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On the measurement of hydrion concentration in some dairy products by means of Biilmann's quinhydrone electrode

Published online by Cambridge University Press:  27 March 2009

Vera Lester
Vera Lester
Affiliation:
From the University Institute of Hygiene1, Copenhagen.
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Extract

In the above I have shown the result of a series of measurements of the hydrion concentration in milk, cream, buttermilk and whey, partly employing Biilmann's Quinhydrone Electrode, partly Höber-Hasselbalch's Hydrogen Electrode.

The results of the tests agree.

Measurements have also been made in fresh and heated milk.

By these measurements I found no difference in the reaction or buffer action of the fresh and heated milk.

The Höber-Hasselblach method is rather slow. This is unfortunate as the reaction of the dairy products (especially whey) is apt to change when kept standing, even for a short time. By this method one also runs the risk of too high pH values owing to loss of carbon dioxide and it is therefore far from being an ideal one.

Biilmann's Quinhydrone Electrode is quick working, easy and simple and you avoid the above-mentioned sources of error. It is therefore to be preferred for measurements in the fluids in question. It is especially well adapted for titrations, as it makes possible a large number of measurements in a short time.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 14 , Issue 4 , October 1924 , pp. 634 - 641
Copyright
Copyright © Cambridge University Press 1924

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References

BIBLIOGRAPHY

(1)Bitlmann, E.. “Sur lyHydrogénation des Quinhydrones.” Ann. de Chimie, 9, XV. 1921.Google Scholar
Bitlmann, E.. “Oxidation and Reduction Potentials of Organic Compounds.” Trans. of the Faraday Soc. No. 57, 19, Part III, 1924.Google Scholar
Bitlmann, E.. “On the measurement of hydrogen-ion concentrations in soil by means of the Quinhydrone Electrode.” Journ. Agric. Sci. 14, Part II, 04, 1924.Google Scholar
Bitlmann, E. and Lund, H.. “Sur l'Éectrode à Quinhydrone.” Ann. de Chimie, 9, XVI, 1921.Google Scholar
(2)Veibel, S.. “The Quinhydrone Electrode as a Comparison Electrode.” Trans. of the Chem. Soc. 123, 2203, 1923.CrossRefGoogle Scholar
(3)Christensen, H. R. and Jensen, Tovborg. “Undersögelser vedrörende elektrometriske Metoder til Bestemmelse af Jordreaktionen.” With a summary in English. G.B.N.F. Copenhagen, 1923.Google Scholar
(4)van Dam, W.. “Des variations de l'acidité du lait dues au chauffage.” Rev. gén. du Lait, No. 12, 7, 1909.Google Scholar
(5)Milroy, . “The Reaction and Calcium Content of Milk as Factors in the Coagulation Process.” Biochem. Journ. 9, 1915.CrossRefGoogle ScholarPubMed
(6)Sørensen, S. P. L. and Jürgensen, E.. “Sur la coagulation des substances protComm. Lab. de Carlsberg, Coperihague, t. 10, 1913.Google Scholar