In this paper, we describe an assay using radioactive rubidium (86Rb) efflux to screen functional human ether-a go-go-related gene (HERG) K+ channels in a high-throughput screening (HTS) format. This assay offers an alternative way to examine junctional interactions between chemical compounds and HERG K+ channels. Follow-up experiments and discussions were carried out to address a variety of factors that affect potency evaluation within the Rb efflux assay. Factors that can affect the assay results, such as assay time, efflux rate, and compound blocking kinetics, are discussed in detail. Our results provide some explanations for the variances of the assay results and offer some guidelines for using the Rb efflux assay to evaluate compound interactions with HERG K+ channels in the pharmaceutical industry.
New amino terminated oligoimides (AOIs) were prepared by the Michael addition reaction of various bismaleimide (1), namely, 1-(4-((4-((2, 5-dioxocyclopent-3 enylamino) methyl) cyclohexyl) methyl) cyclohexyl)-1, 6-dihydropyridine-2, 5-dione with excess of various diamines (2a-c). These AOIs were characterized by elemental analysis, FT-IR spectral studies and number average molecular weight estimated by non-aqueous conductometric titrations. AOIs were then treated with acrylol chloride and resultant acryl terminated oligoimides (AcOIs) samples were also characterized thermogravimetrically. Each of these AcOI was then combined with theN-phenyl maleimide (PM) in THF solvent. The resultant suspensions were then heated in the presence of azobisisobutyronitrile (AIBN) as an initiator. The AcOI and PM polymerized through double bond simultaneously and form interacting blends, which were analyzed thermogravimetrically. The glass fiber reinforced composites were fabricated by using the suspensions of the AcOI and PM. The composites of Interacting blends were analyzed for their mechanical, chemical and electrical properties.
Designing and evaluating a multiparticulate controlled release dosage form, to increase the efficacy of acyclovir (a selective antiherpes agent). Spray drying technique for microsphere production is compared with novel solvent evaporation-matrix erosion technique for variable drug loading in different concentration of ethyl cellulose. The microspheres were characterized for physicochemical properties. The microspheres sizes were ranged from 7-25 μm. The spray dried microspheres had better encapsulation efficiency (up to 91%) compared to that of novel solvent evaporation-matrix erosion technique microspheres. Scanning electron microscopy confirmed spherical geometry due to high cross-linking density. Differential scanning calorimetry, Fourier-transform infrared spectroscopy and x-ray diffraction studies showed chemical stability and intactness of entrapped drug in the microspheres. In vitro release of acyclovir from spray dried microspheres continued for longer period compared to novel solvent evaporation-matrix erosion method. Overall, the release studies depended on the concentration of ethyl cellulose, extent of drug loading, and the technique used to prepare microspheres. Thus, marked retardation of drug release may provide a useful effective anti-retroviral drug therapy.
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