Storage stability of tagatose in buffer solutions of various composition

Dobbs, Cathleen M. Bell, Leonard N.,

January 2008

Thesis--Auburn University, 2008. / Abstract. Includes bibliographical references (p. 52-56).

Relationship Between Total Alkalinity, Conductivity, and Buffering Action of Natural Water

Sechriest, Ralph E.

January 1959

No description available.

Biology

Water

Buffer solutions

Buffering ability of several compounds in vitro, and the effect of a selected buffer combination on ruminal acid production in vivo

Herod, Edward L.

January 1978

Call number: LD2668 .T4 1978 H47 / Master of Science

Buffer solutions.

Cattle--Feeding and feeds.

Masters theses

HEPES Buffer Perfusate Alters Rabbit Lung Endothelial Permeability

Douglas, G. C., Swanson, J. A., Kern, D. F.

01 January 1993

N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES) has been shown to cause changes in cultured endothelial cells and smooth muscle function at concentrations from 5 to 25 mM. To determine whether HEPES also affects vascular permeability, the effects of two buffers, HEPES and phosphate, were compared in isolated perfused rabbit lungs. Hemodynamic parameters and vascular protein permeability-surface area products (PS) were measured after perfusion with the buffers. Endothelial permeability was measured for an anionic and a cationic albumin to assess the charge effects of the zwitterion buffer. With HEPES, there were no changes in vascular pressure or resistance but permeability was affected. Cationic albumin permeability increased with 12 mM HEPES (8.7(phosphate) → 30(12 mM HEPES) x ml · min-1 · g dry lung-1 x 10-2) as did the anionic albumin PS (2.7(phosphate) → 3.52(12 mM HEPES). The cationic PS returned to baseline (8.1(60 mM HEPES)) at 60 mM HEPES, but the anionic PS did not change from the 12 mM HEPES (4.01(60 mM HEPES)). In summary, we find that HEPES is not innocuous. Although hemodynamic parameters did not change, endothelial permeability was increased when HEPES was used at normal concentrations. Therefore, HEPES should be used with caution as a physiological buffer in perfused organ systems.

buffer solutions

endothelial permeability

lung endothelium

Properties of food and buffer solutions during high pressure processing in-situ measurement of density, compressibility, electrical conductivity and reaction volume /

Min, Stephen K.

January 2008

Thesis (Ph. D.)--Ohio State University, 2008. / Title from first page of PDF file. Includes bibliographical references (p. 124-132).

The influence of ionic strength on the kinetics of selected enzymes.

Chuntharpursat, Eulashini.

January 2005

pH studies are used to gain insight into chemical mechanisms of enzyme catalysed reactions. However, perhaps the most important practical point that is often overlooked in pH studies is control of the ionic strength of reaction mixtures at the various pH values. For example, cathepsins Band L were suspected to be involved in cancer invasion but pH vs activity profiles indicated that they were not active at the extracellular pH (pH 7.2). When these profiles were re-evaluated in buffers of constant ionic strength, as opposed to buffers of constant molarity, it was shown that the enzymes were indeed active at pH 7.2. Other enzymes have also been reported to be sensitive to ionic strength. These include neutrophil elastase, class sigma glutathione S-transferase and penicillin G-acylase amongst others. The effects of increasing ionic strength on the activity of six enzymes were investigated. a-Glucosidase (from bakers ' yeast), elastase (human leukocyte) and trypsin (bovine pancreatic), cathepsin L (sheep liver), cathepsin B (rabbit liver), fruit bromelain (pineapple fruit) were subjected to different ionic strength buffers and their activities and Km and Vmax were determined as a function of ionic strength. The influence of ionic strength on Ki values has not been previously reported and was also studied, using the interaction between chicken egg-white cystatin C and cathepsin L as a model. a-Glucosidase was found to have an ionic strength optimum and elastase showed increasing activity with an increase in ionic strength. Trypsin activity decreased with increasing ionic strength with a substrate containing a positively charged side chain in the P1 position, and an increase in activity with a substrate containing a hydrophobic group at the P1 position. Cathepsin B activity increased when acting on the substrate Z-Phe-ArgNHMec and decreased when acting on Z-Arg-Arg-NHMec, with increasing ionic strength. Bromelain showed an increase in activity with increasing ionic strength. Cathepsin L activity decreased at increasing ionic strength and the Ki values for the cathepsin L-cystatin C interaction increased with increasing ionic strength. The results obtained can be attributed to the nature of the specificity pockets involved in binding the substrate, effects on the catalytic mechanism of the enzyme or structural changes due to increasing ionic strength. These results show that the ionic strength is a significant variable and should be kept constant or at in vivo levels when assaying enzymes. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2005.

Ionic solutions.

Enzymes.

Enzyme kinetics.

Hydrogen-ion concentration.

Buffer solutions.

Enzyme inhibitors.

Hydrolases.

Proteinase.

Glucosidases.

Ions.

Theses--Biochemistry.