Driven by need, shaped by access: Heterogeneity in patient profiles and patterns of service utilization in patients with alcohol use disorders.

BACKGROUND: Patients with alcohol-use disorders (AUDs) are highly heterogenous and account for an increasing proportion of general medical hospital visits. However, many patients with AUDs do not present with severe medical or psychiatric needs requiring immediate attention. There may be a mismatch between some patients' needs and the available services, potentially driving re-admissions and re-encounters. The current study aims to identify subgroups of AUD patients and predict differences in patterns of healthcare service use (HSU) over time. METHODS: Latent class analysis (LCA) was conducted using hospital data incorporating sociodemographic, health behavior, clinical, and service use variables to identify subtypes of AUD patients, then class membership was used to predict patterns of HSU. RESULTS: Four classes were identified with the following characteristics: (1) Patients with acute medical injuries (30 %); (2) Patients with socioeconomic and psychiatric risk factors, (11 %); (3) Patients with chronic AUD with primarily non-psychiatric medical needs (18 %); and (4) Patients with primary AUDs with low medical-treatment complexity (40 %). Negative binomial models showed that Class 4 patients accounted for the highest frequency of service use, including significantly higher rates of emergency department reencounters at 30 days and 12 months. CONCLUSIONS: The profile and patterns of HSU exhibited by patients in class 4 suggest that these patients have needs which are not currently being addressed in the emergency department. These have implications for how resources are allocated to meet the needs of patients with AUDs, including those who make frequent visits to the emergency department without high acuity medical needs.

Carbonic anhydrase II-positive pancreatic cells are progenitors for both endocrine and exocrine pancreas after birth.

The regenerative process in the pancreas is of particular interest because diabetes results from an inadequate number of insulin-producing beta cells and pancreatic cancer may arise from the uncontrolled growth of progenitor/stem cells. Continued and substantial growth of islet tissue occurs after birth in rodents and humans, with additional compensatory growth in response to increased demand. In rodents there is clear evidence of pancreatic regeneration after some types of injury, with proliferation of preexisting differentiated cell types accounting for some replacement. Additionally, neogenesis or the budding of new islet cells from pancreatic ducts has been reported, but the existence and identity of a progenitor cell have been debated. We hypothesized that the progenitor cells are duct epithelial cells that after replication undergo a regression to a less differentiated state and then can form new endocrine and exocrine pancreas. To directly test whether ductal cells serve as pancreatic progenitors after birth and give rise to new islets, we generated transgenic mice expressing human carbonic anhydrase II (CAII) promoter: Cre recombinase (Cre) or inducible CreER(TM) to cross with ROSA26 loxP-Stop-loxP LacZ reporter mice. We show that CAII-expressing cells within the pancreas act as progenitors that give rise to both new islets and acini normally after birth and after injury (ductal ligation). This identification of a differentiated pancreatic cell type as an in vivo progenitor of all differentiated pancreatic cell types has implications for a potential expandable source for new islets for replenishment therapy for diabetes.

Normal relationship of beta- and non-beta-cells not needed for successful islet transplantation.

Islets are composed mostly of beta-cells, and therefore stem cell research has concentrated on generating purified beta-cells, neglecting the other endocrine cell types in the islet. We investigated the presence of endocrine non-beta-cells after islet transplantation. In addition, we studied whether the transplantation of pure beta-cells, in volumes similar to that used in islet transplantation, would suffice to reverse hyperglycemia in diabetic mice. Rat islets were dispersed and beta-cells were purified by fluorescence-activated cell sorting according to their endogenous fluorescence. After reaggregation, 600 islet equivalents of the purified beta-cell aggregates were implanted into diabetic SCID mice. In mice implanted with beta-cell-enriched aggregates, the hyperglycemia was reversed and good graft function over a 12-week period was observed with regard to glucose and insulin levels, glucose tolerance tests, and graft insulin content. The endocrine cell composition of the beta-cell-enriched aggregates remained constant; before and 12 weeks after transplantation, the beta-cell-enriched aggregates comprised 95% beta-cells and 5% endocrine non-beta-cells. However, islet grafts, despite originally having comprised 75% beta-cells and 25% endocrine non-beta-cells, comprised just 5% endocrine non-beta-cells after transplantation, indicating a loss of these cells. beta-Cell-enriched aggregates can effectively reverse hyperglycemia in mice, and transplanted intact islets are depleted in non-beta-cells. It is therefore likely that islet non-beta-cells are not essential for successful islet transplantation.

Timing and expression pattern of carbonic anhydrase II in pancreas.

In the search for genetic markers for assessing the role of duct cells in pancreas growth, we examined whether carbonic anhydrase II (CAII) has ductal cell specificity. We determined the distribution and timing of CAII expression in mouse pancreas from embryonic stage to adult. The pancreatic ducts only start expressing CAII at embryonic day (E) 18.5, with increases after birth. Around E15.5, glucagon-positive cells, but not insulin-positive cells, also express CAII, with further increases by adult. CAII expression was restricted to cells within ductal structures and glucagon-positive cells with no colocalization with any insulin-positive cells at any time. In the human pancreas, CAII expression is restricted to the ducts. Furthermore, the activity of a 1.6-kb fragment of the human promoter with Luciferase assays was moderately strong compared with the cytomegalovirus promoter in human pancreatic duct cell line (PANC-1). Thus, we believe that the CAII gene could serve as a useful pancreatic duct cell marker.