Diffractive bifocal lens designs

Modifying the number, width, depth, and shape of the echelettes in a diffractive bifocal lens will influence the image intensity and quality within the zero, first, and higher order images. By appropriately varying these parameters optimal bifocal lens designs may be achieved.     

Transit compartments versus gamma distribution function to model signal transduction processes in pharmacodynamics

Delayed effects for pharmacodynamic responses can be observed for many signal transduction processes. Three approaches are summarized in this report to describe such effects caused by cascading steps: stochastic process model, gamma distribution function, and transit compartment model. The gamma distribution function, a probability density function of the waiting time for the final step in a stochastic process model, is a function of time with two variables: number of compartments N, and the expected number of compartments occurring per unit time k. The parameter k is equal to 1/tau, where tau is the mean transit time in the stochastic process model. Effects of N and k on the gamma distribution function were examined. The transit compartment model can link the pharmacokinetic profile of the tested compound, receptor occupancy, and cascade steps for the signal transduction process. Time delays are described by numbers of steps, the mean transit time tau, and the amplification or suppression of the process as characterized by a power coefficient gamma. The effects of N, tau, and gamma on signal transduction profiles are shown. The gamma distribution function can be utilized to estimate N and k values when the final response profile is available, but it is less flexible than transit compartments when dose-response relationships, receptor dynamics, and efficiency of the transduction process are of concern. The transit compartment model is useful in pharmacokinetic/pharmacodynamic modeling to describe precursor/product relationships in signal transduction process.     

Degradation of gamma D- and gamma s-crystallins in human lenses

Debates within nursing can take the form of useful discussion and critique or verbal conflict generated from inflexible paradigm positions intolerant of differing stances perceived to be of no value. It is suggested that the most profitable process is debate that generates understanding of the strengths and limitations of various tools and techniques and helps identify suitable usage rather than uncritical advocacy or outright rejection. Suggested uses will thus themselves become subject to further debate and practitioners will be encouraged to adopt a use that suits their practice setting and role. The quantitative-qualitative research debate, criticisms of the nursing process and nursing models and reflective practice are examined. Dogmatic positions are highlighted and uses that are potentially controversial are identified.     

gamma-Aminobutyric acid type A receptors in the rat brain can contain both gamma 2 and gamma 3 subunits, but gamma 1 does not exist in combination with another gamma subunit

Antibodies specific for the gamma 1, gamma 2, and gamma 3 subunits of the gamma-aminobutyric acid (GABA)A receptor have been used to probe the composition of naturally occurring GABAA receptors in the rat brain. Most GABAA receptors contain at least one of these three subunits. The percentage of each, determined by immunoprecipitation of [3H]muscimol binding, was 11 +/- 1%, 59 +/- 3%, and 14 +/- 2% for gamma 1, gamma 2, and gamma 3 subunits, respectively. Receptors containing gamma 2 or gamma 3 subunits were labeled by benzodiazepine site ligands with high affinity, whereas gamma 1-containing receptors could be labeled only by [3H]muscimol. Receptors immunoprecipitated by anti-gamma 2 or anti-gamma 3 antibodies were labeled with [3H]Ro 15-1788 with similar affinities (Kd for anti-gamma 2-immunoprecipitated receptors, 1.9 nM; Kd for anti-gamma 3-immunoprecipitated receptors, 1.7 nM). Immunoprecipitation or Western blot analysis of GABAA receptors solubilized from rat cerebellar or whole-brain preparations indicated that gamma 1 was not present coassembled with any other gamma subunit. Western blot analysis of receptors purified on alpha-specific immunoaffinity resins showed that gamma 1 was predominantly assembled with the alpha 2 subunit. Some GABAA receptors may contain more than one type of gamma subunit. Quantitative immunoprecipitation and Western blot analysis both indicated that gamma 2 and gamma 3 subunits can exist in the same receptor complex. A large proportion of GABAA receptors immunopurified on a gamma 3 affinity resin also appeared to contain a gamma 2 subunit. In contrast, when receptors were purified on a gamma 2 affinity resin a small proportion also appeared to contain a gamma 3 subunit. We conclude that most gamma 1-containing receptors have no other gamma subunit in the same receptor complex but some GABAA receptors contain both gamma 2 and gamma 3 subunits.