Reproducibility ofin vivoelectrophysiological measurements in mice

  1. International Brain Laboratory
  2. Kush Banga
  3. Julius Benson
  4. Jai Bhagat
  5. Dan Biderman
  6. Daniel Birman
  7. Niccolò Bonacchi
  8. Sebastian A Bruijns
  9. Kelly Buchanan
  10. Robert AA Campbell
  11. Matteo Carandini
  12. Gaëlle A Chapuis
  13. Anne K Churchland
  14. M Felicia Davatolhagh
  15. Hyun Dong Lee
  16. Mayo Faulkner
  17. Berk Gerçek
  18. Fei Hu
  19. Julia Huntenburg
  20. Cole Hurwitz
  21. Anup Khanal
  22. Christopher Krasniak
  23. Christopher Langfield
  24. Guido T Meijer
  25. Nathaniel J Miska
  26. Zeinab Mohammadi
  27. Jean-Paul Noel
  28. Liam Paninski
  29. Alejandro Pan-Vazquez
  30. Noam Roth
  31. Michael Schartner
  32. Karolina Socha
  33. Nicholas A Steinmetz
  34. Karel Svoboda
  35. Marsa Taheri
  36. Anne E Urai
  37. Miles Wells
  38. Steven J West
  39. Matthew R Whiteway
  40. Olivier Winter
  41. Ilana B Witten
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Abstract

Understanding brain function relies on the collective work of many labs generating reproducible results. However, reproducibility has not been systematically assessed within the context of electrophysiological recordings during cognitive behaviors. To address this, we formed a multi-lab collaboration using a shared, open-source behavioral task and experimental apparatus. Experimenters in ten laboratories repeatedly targeted Neuropixels probes to the same location (spanning secondary visual areas, hippocampus, and thalamus) in mice making decisions; this generated a total of 121 experimental replicates, a unique dataset for evaluating reproducibility of electrophysiology experiments. Despite standardizing both behavioral and electrophysiological procedures, some experimental outcomes were highly variable. A closer analysis uncovered that variability in electrode targeting hindered reproducibility, as did the limited statistical power of some routinely used electrophysiological analyses, such as single-neuron tests of modulation by task parameters. Reproducibility was enhanced by histological and electrophysiological quality-control criteria. Our observations suggest that data from systems neuroscience is vulnerable to a lack of reproducibility, but that across-lab standardization, including metrics we propose, can serve to mitigate this.

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