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A physiological solvent for crystalline insulin (1981)

Lougheed, W. D. ; Fischer, U. ; Perlman, K. ; [et al.]

Springer

Diabetologia 20 (1981), S. 51-53

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ISSN: 1432-0428

Keywords: Insulin ; crystal ; dissolution ; bicarbonate ; pH

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Insulin is insoluble in water at physiological pH, but dissolves relatively rapidly in plasma. To quantify the ability of various solutions to dissolve crystalline insulin, a simple assay measuring dissolution time was developed. At pH 7.5 and room temperature, distilled water, 0.154 mol/1 NaCl, Ringer's lactate solution, and 5% albumin in 0.154 mol/1 NaCl did not dissolve insulin crystals within 30 min. Normal postprandial human plasma and a proteinfree cell culture medium dissolved insulin crystals within 3 to 8 min. This ability was inhibited by acid titration of the fluids to a stable pH of 6.30, at which point bicarbonate depletion could be implied. Repletion of bicarbonate did restore the ability of these solutions to dissolve insulin crystals, but back-titration to the initial pH with NaOH did not. The effect of sodium bicarbonate alone was strongly concentration dependent above 23 mmol/1. We suggest that the ability of physiological fluids to dissolve insulin crystals at normal pH depends on their bicarbonate content. The ability to dissolve insulin with a physiological solvent which prevents its reaggregation promises to facilitate its use in portable pumping systems.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00253817

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A physiological solvent for crystalline insulin (1981)

Lougheed, W. D. ; Fischer, U. ; Perlman, K. ; [et al.]

Springer

Diabetologia 21 (1981), S. 51-53

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Details

ISSN: 1432-0428

Keywords: Insulin ; crystal ; dissolution ; bicarbonate ; pH

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Insulin is insoluble in water at physiological pH, but dissolves relatively rapidly in plasma. To quantify the ability of various solutions to dissolve crystalline insulin, a simple assay measuring dissolution time was developed. At pH 7.5 and room temperature, distilled water, 0.154 mol/l NaCl, Ringer's lactate solution, and 5% albumin in 0.154 mol/l NaCl did not dissolve insulin crystals within 30 min. Normal postprandial human plasma and a protein-free cell culture medium dissolved insulin crystals within 3 to 8 min. This ability was inhibited by acid titration of the fluids to a stable pH of 6.30, at which point bicarbonate depletion could be implied. Repletion of bicarbonate did restore the ability of these solutions to dissolve insulin crystals, but back-titration to the initial pH with NaOH did not. The effect of sodium bicarbonate alone was strongly concentration dependent above 23 mmol/l. We suggest that the ability of physiological fluids to dissolve insulin crystals at normal pH depends on their bicarbonate content. The ability to dissolve insulin with a physiological solvent which prevents its raggregation promises to facilitate its use in portable pumping systems.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01789114

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Scanning near-field acoustic microscopy (1989)

Günther, P. ; Fischer, U. Ch. ; Dransfeld, K.

Springer

Applied physics 48 (1989), S. 89-92

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ISSN: 1432-0649

Keywords: 16.16d ; 43.35d

Source: Springer Online Journal Archives 1860-2000

Topics: Physics

Notes: Abstract Scanning near-field acoustic microscopy (SNAM) is a new method for imaging the topography of nonconducting surfaces at a potential lateral resolution in the sub-micron range. The basic element of this method is a distance sensor consisting of a sharply pointed vibrating tip, which is part of a high-Q quartz resonator driven at its resonance frequency. The decrease of the resonance frequency or of the amplitude of vibration when an object comes into the proximity of the tip serves as the important signal. The dependence of this signal on pressure and composition of the coupling gas shows that the hydrodynamic forces in the gas are responsible for the coupling between object and tip. The sensor is incorporated into a scanning device. Well-resolved line scans of a grating of 8 μm periodicity, a lateral resolution of 3 μm and a vertical resolution of 5nm have been achieved in our first experiments.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00694423

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