Superoxide dismutase restores impaired histamine-induced increases in venular macromolecular efflux during diabetes mellitus

The goal of this study was to determine the role of oxygen radicals in impaired histamine-induced increases in venular macromolecular efflux from the hamster cheek pouch. We used intravital fluorescent microscopy and fluorescein isothiocyanate dextran (FITC-dextran; MW = 70K) to examine macromolecular extravasation from post-capillary venules in nondiabetic and diabetic (2-4 weeks after injection of streptozotocin) hamsters in response to histamine. Increases in extravasation of macromolecules were quantitated by counting venular leaky sites and by calculating clearance (ml/s x 10(-6)) of FITC-dextran-70K. In nondiabetic hamsters, superfusion with histamine (1.0 and 5.0 microM) increased venular leaky sites from 0 +/- 0 to 17 +/- 6 and 35 +/- 6 per 0.11 cm2, respectively. In addition, clearance of FITC-dextran-70K increased during superfusion with histamine. In contrast, superfusion with histamine did not increase the formation of venular leaky sites (0 +/- 0) or clearance of FITC-dextran-70K in diabetic hamsters. Next, we examined whether alterations in histamine-induced increases in macromolecular efflux in diabetic hamsters may be related to the production of oxygen radicals. We examined whether exogenous application of superoxide dismutase (150 U/ml) could restore impaired histamine-induced increases in macromolecular extravasation in diabetic hamsters. Application of superoxide dismutase did not alter histamine-induced increases in venular leaky sites or clearance of FITC-dextran-70K in nondiabetic hamsters. However, application of superoxide dismutase restored histamine-induced increases in leaky site formation and clearance of FITC-dextran-70K in diabetic hamsters towards that observed in nondiabetic hamsters. These findings suggest that oxygen radical formation appears to contribute to impaired macromolecular efflux in response to histamine during short-term diabetes mellitus.     

L-arginine prevents impaired endothelium-dependent cerebral arteriolar dilatation during acute infusion of nicotine.

Exogenous treatment with L-arginine has been shown to restore impaired nitric oxide synthase (NOS)-dependent dilatation of peripheral blood vessels during disease states. We have shown that nicotine impairs NOS-dependent arteriolar dilatation in the cerebral circulation. However, the role of L-arginine in impaired responses of cerebral arterioles during infusion of nicotine has not been examined. Thus the goal of the present study was to examine the role of L-arginine in nicotine-induced impairment of cerebral arteriolar reactivity. We measured the diameter of pial arterioles in response to NOS-dependent (5'-adenosine diphosphate [ADP] and acetylcholine) and NOS-independent (nitroglycerin) agonists before and after infusion of vehicle or nicotine (2 microg/kg/min intravenously for 30 min followed by a maintenance dose of 0.35 microg/kg/min) in the absence or presence of L-arginine (10(-3) M). We found that topical application of L-arginine to cerebral microvessels during infusion of nicotine could prevent impaired NOS-dependent vasodilatation. We suggest that exogenous L-arginine may have a beneficial role in preventing cerebral microvascular dysfunction during exposure to nicotine.     

Kinetic analysis of the radiation polymerization of methyl methacrylate–kaolin clay composites

In the first of a two-part series, a kinetic study has been made on the effects of gamma rays (⁶⁰Co) in air and inert gas on the polymerization of a 50:50 weight-mixture methyl methacrylate (MMA)–kaolin clay system. The effect of dose rate (7.35–24.9 rads/sec), temperature (25° to 75°C), and total dose on the percentage conversion of monomer to polymer was studied. The rate of formation of polymer at 25°C in the composite system was found to be faster when compared to a bulk MMA system at the same dose rate. This acceleration showed that the clay had a catalytic effect on the formation of polymer. The effect decreased as temperature increased. Two types of poly(methyl methacrylate) (PMMA) were formed in the composite. One type was called homopolymer and could be removed from the composite by extraction with organic solvents. The other type was called inserted polymer and could only be removed by dissolving the clay matrix with hydrofluoric acid. The total polymer conversion was the summation of these two types of polymer formed. The kinetic analysis examined the orders of reaction and activation energies of the homopolymer, inserted polymer, and total polymer. The initial reaction orders of the homopolymer and total polymer based on dose were ?0.46 and ?0.49, respectively. These indicate a definite free-radical reaction. The reaction order of the inserted polymer was temperature dependent. The activation energies for the homopolymer and total polymer in both atmospheres were approximately 1 kcal/mole less than the bulk activation energy at the same conditions. The inserted polymer had an activation energy which was dose rate dependent.     

Bounds on the electric field outside a radiating system--II

Bounds on the near electric field outside a rectangular aperture in a conducting ground plane are obtained and analyzed. The results are used to predict the power limitations (due to microwave breakdown) for such apertuares.     

Polymers from the hydrolysis of tetraethoxysilane

The hydrolysis of tetraethoxysilane was studied under various solvent and temperature conditions. A method was developed by which reaction rates can be measured even in the presence of alcohols other than ethanol. The structures of the resulting polymers were dependent upon the reaction conditions employed, those formed at high temperature being highly condensed materials.     

Complete electric field of the infinite slot antenna

The complete electric field of an aperture, with uniform excitation, in an infinite plane is derived and studied.     

Ultrawide-band coherent processing

In this paper, we develop an approach for estimating the ultrawide-band (UWB) radar signature of a target by using sparse subband measurements. First, we determine the parameters of an appropriate signal model that best fits the measured data. Next, the fitted signal model is used to interpolate between and extrapolate outside of the measurement subbands. Standard pulse-compression methods are then applied to provide superresolved range profiles of the target. The algorithm can automatically compensate for lack of mutual coherence between the radar subbands, providing the potential for UWB processing of real-world radar data collected by separate wide-band radars, because the processing preserves the phase distribution across the measured and estimated subbands, extended coherent processing can be applied to the UWB compressed radar pulses to generate superresolved radar images of the target. Applications of this approach to static test range and field data show promising results     

Characterization of poly(methyl methacrylate) from radiation-induced polymerization in the presence of a kaolin clay substrate

Two types of polymer are formed in the radiation-initiated polymerization of methyl methacrylate (MMA)–kaolin clay complexes. Homopolymer can be extracted from the complex by the use of organic solvents. Inserted polymer must be removed by dissolution of the polymer–clay complex with hydrofluoric acid. The polymers formed show no differences in structure (as determined by infrared analysis), had high molecular weights (1–5 × 10⁶), and had similar molecular weight distributions (as determined by GPC). The molecular weights of the homopolymer increased as temperature increased (25°–75°C), and dose rate decreased (24.9–7.35 rads/sec). The isotacticity of the polymers when compared to irradiated bulk polymer decreased as follows: inserted > homo > bulk. The compressive properties of the irradiated composite compared well with those of commercial bulk polymers. Degradation temperatures were 20° to 30°C higher for the composite than for the commercial chemically initiated bulk polymer.     

Activation of protein kinase C does not participate in disruption of the blood-brain barrier to albumin during acute hypertension

The blood-brain barrier minimizes the entry of macromolecules into brain tissue. During acute increases in arterial blood pressure, disruption of the blood-brain barrier occurs primarily in cerebral venules and veins. Mechanisms by which increases in cerebral venous pressure produce disruption of the blood-brain barrier during acute hypertension are not clear. The goal of this study was to determine the role of activation of protein kinase C in disruption of the blood-brain barrier during acute hypertension. We examined the microcirculation of the cerebrum in vivo. Permeability of the blood-brain barrier was quantitated by the formation of venular leaky sites and clearance of fluorescent-labeled albumin (FITC-albumin) before and during phenylephrine-induced acute hypertension. In addition, we examined changes in pial arteriolar and pial venular pressure before and during phenylephrine-induced acute hypertension. We compared responses of the blood-brain barrier to acute hypertension in control (untreated) rats and in rats treated with inhibitors of protein kinase C; calphostin C (0.1 microM) or sphingosine (1.0 microM). Under control conditions, no venular leaky sites were visible and clearance of FITC-albumin was minimal in all groups. Phenylephrine infusion increased systemic arterial, pial arteriolar and pial venular pressures, and increased the formation of venular leaky sites and clearance of FITC-albumin by a similar magnitude in all groups. The findings of the present study suggest that inhibition of protein kinase C does not significantly alter the formation of venular leaky sites and/or clearance of FITC-albumin during acute hypertension. Thus, disruption of the blood-brain barrier during acute hypertension does not appear to be influenced by activation of protein kinase C.