, purity, morphology, in vitro function and islet cell apoptosis were assessed. The results were compared to those of nine human islet isolations performed with Liberase (Roche, group II) and matched for donor age, BMI, and circumstances of death. RESULTS: Islet yields were similar in both groups. However, islet equivalents (IE) per gram of pancreas and IE number to islet number were higher in group I (P <.05). Stimulation indices after insulin response to glucose (static incubation) were similar in both groups. Islet cell apoptosis rate was statistically significantly lower in group I. Islet morphology was significantly improved in group I with a higher proportion of intact islets. CONCLUSION: This new enzyme preparation (collagenase NB1 with neutral protease adjunct) was as effective as Liberase in terms of islet yields and function. Islet morphology was improved and rate of islet cell apoptosis was lower with this new collagenase. The absence of lot-to-lot variability in terms of neutral protease to collagenase ratio makes collagenase NB1 a promising enzyme for human islet isolation.     

Serine-protease inhibition during islet isolation increases islet yield from human pancreases with prolonged ischemia.

BACKGROUND: Islet isolation from the pancreatic tissue matrix remains highly variable. Recent evidence suggests that intrinsic human pancreatic proteases, including trypsin, may inhibit effective collagenase enzymatic activity during islet isolation, thereby impairing the isolation success. In this study we have hypothesized that serine protease inhibition applied during pancreatic digestion, could improve yield and/or functional viability of islets isolated from human pancreases. METHODS: Twelve organ donor pancreases with 12.9+/-0.6 hr cold storage (mean+/-SEM) were perfused via their ducts with Liberase-HI enzyme in the presence (n=6) or absence (n=6) of 0.4 mM Pefabloc. All were then gently dissociated and their purified islets separated with Ficoll density gradient centrifugation. RESULTS: Donor-related factors (age, gender, cold storage time, body mass index, and pancreas weight) did not differ significantly between the two experimental groups. Pefabloc supplementation did not affect the digestion time, islets remaining trapped in exocrine tissue, or final islet purity. Islet recovery was increased in the Pefabloc-treated group (mean+/-SEM yield 323.8+/-80.8 x 10(3) islet equivalents vs. 130.8+/-13.6 x 10(3) islet equivalents, P<0.05). Cellular composition, DNA and insulin content, and insulin secretory activity of the isolated islets was similar. CONCLUSIONS: Inhibition of intrinsic protease activity within pancreases after prolonged cold storage improves isolation of viable islets.     

Effective islet isolation method with extremely high islet yields from adult pigs

Achieving good islet isolation is one of the most important factors for successful islet transplantation. Porcine pancreas is suitable for islet isolation research due to its anatomical and physiological similarities to human pancreas. In this study, we evaluated a new porcine islet isolation method designed to maximize islet yield and compared it with our previous open pan method and the standard method using a Ricordi chamber (Ricordi method). We performed 15 porcine islet isolations, five each with the new method, the open pan method, and the Ricordi method. The new method features several important improvements. Pancreata remain uncut and are kept intact during collagenase intraductal injection, a large filtration chamber to handle whole pancreata, low concentration of collagenase (Liberase HI) for digestion, and large plastic containers for large-scale islet purification. All isolated islets were assessed for yield, purity, viability and in vitro function. Islets isolated with this new method were transplanted under the kidney capsules of SCID mice with chemically induced diabetes for in vivo functional assessment (n = 8). With the new method, we obtained on average more than 1,000,000 islet equivalents (IE) (1,236,266 +/- 213,486 IE) (mean +/- SE) before purification and 800,000 IE (879,815 +/- 222,729 IE) after purification from one adult pig. Islet yield per pancreas was significantly higher compared with our previous open pan method (30,666 +/- 11,532 IE, p < 0.01) and the Ricordi method (317,073 +/- 86,093 IE, p < 0.05). All mice, transplanted with 1000 islets from the new method, returned to normoglycemia within 4 days after transplantation. Our new method makes it possible to obtain extremely high porcine islet yield with good function. It should produce useful information for human islet isolation and transplantation, and might be applied to single donor clinical xenogeneic transplantation.     

Comparison of size,viability, and function of fetal pig islet-like cell clusters after digestion using collagenase or liberase

Liberase is a highly purified blend of collagenases that has been specifically developed to eliminate the numerous problems associated with the conventional use of crude collagenase when isolating islet-like cell clusters (ICCs) from pancreases of different species. The influence of Liberase on yield, size, viability, and function of ICCs has been documented when this enzyme was used to digest adult but not fetal pancreases. In this study, we compared the effects of collagenase and Liberase on fetal pig ICCs. A total of eight fetal pig pancreas digestions were analyzed. Fetuses were obtained from Large White Landrace pigs of gestational age 80 +/- 2.1 days. The pancreases were digested with either 3 mg/ml collagenase P or 1.2 mg/ml Liberase HI. The time taken to digest the pancreas was shorter for collagenase when compared with Liberase (22 +/- 2 vs. 31 +/- 2 min). The size of ICCs was similar for both collagenase (83 +/- 0.5 microm) and Liberase (79 +/- 0.4 microm) as was the number of ICCs produced per pancreas (7,653 +/- 1,297 vs. 8,101 +/- 1,177). Viability, as assessed using fluorescent markers, was slightly greater for Liberase (79 +/- 1% vs. 76 +/- 1%, p < 0.05). Responsiveness to beta-cell stimulus (20 mM KCl) was similar for both methods of isolation, as was the insulin content of the ICCs, both in vitro and at I month after transplantation of 1,500 ICCs beneath the renal capsule of immunoincompetent mice. Despite the high content of endotoxins in collagenase, the above results show that this enzyme was equally as efficient as Liberase in isolating functional ICCs from fetal pig pancreas.     

Quantitative assessment of collagenase blends for human islet isolation

BACKGROUND: The variability in collagenase blends has been speculated as the single most important determinant of the success or failure in isolated islet yields in clinical islet transplantation. Examination of the formulation and potency of the widely used Liberase HI enzyme blend will uncover possible sources of imprecision. METHODS: High performance liquid chromatography (HPLC) and kinetic measurements of collagenase and protease activity were used to assess potency. Between four and nine clinical lots were assessed for various parameters such as relative formulation of collagenase isoforms, and recovered collagenase and protease potencies postreconstitution. RESULTS: Six vials from a single typical lot had a mean enzyme content of 489+/-62.5 mg (mean+/-SEM; range 398-610 mg). The mean recovered collagenase activity was 2235+/-310 Wünsch units (WU)/vial (range 1794-2968 WU/vial). The percent coefficients of variation for collagenase and protease activity in these vials were 17.4%, and 13.4%, respectively. The increase in the presence of the collagenase Ib (CIb) isoform detected by HPLC analysis was related to the chronological order of the date of manufacture. The CIb isoform was found to have a reduced specific activity compared to intact collagenase I (CI) (3.8+/-1.2 WU/mg vs. 2.1+/-0.7 WU/mg, P < 0.05). The presence of CIb was related to reduced islet yields in twelve human isolations studied. CONCLUSIONS: Variation in potency was observed between, and within lots of Liberase HI in this study. Differences in relative collagenase isoform composition may also affect the stability and potency characteristics of these blends.     

三种消化酶在大鼠胰岛分离纯化中的效果比较

目的　分别用 3种酶消化大鼠胰腺 ,比较分离纯化后胰岛细胞的收获量、纯度、活性和功能。方法　将 2 1只SD大鼠按应用释放酶、胶原酶P、胶原酶V消化胰腺随机均分为A、B、C组。结果　A组的胰岛细胞收获量比B组或C组多 ( 93 0± 78比 692± 68或 70 6± 70 ,P <0 .0 5 ) ;纯度比B组或C组高 ( 93 .8± 2 .3比 88.4± 2 .0或 89.2± 2 .1,P <0 .0 5 ) ;成活率比B组或C组高( 97.2± 1.4比 92 .2± 1.9或 92 .9± 2 .1,P <0 .0 5 ) ;A组培养后胰岛素分泌量和葡萄糖刺激时胰岛素分泌量比B组或C组多 (P <0 .0 5 ) ;A组逆转糖尿病大鼠的高血糖状态时间比B组或C组长( 7.5± 1.3比 5 .8± 1.6或 6.3± 1.2 ,P <0 .0 5 )。结论　与胶原酶P和胶原酶V比较 ,释放酶消化大鼠胰腺可提高胰岛细胞的收获量、纯度、活性和功能。     

Adaption of neutral protease activity for islet isolation from the long-term two-layer method-stored pig pancreas

BACKGROUND: Islet release from the pancreas is mediated by both collagenase and neutral protease (NP), a critical effector of islet integrity. To prove the hypothesis that adjustment of NP reduces islet damage after prolonged ischemia, adult pig pancreata were digested after 7-hour preservation by the two-layer method (TLM) using a 2-component enzyme blend consisting of collagenase NB-8 and NP. METHODS: After intraductal University of Wisconsin (UW) flush resected pancreata were distended with 4.4 PZ-U/g of UW-dissolved Serva collagenase either before (TLM-preloaded, n = 7) or after (TLM-postloaded, n = 10) cold storage, or for immediate processing (n = 6). NP was adjusted after preliminary experiments to respectively 1.1, 0.2, or 0.8 DMC-U/g for unstored, TLM-preloaded, or postloaded organs. RESULTS: Purified islet yield decreased from 3670 +/- 730 islet equivalents (IEQ)/g in unstored pancreata to 1800 +/- 180 and 2080 +/- 290 IEQ/g in TLM-preloaded or postloaded organs, respectively (P < .05). Although purity was always >90%, IEQ recovery was significantly decreased in TLM-preloaded pancreata. Quality control revealed consistently high viability as determined using trypan-blue exclusion (>95%) or formazan production. Compared with unstored organs (2.47 +/- 0.36; P < .05), glucose stimulation index was reduced in TLM-preloaded (1.48 +/- 0.15) and TLM-postloaded pancreata (1.81 +/- 0.20). Normoglycemia in diabetic nude mice transplanted with islets from TLM-preloaded pancreata was transient in contrast to sustained function in the other groups. CONCLUSIONS: Significant amounts of viable pig islets can be isolated after prolonged TLM preservation by reducing NP activity. Nevertheless, early enzyme administration prior to long-term storage deteriorates islet graft function.     

Optimization of neutral protease to collagenase activity ratio for islet of Langerhans isolation

AIM: The optimal neutral protease to collagenase activity ratio has not been determined for islet isolation. We evaluated a new highly purified collagenase that can be blended with predetermined amounts of neutral protease (NP). METHODS: Islets were isolated from 7 groups of Sprague-Dawley rats. In group I, collagenase type XI (Sigma) at 2 mg/mL, and, in group II, Liberase at 0.6 mg/mL (2.4 PZ- U/mL; Roche) were used as controls. In groups III to VII, collagenase NB1 0.6 mg/mL (2.4 PZ-U/mL; Serva Electrophoresis) was used with increasing amounts of added NP. The NP to collagenase activity ratio (DMC-U/PZ-U) increased from 0.5% in group III to 2.0% in group VII. RESULTS: Mean islet equivalent (IE) yields per rat were 1367, 1755, 597, 895, 1712, 1043, and 905 in groups I to VII. IE yields were maximal at DMC-U/PZ-U = 1.2%. Islet morphology was influenced by NP concentration with decreasing numbers of trapped islets and increasing numbers of fragmented islets as NP contents increased. Cytokine release, islet cell apoptosis, and in vitro function were significantly better in groups III to VII as compared with groups I and II. CONCLUSION: NP is a crucial additive to collagenase for islet isolation. Optimization of the NP to collagenase activity ratio (1.2% in this model) improves yields and morphology after islet isolation.     

Studies of the isolation and viability of human islets of Langerhans

Pancreas obtained from 34 adult human cadaver organ donors was divided into proximal and distal segments, and the duct to each segment was cannulated. Collagenase was injected into the proximal duct of 7 glands and into the distal duct of 7 others; the duct of the opposite segment was perfused with collagenase. The pancreas was then dispersed by teasing, trituration, and passage through filters. Perfused proximal and distal segments released 1461 +/- 287 and 2728 +/- 797 islets/g (+/- SEM) versus 710 +/- 149 (P less than 0.05) and 1950 +/- 636 after injection. Twenty other pancreases were perfused with collagenase warmed rapidly to 39 degrees C (n = 4) or warmed slowly to 37 degrees C (n = 6) or 39 degrees C (n = 10): the yield was 1625 +/- 632, 1320 +/- 116, and 2009 +/- 277 islets/g respectively. Total yields from the latter were 76 X 10(3) large (greater than 100 microns) and 85 X 10(3) small (less than 100 microns) islets with recoveries of 61% and 42%, respectively, after Ficoll density gradient purification. Histology showed highly purified islets. Perifusion with glucose elicited a biphasic release of insulin with the mean response (microU/islet/min) rising to a first peak of 0.5 and constant second phase secretion of 0.25, followed by a return to baseline. Reduced response was observed for islets from pancreas stored greater than 6 hr and tissue obtained from multiple centers. Less insulin was produced by freshly isolated islets, islets less than 100 microns, and after Ficoll separation. Secretion was similar for islets derived from proximal or distal segments. Perfusion of collagenase via the ducts of human pancreas improves islet isolation and Ficoll gradient separation yields highly purified islets. Important factors influencing insulin secretion are the source of donor tissue, cold storage of pancreas, Ficoll purification, islet size, and tissue culture.     

Degraded collagenase deteriorates islet viability

OBJECTIVE: The utilization of purified enzyme blends consisting of collagenase class I (CI) and II (CII) and neutral protease is an essential step for clinical islet isolation. Previous studies suggested that the use of enzyme lots containing degraded CI reduced islet release from human pancreata. The present study sought to assess the effect of degraded collagenase on islet function in vitro and posttransplantation. MATERIALS AND METHODS: Crude collagenase was chromatographically separated into CI, CII, and a mixture of degraded CI and CII isomers. Subsequently, classes were recombined to obtain a CII/CI ratio of 0.5. Rat islets were isolated utilizing neutral protease and 20 units of recombined collagenase containing either intact (Ci) or degraded isomers (Cd). RESULTS: Digestion time was reduced utilizing Cd (P < .001). The highest islet yield and lowest islet fragmentation were obtained with Ci (P < .01). Utilization of Cd corresponded to a reduction in viability and in vitro function (NS). Islet transplantation reversed hyperglycemia in diabetic nude mice, but revealed an absence of weight gain in recipients receiving islets isolated using Cd (P < .01). CONCLUSION: This study suggested that islet function posttransplantation is affected by degraded collagenase isomers. This finding has to be considered for the purification process of collagenase.     

Experimental islet isolation in porcine pancreas with new enzyme Liberase PI

The aim of this study was to investigate the results of 20 consecutive porcine islet isolations using a new enzyme Liberase PI. Twenty pancreata were procured for islet isolation, which was performed using modified Ricordi's method with Liberase PI. Quantitation of islet viability staining, insulin stimulation assay, intracellular insulin content/DNA, and in vivo transplantability into diabetic nude mice were examined for quality control. The results were compared between a high-yield group (>2500 IEQ/g pancreas) and a low-yield group (<2500 IEQ/g pancreas). Sufficient amount of purified islets (3000 IEQ/g pancreas) were obtained using the new brand enzyme Liberase PI. These islets showed good quality in structure and functions, which were demonstrated by in vitro and in vivo standard assays. Isolation index (IEQ/number) of the low-yield group was lower than that of high-yield group (0.75 vs 0.86), which means more fragmentation of islets in the low-yield group. There were no differences in function between the two groups. In conclusion, we obtained sufficient numbers of viable, functional islets from porcine pancreas using a new brand enzyme Liberase PI and low-temperature isolation technique. However, overdigestion of islets during the isolation remains to be overcome. Advance in porcine islet isolation technique will in the future make the porcine islet xenotransplantation a reality for the cure of diabetes mellitus.     

Characterization of collagenase blend enzymes for human islet transplantation

BACKGROUND: Efficient islet isolation represents a necessary requirement for successful islet transplantation as a treatment for type 1 diabetes. The choice of collagenase for pancreas digestion is critical for the isolation outcome, and Liberase is the most widely used enzyme, although large intra-batched variability in activity and efficiency has been observed. METHODS: The aim of this study was to characterize Liberase components and their relative role in pancreas digestion. Liberase batches were characterized by microelectrophoresis. RESULTS: By means of microelectrophoresis, we identified three main proteins each with different prevalences between batches. Two proteins were found to correspond to class I (CI) and one to class II (CII) collagenase. In a series of 163 islet isolations, we observed that the CII correlated with islet yield (P<0.001) and digestion time (P<0.001); additionally, CI directly correlated with purity (P=0.028). Finally, when CII and one of the CI isoforms were >50 percentile, 15 of 36 preparations were transplanted, with 27 of 127 transplanted in the other cases (P=0.013). CONCLUSION: These results represent an important step toward the characterization of enzymes, with the final aim of identifying key components for a standardized product.     

The use of iodixanol for the purification of rat pancreatic islets

Transplantation of pancreatic islets is a promising therapeutic treatment for type 1 diabetes mellitus. For clinical and experimental transplantation, a large number of pure pancreatic islets are required for transplantation. Thus, the improvement of islet isolation and purification techniques are crucial. In this context, iodixanol-based solution, successfully used for the purification of porcine islets, seems to be a possible alternative to Ficoll for purification of islets. The aim of this study was to test the efficacy of iodixanol compared with Ficoll density gradients for the purification of rat pancreatic islets. Twelve Wistar rats were used for isolation and purification of pancreatic islets. Pancreata were digested with Liberase R1 and islets purified by two gradients: Ficoll or iodixanol gradient. The number and the purity of the pancreatic islets were assessed. To analyze the response of isolated pancreatic islet to glucose challenge, in vitro experiments were performed by measuring the insulin concentration in the Supernatant. The results demonstrated that the iodixanol gradient provided a higher purity of pancreatic islets compared to the Ficoll gradient. In addition, the rat islet yield by iodixanol gradient was significantly higher compared to a Ficoll gradient (751 +/- 16 versus 464 +/- 19 pancreatic islets, respectively; P < .001). The viability of pancreatic islets isolated by an iodixanol gradient was confirmed by high glucose challenge, with more than twofold higher increase in insulin secretion. The present study demonstrated that iodixanol density gradient overcomes Ficoll density gradient, providing a greater number of pure and functional rat pancreatic islets.     

国产胶原酶在小鼠胰岛分离中的效果研究#br#

目的 研究一种国产胶原酶在小鼠胰岛分离中的分离效果,探索该胶原酶在胰岛分离中应用的 可行性。方法 将国产胶原酶分别配成不同浓度的胶原酶溶液和含中性蛋白酶的胶原酶的溶液,经胰管逆行灌注胶原酶的方法进行小鼠胰岛分离,采用Ficoll液对胰岛进行纯化,计数所得的胰岛细胞团,培养 6 h后检测活性,对最佳分离结果的胰岛做同系糖尿病小鼠的肾被膜下移植,监测术后血糖和进行组织学 检查,以进口Sigma胶原酶V为对照。结果 国产胶原酶在小鼠胰腺消化时间、所得胰岛数量和活性效果 上跟进口胶原酶V有一定差距（P＜0.01）,但含中性蛋白酶的国产胶原酶组在小鼠胰岛分离数量和当量上 与进口胶原酶组无差异（P＞0.05）,分离的胰岛在体内移植后降血糖效果与进口胶原酶组无差异（P＞0.05）。 结论 国产胶原酶结合中性蛋白酶可用于小鼠胰岛的分离。