Identification of susceptibility loci in a mouse model of KRASG12D-driven pancreatic cancer.

Genetic background affects susceptibility to pancreatic ductal adenocarcinoma in the Ela-KRAS(G12D) mouse model. In this model, KRAS oncogene expression is driven by an elastase promoter in acinar cells of the pancreas on an FVB/NTac (FVB) background [FVB-Tg(Ela-KRAS(G12D))] with the transgene carried on the Y chromosome. Through linkage analysis of crosses between the C57BL/6J (B6), BALB/cJ (BALB), and DBA/2J (D2) inbred strains of mice and resistant FVB-Tg(Ela-KRAS(G12D)), we have identified six susceptibility loci that affect mean preinvasive lesion multiplicity. Markers on chromosome 2 segregated with high tumor multiplicity in all three strains; these loci were designated Prsq1-3 (pancreatic ras susceptibility quantitative trait loci 1-3; combined F2 and N2 LOD(W), 6.0, 4.1, and 2.7, respectively). Susceptibility loci on chromosome 4, designated Prsq4 and Prsq5, were identified in crosses between FVB transgenic mice and B6 or BALB mice (combined F2 and N2 LOD(W), 3.6 and 2.9, respectively). A marker on chromosome 12 segregated with tumor multiplicity in a BALB × FVB-Tg(Ela-KRAS(G12D)) cross and was designated Prsq6 (LOD(W), ∼2.5). B6-Chr Y(FVB-Tg(Ela-KRASG12D)) and BALB-Chr Y(FVB-Tg(Ela-KRASG12D)) consomics, which carry the KRAS transgene on the FVB Y chromosome on an otherwise inbred B6 or BALB background, developed ∼4-fold (B6) and ∼10-fold (BALB) more lesions than FVB-Tg(Ela-KRAS(G12D)) mice. By 12 months of age, 10% of BALB-Chr Y(FVB-Tg(Ela-KRASG12D)) mice developed invasive carcinomas. Our findings provide evidence that regions of chromosomes 2, 4, and 12 influence the development and progression of pancreatic neoplasms initiated by an oncogenic allele of KRAS in mice.

Liposome-encapsulated oxymorphone hydrochloride provides prolonged relief of postsurgical visceral pain in rats.

Adequate pain control is necessary for optimal postsurgical recovery and humane treatment of laboratory and companion animals. Opioid drugs are currently the most potent analgesic agents available in human and veterinary medicine. Long-acting formulations of opioid drugs confer several important advantages over standard pharmaceutical preparations, especially for use in animals. A long-acting formulation of oxymorphone hydrochloride was produced by encapsulation into liposomes. Liposome-encapsulated (LE) oxymorphone was tested in a rat model of visceral postoperative pain. Rats were given one subcutaneous injection of LE oxymorphone (1.2 or 1.6 mg/kg of body weight) or standard oxymorphone (0.3 mg/kg) at the time of intestinal transection or resection. A single administration of LE oxymorphone hydrochloride was as effective for relief of postoperative pain in rats (P = 0.18), as were multiple (q4 h or q8 h) injections of 0.3 mg/kg of the standard pharmaceutical preparation. The rats given LE oxymorphone prior to intestinal resection also had significantly higher body weight at three and seven days after surgery than did rats that were given standard oxymorphone. In conclusion, LE oxymorphone was effective in treating visceral pain associated with intestinal surgery in rats. On the basis of body weight gain, rats treated with LE oxymorphone had improved recovery outcome, compared with rats treated with repeated injections of standard oxymorphone.

A single dose of liposome-encapsulated oxymorphone or morphine provides long-term analgesia in an animal model of neuropathic pain.

An extended-release formulation of oxymorphone was produced by encapsulation into liposomes, using a novel technique. Liposome-encapsulated morphine was produced, using a standard technique These preparations were tested in an animal model of neuropathic pain. Male Sprague-Dawley rats (approx. 300 g) were allotted to control (non-loaded liposomes) and treatment (liposome-encapsulated oxymorphone or morphine) groups. Drugs were administered subcutaneously to all rats immediately prior to sciatic nerve ligation. Thermal withdrawal latencies were measured at baseline and daily for seven days after sciatic nerve ligation. A second experiment involved subcutaneous administration of non-loaded liposomes, morphine, or oxymorphone to rats that did not undergo sciatic nerve ligation. Thermal withdrawal latencies in sciatic nerve-ligated rats given non-loaded liposomes decreased significantly by day four, with maximal decrease at day seven after surgery, indicating development of full hyperalgesia. In contrast, ligated rats given liposome-encapsulated morphine or liposome-encapsulated oxymorphone had no decrease in thermal withdrawal latency by day four, indicating that these long-acting preparations prevented development of hyperalgesia after a single injection. This treatment effect persisted to day seven. Non-ligated rats treated with vehicle or liposome-encapsulated morphine had no change in thermal withdrawal latencies. Non-ligated rats treated with liposome-encapsulated oxymorphone had a small, but significant increase in thermal withdrawal latency from day four through day seven. One subcutaneous injection of liposome-encapsulated oxymorphone or morphine was effective in preventing hyperalgesia in this pain model for up to seven days. These results suggest that liposome-encapsulation of oxymorphone offers a novel, convenient, and effective means to provide long-term analgesia.