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A metal-oxide-semiconductor field-effect transistor with a 20-nm channel length (1990)

Hartstein, A. ; Albert, N. F. ; Bright, A. A. ; [et al.]

[S.l.] : American Institute of Physics (AIP)

Journal of Applied Physics 68 (1990), S. 2493-2495

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ISSN: 1089-7550

Source: AIP Digital Archive

Topics: Physics

Notes: We have fabricated a Si metal-oxide-semiconductor field-effect transistor with a 20-nm channel length using a novel step/edge technique. An Al gate is evaporated onto a step in the SiO2 gate oxide. A second Al gate, separated from the first by a plasma-enhanced chemical-vapor-deposited SiO2 layer, provides inversion layer extensions of the source and drain contacts. Electrical conductance measurements indicate a channel length approximately equal to the fabricated gate length.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.346512

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Regional myocadial blood flow and cardiac mechanics in dog hearts with CO2 laser-induced intramyocardial revascularization (1990)

Hardy, R. I. ; James, F. W. ; Millard, R. W. ; [et al.]

Springer

Basic research in cardiology 85 (1990), S. 179-197

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ISSN: 1435-1803

Keywords: myocardial ischemia ; revascularization ; laser ; systolicperfusion

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Laser-induced intramyocardial revascularization (LIR) has been used to promote direct communications between blood within the ventricular cavity and that of the existing myocardial vasculature in an attempt to increase perfusion in patients with ischemic heart discase. This study was conducted to measure the effects of LIR channels on regional myocardial flood flow (microspheres), cardiac mechanics (sonomicrometers), and myocardial tissue pressures in 18 dogs. Under baseline hemodynamic conditions (mean HR=165.2±11.4 bpm, LVP=123.6±22.9/4.0±1.8 mmHg, AoP=112.8±27.1/77.0±22.5 mmHg), myocardial blood flow in laser-treated tissue (mean =1.11±.10 cc/min/gm before laser; .71±.19 cc/min/gm after laser) was reduced as compared to blood flow in control tissue (mean=1.12±.15 cc/min/gm before laser; 1.25±.22 cc/min/gm after laser). Regional myocardial systolic shortening (11.32%±3.82% before laser; 7.49%±2.86% after laser) was decreased by 33%. During simultaneous reversible ligation of the LAD and LCCA for 2 min, when intramyocardial channels represented the only tissue access for the injected microspheres, blood flow in laser-treated tissue was not increased above that of the control non-lasered tissue. However, regional blood flow was greater in laser-treated ischemic tissue (mean=.61±.12 cc/min/gm) than in untreated ischemic areas (mean=.04±.03 cc/min/gm) when left ventricular pressure (LVP) was acutely elevated (mean SLVP=207.0±16.1 mmHg). Using these measurements, a model is proposed to predict regional systolic pressure gradients between the left ventricular cavity and coronary intramyocardial vasculature required to permit restoration of blood flow to ischemic myocardium. We conclude that improved perfusion via laser-induced intramyocardial channels does not occur in otherwise normal myocardium exposed to acute coronary ligation and only small improvements in perfusion are noted when LVP is significantly elevated. Consideration of further clinical application of this approach is seriously cautioned awaiting additional experimental studies.