Limitations of the whole cell patch clamp technique in the control of intracellular concentrations.

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Limitations of the whole cell patch clamp technique in the control of intracellular concentrations.

R T Mathias, I S Cohen and C Oliva

Department of Physiology and Biophysics, State University of New York, Stony Brook 11794.

ABSTRACT

Recent experimental studies (Pusch and Neher, 1988) and theoreticalstudies (Oliva et al., 1988) have found that the pipette tipis a significant barrier to diffusion in the whole cell patchclamp configuration. In this paper, we extend the theoreticalanalysis of fluxes between the pipette and cell to include transmembranefluxes. The general conclusions are: (a) within the pipette,ion fluxes are driven primarily by diffusion rather than voltagegradients. (b) At steady state there is a concentration differencebetween the bulk pipette and intracellular solution that isdescribed by delta c = jRp/Dp, where delta c = 1 mM for a flux,j = 1 fmol/s, through a pipette of resistance, Rp = 1 M omega,filled with a solution of resistivity, p = 100 omega --cm, givena solute diffusion coefficient, D = 10(-5) cm2/s. (c) The timeto steady state is always accelerated by membrane transport,regardless of the direction of transport. We apply our analysisto the measurement of transport by the Na/K pump and Na/Ca exchangerin cells from the ventricles of mammalian heart. We find thatthe binding curve for intracellular Na+ to the Na/K pump willappear significantly less steep and more linear if one doesnot correct for the concentration difference between intracellularand pipette Na+. Similar shifts in the binding curve for extracellularNa+ to the Na/Ca exchanger can occur due to depletion of intracellularCa(+)+ when the exchanger is stimulated. Lastly, in Appendixwe analyze the effects of mobile and fixed intracellular bufferson the movement of Ca(+)+ between the pipette and cell. Fixedbuffers greatly slow the time for equilibration of pipette andintracellular Ca(+)+. Mobile buffers act like a shuttle system,as they carry Ca(+)+ from pipette to cell then diffuse backwhen they are empty. Vigorous transport by the Na/Ca exchangerdepletes mobile buffered calcium, thus stimulating diffusionfrom the pipette to match the rate of Ca(+)+ transport. Moreover,we find that binding of Ca(+)+ to the exchanger can be affectedby the mobile buffer.

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