Vascular access outcome with a dedicated vascular team based approach.

The objective of this study is to determine the impact of a dedicated vascular team in the early detection of complications and improvement of vascular access patency. A dedicated vascular access team comprised four dialysis nurses, a vascular access coordinator and led by a physician. They were assigned for the surveillance and care of all vascular accesses. The team presented problematic cases in the regular quality meeting with documentation of access blood flow, dynamic venous pressure, findings of hematoma, prolonged bleeding, swelling, low arterial pressures, steal syndrome, recirculation studies and dialysis adequacy. In case of failed recirculation or persistently elevated dynamic venous pressure, further evaluation was done either a fistulogram or review by a vascular surgeon. A total of 226 problematic vascular access cases were detected during the study (January 2014 to October 2017). The majority were in 41-70 years age group. A total of 248 referrals were given. Two hundred cases were referred for fistulogram, but it was performed in 188 patients. Vascular access stenosis was detected in 153 patients (81.3%) and angioplasty was performed in 137 (89.5%) of these patients. Fifteen (9.8%) patients were managed conservatively and one patient refused angioplasty. The 15 cases managed conservatively continued to work normally. One patient who refused to angioplasty later clotted his fistula during the follow-up period. Out of 41 cases who were totally noncompliant to referral, nine (22%) clotted their fistula during the follow-up period. In 12 cases in whom fistulogram was requested, but the request was declined by the primary hospital, five patients (41.6%) clotted their fistulas. Subgroup analysis showed that in patients who had both failed recirculation and high venous pressure, the prevalence of stenosis was 90% and angioplasty was performed in 94.4%. In patients who had failed recirculation and low arterial pressure, stenosis was detected in 85.7% and angioplasty was performed in 100% of cases. A dedicated vascular team approach for the care of dialysis vascular access helps in early identification of complications and improve vascular access outcome.

ATP-sensitive potassium channels and efaroxan-induced insulin release in the electrofusion-derived BRIN-BD11 beta-cell line.

The properties of ATP-sensitive K+ (K(ATP)) channels were explored in the electrofusion-derived, glucose-responsive, insulin-secreting cell line BRIN-BD11 using patch-clamp techniques. In intact cells, K(ATP) channels were inhibited by glucose, the sulfonylurea tolbutamide, and the imidazoline compounds efaroxan and phentolamine. Each of these agents initiated insulin secretion and potentiated the actions of glucose. K(ATP) channels were blocked by ATP in a concentration-dependent manner and activated by ADP in the presence of ATP. In both intact cells and excised inside-out patches, the K(ATP) channel agonists diazoxide and pinacidil activated channels, and both compounds inhibited insulin secretion evoked by glucose, tolbutamide, and imidazolines. The mechanisms of action of imidazolines were examined in more detail. Pre-exposure of BRIN-BD11 cells to either efaroxan or phentolamine selectively inhibited imidazoline-induced insulin secretion but not the secretory responses of cells to glucose, tolbutamide, or a depolarizing concentration of KCl. These conditions did not result in the loss of depolarization-dependent rises in intracellular Ca2+ ([Ca2+]i), K(ATP) channel operation, or the actions of either ATP or efaroxan on K(ATP) channels. Desensitization of the imidazoline receptor following exposure to high concentrations of efaroxan, however, was found to result in an increase in SUR1 protein expression and, as a consequence, an upregulation of K(ATP) channel density. Our data provide 1) the first characterization of K(ATP) channels in BRIN-BD11 cells, a novel insulin-secreting cell line produced by electrofusion techniques, and 2) a further analysis of the role of imidazolines in the control of insulin release.

Engineering a glucose-responsive human insulin-secreting cell line from islets of Langerhans isolated from a patient with persistent hyperinsulinemic hypoglycemia of infancy.

Persistent hyperinsulinemic hypoglycemia of infancy (PHHI) is a neonatal disease characterized by dysregulation of insulin secretion accompanied by profound hypoglycemia. We have discovered that islet cells, isolated from the pancreas of a PHHI patient, proliferate in culture while maintaining a beta cell-like phenotype. The PHHI-derived cell line (NES2Y) exhibits insulin secretory characteristics typical of islet cells derived from these patients, i.e. they have no K(ATP) channel activity and as a consequence secrete insulin at constitutively high levels in the absence of glucose. In addition, they exhibit impaired expression of the homeodomain transcription factor PDX1, which is a key component of the signaling pathway linking nutrient metabolism to the regulation of insulin gene expression. To repair these defects NES2Y cells were triple-transfected with cDNAs encoding the two components of the K(ATP) channel (SUR1 and Kir6.2) and PDX1. One selected clonal cell line (NISK9) had normal K(ATP) channel activity, and as a result of changes in intracellular Ca(2+) homeostasis ([Ca(2+)](i)) secreted insulin within the physiological range of glucose concentrations. This approach to engineering PHHI-derived islet cells may be of use in gene therapy for PHHI and in cell engineering techniques for administering insulin for the treatment of diabetes mellitus.

Elevation of cytosolic calcium by imidazolines in mouse islets of Langerhans: implications for stimulus-response coupling of insulin release.

1. Microfluorimetry techniques with fura-2 were used to characterize the effects of efaroxan (200 microM), phenotolamine (200-500 microM) and idazoxan (200-500 microM) on the intracellular free Ca2+ concentration ([Ca2+]i) in mouse isolated islets of Langerhans. 2. The imidazoline receptor agonists efaroxan and phentolamine consistently elevated cytosolic Ca2+ by mechanisms that were dependent upon Ca2+ influx across the plasma membrane; there was no rise in [Ca2+]i when Ca2+ was removed from outside of the islets and diazoxide (100-250 microM) attenuated the responses. 3. Modulation of cytosolic [Ca2+]i by efaroxan and phentolamine was augmented by glucose (5-10 mM) which both potentiated the magnitude of the response and reduced the onset time of imidazoline-induced rises in [Ca2+]i. 4. Efaroxan- and phentolamine-evoked increases in [Ca2+]i were unaffected by overnight pretreatment of islets with the imidazolines. Idazoxan failed to increase [Ca2+]i under any experimental condition tested. 5. The putative endogenous ligand of imidazoline receptors, agmatine (1 microM-1 mM), blocked KATP channels in isolated patches of beta-cell membrane, but effects upon [Ca2+]i could not be further investigated since agmatine disrupts fura-2 fluorescence. 6. In conclusion, the present study shows that imidazolines will evoke rises in [Ca2+]i in intact islets, and this provides an explanation to account for the previously described effects of imidazolines on KATP channels, the cell membrane potential and insulin secretion in pancreatic beta-cells.