Wellcome Open Research (Nov 2021)

A nonlinear and time-dependent leak current in the presence of calcium fluoride patch-clamp seal enhancer [version 2; peer review: 1 approved, 3 approved with reservations]

  • Chon Lok Lei,
  • Alan Fabbri,
  • Dominic G. Whittaker,
  • Michael Clerx,
  • Monique J. Windley,
  • Adam P. Hill,
  • Gary R. Mirams,
  • Teun P. de Boer

DOI
https://doi.org/10.12688/wellcomeopenres.15968.2
Journal volume & issue
Vol. 5

Abstract

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Automated patch-clamp platforms are widely used and vital tools in both academia and industry to enable high-throughput studies such as drug screening. A leak current to ground occurs whenever the seal between a pipette and cell (or internal solution and cell in high-throughput machines) is not perfectly insulated from the bath (extracellular) solution. Over 1 GΩ seal resistance between pipette and bath solutions is commonly used as a quality standard for manual patch work. With automated platforms it can be difficult to obtain such a high seal resistance between the intra- and extra-cellular solutions. One suggested method to alleviate this problem is using an F− containing internal solution together with a Ca2+ containing external solution — so that a CaF2 crystal forms when the two solutions meet which ‘plugs the holes’ to enhance the seal resistance. However, we observed an unexpected nonlinear-in-voltage and time-dependent current using these solutions on an automated patch-clamp platform. We performed manual patch-clamp experiments with the automated patch-clamp solutions, but no biological cell, and observed the same nonlinear time-dependent leak current. The current could be completely removed by washing out F− ions to leave a conventional leak current that was linear and not time-dependent. We therefore conclude fluoride ions interacting with the CaF2 crystal are the origin of the nonlinear time-dependent leak current. The consequences of such a nonlinear and time-dependent leak current polluting measurements should be considered carefully if it cannot be isolated and subtracted.