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.

Adjustment of the ratio between collagenase class II and I improves islet isolation outcome.

BACKGROUND: Previous studies have clarified the distinct roles of collagenase class I (ccI) and class II (ccII) in enzymatic release of islets from pancreatic tissue. The present study sought to enhance the limited knowledge about the optimal ratio between collagenase classes. METHODS: Rat islets were isolated utilizing 0.4 DMC-U of neutral protease and 20 PZ-U of fractionated NB-1 collagenase recombined to obtain a ccII/I ratio of 0.5, 1.0, and 1.5. Quality control included assessment of yield (islet equivalents), trypan-blue exclusion, insulin release during static glucose incubation, and transplant function in diabetic nude mice. Data are expressed as mean values +/- SEM. RESULTS: Digestion time was only minimally influenced by different ccII/I ratios. The highest islet yield (P < .05) was obtained using a ccII/I ratio of 1.0. Purity and glucose stimulation index were only marginally affected by different ccII/I ratios. A significant loss of islet viability after 24-hour culture (P < .05) was observed only in islets isolated by means of a ccII/I ratio of 0.5 and 1.5 but not 1.0. Transplantation into diabetic nude mice revealed sustained islet graft function in all experimental groups. CONCLUSIONS: The present study indicates that the ratio between ccII and ccI is of significant relevance for optimizing islet yield and viability.

The ratio between class II and class I collagenase determines the amount of neutral protease activity required for efficient islet release from the rat pancreas.

UNLABELLED: Previous investigations clearly showed that the successful release of islets from the pancreas is mediated by both neutral protease (NP) and collagenase, consisting of subclasses I and II showing different capacities to cleave islets from the pancreas. Since no informations about the optimal ratio between class II and class I collagenase (II/I-ratio) are available yet, the present study sought to evaluate the efficient range for the II/I-ratio. METHODS: Following intraductal pancreas collagenase distension, rat islets were isolated utilizing 20 PZ-U Serva collagenase NB 1 and 1.0 or 0.4 DMC-U NP. After purification we determined the islet yield (IEQ), viability (trypan-blue exclusion) and function in diabetic nude mice. RESULTS: At 1.0 DMC-U NP, a II/I-ratio of 2.6, 1.5 or 0.7 yielded 2200 +/- 280, 2185 +/- 420, and 2205 +/-90 IEQ, respectively (ns). Viability varied between 70% and 80% (ns). Digestion time was significantly lowest (P < .05) using a II/I-ratio of 0.7. Utilization of 0.4 DMC-U NP resulted in a viability of >98% among all experimental groups (P < .001 vs 1.0 DMC-U). Islet yield decreased at a II/I-ratio of 2.6 (1520 +/- 120 IEQ, P < .05) and 1.5 (1780 +/- 130 IEQ, ns), but not at 0.7 (2310 +/- 160 IEQ, ns). Again, digestion time was lowest (P < .001) using a II/I- ratio of 0.7. Transplantation into diabetic nude mice demonstrated islet function in all experimental groups. CONCLUSIONS: NP significantly affects islet viability. This study indicates that the minimal amount of NP required for efficient islet cleavage depends on the II/I-ratio.