Diabetic gastroparesis: Therapeutic options

Gastroparesis is a condition characterized by delayed gastric emptying and the most common known underlying cause is diabetes mellitus. Symptoms include nausea, vomiting, abdominal fullness, and early satiety, which impact to varying degrees on the patient’s quality of life. Symptoms and deficits do not necessarily relate to each other, hence despite significant abnormalities in gastric emptying, some individuals have only minimal symptoms and, conversely, severe symptoms do not always relate to measures of gastric emptying. Prokinetic agents such as metoclopramide, domperidone, and erythromycin enhance gastric motility and have remained the mainstay of treatment for several decades, despite unwanted side effects and numerous drug interactions. Mechanical therapies such as endoscopic pyloric botulinum toxin injection, gastric electrical stimulation, and gastrostomy or jejunostomy are used in intractable diabetic gastroparesis (DG), refractory to prokinetic therapies. Mitemcinal and TZP-101 are novel investigational motilin receptor and ghrelin agonists, respectively, and show promise in the treatment of DG. The aim of this review is to provide an update on prokinetic and mechanical therapies in the treatment of DG

Analytical solutions to zeroth-order dispersion relations of a cylindrical metallic nanowire

Zeroth-order complex dispersion relations of a cylindrical metallic nanowire have been solved out analytically with approximate methods. The analytical solutions are valid for the sections of the dispersion relations whose frequencies are close to the Surface Plasmon frequency. The back bending of the Surface Plasmon-Polaritons(SPPs) can be well described by the analytical solutions, confirming that the back bending is originated from the metal Ohmic loss. The utility of the back bending point in the dispersion relation for the measurement of the metallic Ohimc loss has also been suggested.Comment: 6pages, 3figure

A consultation on the optimization of controlled human malaria infection by mosquito bite for evaluation of candidate malaria vaccines.

Early clinical investigations of candidate malaria vaccines and antimalarial medications increasingly employ an established model of controlled human malaria infection (CHMI). Study results are used to guide further clinical development of vaccines and antimalarial medications as CHMI results to date are generally predictive of efficacy in malaria-endemic areas. The urgency to rapidly develop an efficacious malaria vaccine has increased demand for efficacy studies that include CHMI and the need for comparability of study results among the different centres conducting CHMI. An initial meeting with the goal to optimize and standardise CHMI procedures was held in 2009 with follow-up meetings in March and June 2010 to harmonise methods used at different centres. The end result is a standardised document for the design and conduct of CHMI and a second document for the microscopy methods used to determine the patency endpoint. These documents will facilitate high accuracy and comparability of CHMI studies and will be revised commensurate with advances in the field

A consultation on the optimization of controlled human malaria infection by mosquito bite for evaluation of candidate malaria vaccines.

Item does not contain fulltextEarly clinical investigations of candidate malaria vaccines and antimalarial medications increasingly employ an established model of controlled human malaria infection (CHMI). Study results are used to guide further clinical development of vaccines and antimalarial medications as CHMI results to date are generally predictive of efficacy in malaria-endemic areas. The urgency to rapidly develop an efficacious malaria vaccine has increased demand for efficacy studies that include CHMI and the need for comparability of study results among the different centres conducting CHMI. An initial meeting with the goal to optimize and standardise CHMI procedures was held in 2009 with follow-up meetings in March and June 2010 to harmonise methods used at different centres. The end result is a standardised document for the design and conduct of CHMI and a second document for the microscopy methods used to determine the patency endpoint. These documents will facilitate high accuracy and comparability of CHMI studies and will be revised commensurate with advances in the field