Characterization of intracellular pH regulation in the guinea‐pig ventricular myocyte

Leem, Chae Hun; Lagadic‐Gossmann, Dominique; Vaughan‐Jones, Richard D.

doi:10.1111/j.1469-7793.1999.0159z.x

Cited by 235 publications

(375 citation statements)

References 50 publications

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“…; Grabe & Oster 2001). In this section, we describe the elements of a dynamic model for pH buffering, proton transport and associated model components developed by Leem & VaughanJones (1998) and Leem et al (1999), and their integration with existing cell models to provide a simulation study of pH regulation in cardiac myocytes.…”

Section: Modelling Ph Regulationmentioning

confidence: 99%

“…Typically, the proton buffering power in the myocyte is of the order of bZ20-90 mM per pH unit. This comprises (at least) two distinct intrinsic buffers (Leem et al 1999) where, from the Henderson-Hasselbalch equation, b i ðpH i Þ Z ln 10 !10 ðKpH i Þ 1 C ½B 1 !10 pK 1 ð1 C 10 pK 1 KpH i Þ 2 C ½B 2 !10 pK 2 ð1 C 10 pK 2 KpH i Þ 2 ! ; ð5:3Þ…”

Section: (A ) Bufferingmentioning

confidence: 99%

“…The processes regulating pH have been modelled in a variety of tissue and cell types in which pH regulation plays an important role, including heart (Ch'en et al 1998; Leem et al 1999), nerve cells (Boron & De Weer 1976) and pancreatic ductal epithelium (Sohma et al 1996(Sohma et al , 2000, and in subcellular compartments, including intracellular organelles which maintain an acidic interior (such as lysosome, endocytic and secretory organelles, etc. ; Grabe & Oster 2001).…”

Section: Modelling Ph Regulationmentioning

confidence: 99%

“…(b ) Acid transporters Leem et al (1999) have performed detailed and comprehensive measurements of transmembrane proton fluxes with varying intracellular pH under a variety of acid and base loading conditions in order to characterize the pH-dependence of the four transporter fluxes. Using a variety of pharmacological agents and ligand conditions, they were able to dissect out the contributions to net proton transport of the four individual proteins.…”

Section: (A ) Bufferingmentioning

confidence: 99%

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Acidosis in models of cardiac ventricular myocytes

Crampin

Smith

Langham

et al. 2006

Phil. Trans. R. Soc. A.

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The effects of acidosis on cardiac electrophysiology and excitation-contraction coupling have been studied extensively. Acidosis decreases the strength of contraction and leads to altered calcium transients as a net result of complex interactions between protons and a variety of intracellular processes. The relative contributions of each of the changes under acidosis are difficult to establish experimentally, however, and significant uncertainties remain about the key mechanisms of impaired cardiac function.In this paper, we review the experimental findings concerning the effects of acidosis on the action potential and calcium handling in the cardiac ventricular myocyte, and we present a modelling study that establishes the contribution of the different effects to altered Ca 2C transients during acidosis. These interactions are incorporated into a dynamical model of pH regulation in the myocyte to simulate respiratory acidosis in the heart.

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Section: Modelling Ph Regulationmentioning

confidence: 99%

Section: (A ) Bufferingmentioning

confidence: 99%

Section: Modelling Ph Regulationmentioning

confidence: 99%

Section: (A ) Bufferingmentioning

confidence: 99%

See 2 more Smart Citations

Acidosis in models of cardiac ventricular myocytes

Crampin

Smith

Langham

et al. 2006

Phil. Trans. R. Soc. A.

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“…Intracellular pH, Na + , and Ca 2+ in the heart are regulated by several ion transporters, such as Na + -H + exchanger (NHE), Na-HCO 3 cotransporter (NBC), Na + -Ca 2+ exchanger (NCX), Cl-HCO 3 exchanger, and ATP-dependent H + pump (Leem et al, 1999). Of these transporters, the Na + -H + exchanger (NHE) is a dominant ion transporter in restoration of intracellular pH during ischemia and reperfusion and acts overloading intracellular Na + , which activates Na + -Ca 2+ exchanger in the reverse mode and leads to intracellular Ca 2+ overload in the heart (Karmazyn, 2001).…”

Section: Introductionmentioning

confidence: 99%

Pharmacological profile of KR-33028, a highly selective inhibitor of Na+/H+ exchanger

Kim¹,

Kim²,

Oh³

et al. 2006

European Journal of Pharmacology

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Buffer‐free therapeutic antibody preparations provide a viable alternative to conventionally buffered solutions: From protein buffer capacity prediction to bioprocess applications

Bahrenburg

Karow

Garidel

2015

Biotechnology Journal

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Protein therapeutics, including monoclonal antibodies (mAbs), have significant buffering capacity, particularly at concentrations>50 mg/mL. This report addresses pH-related issues critical to adoption of self-buffered monoclonal antibody formulations. We evaluated solution conditions with protein concentrations ranging from 50 to 250 mg/mL. Samples were both buffer-free and conventionally buffered with citrate. Samples were non-isotonic or adjusted for isotonicity with NaCl or trehalose. Studies included accelerated temperature stability tests, shaking stability studies, and pH changes in infusion media as protein concentrate is added. We present averaged buffering slopes of capacity that can be applied to any mAb and present a general method for calculating buffering capacity of buffer-free, highly concentrated antibody liquid formulations. In temperature stability tests, neither buffer-free nor conventionally buffered solution conditions showed significant pH changes. Conventionally buffered solutions showed significantly higher opalescence than buffer-free ones. In general, buffer-free solution conditions showed less aggregation than conventionally buffered solutions. Shaking stability tests showed no differences between buffer-free and conventionally buffered solutions. "In-use" preparation experiments showed that pH in infusion bag medium can rapidly approximate that of self-buffered protein concentrate as concentrate is added. In summary, the buffer capacity of proteins can be predicted and buffer-free therapeutic antibody preparations provide a viable alternative to conventionally buffered solutions.

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Characterization of intracellular pH regulation in the guinea‐pig ventricular myocyte

Cited by 235 publications

References 50 publications

Acidosis in models of cardiac ventricular myocytes

Acidosis in models of cardiac ventricular myocytes

Pharmacological profile of KR-33028, a highly selective inhibitor of Na+/H+ exchanger

Buffer‐free therapeutic antibody preparations provide a viable alternative to conventionally buffered solutions: From protein buffer capacity prediction to bioprocess applications

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