Direct and general support maintenance manual for truck, tractor, line haul, 52,000 GVWR, 6 x 4, M915A2 (NSN 2320-01-272-5029), truck, tractor, light equipment transporter (LET), 68,000 GVWR, 6 x 6 w/winch, M916A1 (NSN 2320-01-272-5028).

"June 1992."

Unit maintenance manual for truck, tractor, line haul, 52,000 GVWR, 6 x 4, M915A2 (NSN 2320-01-272-5029), truck, tractor, light equipment transporter (LET), 68,000 GVWR, 6 x 6 w/winch, M916A1 (NSN 2320-01-272-5028).

"June 1992."

Operator's manual : truck tractor, line haul, 50,000 GVWR, 6 x 4, M915 (NSN 2320-01-028-4395), truck tractor, light equipment transporter (LET), 56,000 GVWR, 6 x 6, w/winch, M916 (NSN 2320-01-028-4396), truck tractor, medium equipment transporter (MET), 75,000 GVWH, 8 x 6, w/winch, M920 (NSN 2320-01-028-4397) ....

Includes index.

Operator's manual : truck tractor, line haul, 50,000 GVWR, 6 x 4, M915 (NSN 2320-01-028-4395), truck tractor, light equipment transporter (LET), 56,000 GVWR, 6 x 6, w/winch, M916 (NSN 2320-01-028-4396), truck tractor, medium equipment transporter (MET), 75,000 GVWR, 8 x 6, w/winch, M920 (NSN 2320-01-028-4397) ....

"May 1980."

Operator's manual [microform] : truck tractor, line haul, 50,000 GVWR, 6 x 4, M915 (NSN 2320-01-028-4396), truck tractor, light equipment transporter (let), 56,000 CVWR, 6 x 6, w/winch, M916 (NSN 2320-01-028-4396), truck tractor, medium equipment transporter (met), 75,000 GVWR, 8 x 6, w/winch, M920 (NSN 2320-01-028-4397) : truck chassis, 75,000 BVWR, 8 x 6 for 20 ton dump truck, M917 (NSN 3806-01-028-4389), truck chassis, 56,000 GVWR, 6 x 8, for bituminous distributor truck, M918 (NSN 3805-01-028-4390), truck chassis, 75,000 GVWR, 8 x 6, for concrete mobile mixer truck, M819 (NSN 3856-01-4391).

"May 1980."

Operator's manual for truck, tractor, line haul, 52,000 GVWR, 6 x 4, M915A2 (NSN 2320-01-272-5029) and truck, tractor, light equipment transporter (LET), 68,000 GVWR, 6 x 6 w/winch, M916A1 (NSN 2320-01-272-5028).

"November 1991."

Future glucose-lowering drugs for type 2 diabetes

The multivariable and progressive natural history of type 2 diabetes limits the effectiveness of available glucose-lowering drugs. Constraints imposed by comorbidities (notably cardiovascular disease and renal impairment) and the need to avoid hypoglycaemia, weight gain, and drug interactions further complicate the treatment process. These challenges have prompted the development of new formulations and delivery methods for existing drugs alongside research into novel pharmacological entities. Advances in incretin-based therapies include a miniature implantable osmotic pump to give continuous delivery of a glucagon-like peptide-1 receptor agonist for 6-12 months and once-weekly tablets of dipeptidyl peptidase-4 inhibitors. Hybrid molecules that combine the properties of selected incretins and other peptides are at early stages of development, and proof of concept has been shown for small non-peptide molecules to activate glucagon-like peptide-1 receptors. Additional sodium-glucose co-transporter inhibitors are progressing in development as well as possible new insulin-releasing biological agents and small-molecule inhibitors of glucagon action. Adiponectin receptor agonists, selective peroxisome proliferator-activated receptor modulators, cellular glucocorticoid inhibitors, and analogues of fibroblast growth factor 21 are being considered as potential new approaches to glucose lowering. Compounds that can enhance insulin receptor and post-receptor signalling cascades or directly promote selected pathways of glucose metabolism have suggested opportunities for future treatments. However, pharmacological interventions that are able to restore normal β-cell function and β-cell mass, normalise insulin action, and fully correct glucose homoeostasis are a distant vision.

Total Synthesis of the Antitumor Macrolides, (+)-Brefeldin A and 4‑Epi-Brefeldin A from D‑Glucose: Use of the Padwa Anionic Allenylsulfone [3+2]-Cycloadditive Elimination To Construct Trans-Configured Chiral Cyclopentane Systems

A new synthesis of (+)-brefeldin A is reported via Padwa allenylsulfone [3+2]-cycloadditive elimination. Cycloadduct 13 was initially elaborated into iodide
27, which, following treatment with Zn, gave aldehyde 28 whose C(9) stereocenter was epimerized. Further elaboration into enoate 38 and Julia−Kocienski olefination with 5 subsequently afforded 39, which was deprotected at C(1) and O(15). Yamaguchi macrolactonization of the seco-acid thereafter afforded a macrocycle that underwent O-desilylation and inversion at C(4) to give (+)-brefeldin A following deprotection

Continuous intravenous infusion of glucose induces endogenous hyperinsulinaemia and lamellar histopathology in Standardbred horses

Endocrinopathic laminitis is frequently associated with hyperinsulinaemia but the role of glucose in the pathogenesis of the disease has not been fully investigated. This study aimed to determine the endogenous insulin response to a quantity of glucose equivalent to that administered during a laminitis-inducing, euglycaemic, hyperinsulinaemic clamp, over 48. h in insulin-sensitive Standardbred racehorses. In addition, the study investigated whether glucose infusion, in the absence of exogenous insulin administration, would result in the development of clinical and histopathological evidence of laminitis. Glucose (50% dextrose) was infused intravenously at a rate of 0.68 mL/kg/h for 48. h in treated horses (n = 4) and control horses (n = 3) received a balanced electrolyte solution (0.68 mL/kg/h). Lamellar histology was examined at the conclusion of the experiment. Horses in the treatment group were insulin sensitive (M value 0.039 ± 0.0012. mmol/kg/min and M-to-I ratio (100×) 0.014 ± 0.002) as determined by an approximated hyperglycaemic clamp. Treated horses developed glycosuria, hyperglycaemia (10.7 ± 0.78. mmol/L) and hyperinsulinaemia (208 ± 26.1. μIU/mL), whereas control horses did not. None of the horses became lame as a consequence of the experiment but all of the treated horses developed histopathological evidence of laminitis in at least one foot. Combined with earlier studies, the results showed that laminitis may be induced by either insulin alone or a combination of insulin and glucose, but that it is unlikely to be due to a glucose overload mechanism. Based on the histopathological data, the potential threshold for insulin toxicity (i.e. laminitis) in horses may be at or below a serum concentration of ∼200. μIU/mL.