Der Einfluß von pH auf das freie Serum-Thyroxin und seine physiologische Bedeutung

 

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Zusammenfassung

Das freie, biochemisch wirksame Serum-Thyroxin bleibt im dynamischen Gleichgewicht mit dem proteingebundenen Thyroxin, welches als Reservoir wirkt. Der Thyroxin-Spiegel im Blut bleibt konstant unabhängig vom Tages/Nacht-Rhythmus, körperlichen und psychischen Belastungen. Meßbare Veränderungen des freien Serum-Thyroxins sowie der thyroxinbindenden Präalbumine konnten dagegen bei verschiedenen Stress-Situationen festgestellt werden.

Mittels Gleichgewichts-Dialyse (Equilibrium Dialysis) wird der Einfluß der Wasserstoffionenkonzentration auf die dialysierbare Thyroxin-Fraktion des Serums untersucht. Bei pH Verschiebung der Pufferlösung in saurer Richtung konnte eine Zunahme der dialysierbaren Thyroxin-Fraktion beobachtet werden.

Die elektrophoretischen Untersuchungen im Veronal-Natrium-Puffer pH 8,6 und 7,0 zeigten eine nicht signifikante Zunahme der Thyroxin-Bindung durch die Albumin-Fraktion im pH 7,0.

Die beobachteten Auswirkungen der Wasserstoffionenkonzentration auf die thyroxinbindenden Proteine des Serums und das freie Serum-Thyroxin stimmen überein mit den Literaturangaben.

Die Zusammenhänge zwischen dem pH des Serums, der Bindungskapazität der thyroxinbindenden Proteine sowie dem freien Serum-Thyroxin deuten auf eine physiologisch-regulatorische Rolle der Wasserstoffionenkonzentration.

The free, biochemically active serum thyroxine remains in dynamic equilibrium with the protein-bound thyroxine, which acts as a reservoir. The thyroxine level in blood remains constant independently of the diurnal rhythm, and physical and psychic stresses. Measurable changes of the free serum thyroxine and the thyroxine-binding prealbumins, on the other hand, were found in various stress situations. The influence of the hydrogen in concentration on the dialysable thyroxine fraction of the serum was investigated by means of equilibrium dialysis (dialysable fraction). An increase in the dialysable fraction was observed when the pH of the buffer solution changed in an acid direction.

Electrophoretic investigations in Veronal Sodium (Barbital) buffer, pH 8,6 and 7,0, showed an insignificant increase in thyroxine binding by the albumin fraction in pH 7,0. The observed effects of the hydrogen-ion concentration on the thyroxine-binding proteins and the free serum thyroxine agree with the literature. The relations between the pH of the serum and the binding capacity of the thyroxine-binding proteins and the free serum thyroxine indicate that the hydrogen-ion concentration acts as a physiological regulator.

La thyroxine libre du sérum reste en équilibre dynamique avec la fraction liée qui joue le rôle de réservoir. La thyroxinemie reste constante indépendamment du rythme nycthémeral et des stresses physiques et psychiques.

Des changements apréciables du taux de la thyroxine libre du sérum et de la fraction liée aux préalbumine on été découvertes dans plusieurs états de stress.

L’influence de la concentration d’ions hydrogène sur la fraction dialysable de la thyroxine du sérum est examinée par la méthode de la dialyse en équilibré.

Une augmentation de la fraction dialysable a été observée quand le PH de la solution tampon a viré du côté acide. Des investigations éléctrophorétiques dans du tampon de véronal de sodium PH 8,6 et 7,0 ont montré une augmentation insignifiante de la liaison de la thyroxine par la fraction albumin à PH 7,0.

Les effets observés de la concentration en ions hydrogène sur les portéines liant la thyroxine et la thyroxine libre du sérum concordent avec la litérature. Les relations entre le PH du sérum, la capacitée de liaison de la protéine à la thyroxine et la thyroxine libre du sérum montrent que la concentration en ion hydrogène agit comme un régulateur physiologique.

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