Publications

Lab Publications

1. Oor EE, Stanford TR, Salinas E (2023) Stimulus salience conflicts and colludes with endogenous goals during urgent choices. iScience 26:106253. [pdf] [doi]  

2. Seideman JA, Stanford TR, Salinas E (2022) A conflict between spatial selection and evidence accumulation in area LIP. Nat Commun 13:4463. [pdf] [doi]

3. Goldstein AT, Stanford TR, Salinas E (2022) Exogenous capture accounts for fundamental differences between pro- and antisaccade performance. eLife 11:e76964. [pdf] [doi] 

4. Salinas E, Stanford TR (2021) Under time pressure, the exogenous modulation of saccade plans is ubiquitous, intricate, and lawful. Curr Opin Neurobiol 70:154–172. [pdf] [doi]

5. Stanford TR, Salinas E (2021) Urgent decision making: resolving visuomotor interactions at high temporal resolution. Annu Rev Vis Sci 7:323–348. [pdf] [doi]

6. Salinas E, Steinberg BR, Sussman LA, Fry SM, Hauser CK, Anderson DD, Stanford TR (2019) Voluntary and involuntary contributions to perceptually guided saccadic choices resolved with millisecond precision. eLife 8:e46359. [pdf] [doi]

7. Scerra VE, Costello MG, Salinas E, Stanford TR (2019) All-or-none context dependence delineates limits of FEF visual target selection. Curr Biol 29:294–305. [pdf] [doi]

8. Seideman JA, Stanford TR, Salinas E (2018) Saccade metrics reflect decision-making dynamics during urgent choices. Nat Commun 9:2907. [pdf] [doi]

9. Salinas E, Stanford TR (2018) Saccadic inhibition interrupts ongoing oculomotor activity to enable the rapid deployment of alternate movement plans. Sci Rep 8:14163. [pdf] [doi]

10. Salinas E, Seideman JA, Stanford TR (2018) When the simplest voluntary decisions appear patently suboptimal. Behav Brain Sci 41:e240. [pdf] [doi]

11. Hauser CK, Zhu D, Stanford TR, Salinas E (2018) Motor selection dynamics in FEF explain the reaction time variance of saccades to single targets. eLife 7:e33456. [pdf] [doi] 

12. Costello MG, Zhu D, May PJ, Salinas E, Stanford TR (2016) Task dependence of decision- and choice-related activity in monkey oculomotor thalamus. J Neurophysiol 115:581–601. [pdf] [doi]

13. Salinas E, Scerra VE, Hauser CK, Costello MG, Stanford TR (2014) Decoupling speed and accuracy in an urgent decision-making task reveals multiple contributions to their trade-off. Front Neurosci 8:85. [pdf] [doi]

14. Salinas E, Stanford TR (2013) The countermanding task revisited: fast stimulus detection is a key determinant of psychophysical performance. J Neurosci 33:5668–5685. [pdf] [doi]

15. Costello MG, Zhu D, Salinas E, Stanford TR (2013) Perceptual modulation of motor — but not visual — responses in the frontal eye field during an urgent-decision task. J Neurosci 33:16394–16408. [pdf] [doi]

16. Stanford TR, Salinas E (2012) The potential impact of multisensory integration on perceptual decision making. In: The New Handbook of Multisensory Processes, BE Stein, ed., pp. 495–508 (Cambridge, MA: MIT Press). [pdf]

17. Shankar S, Massoglia DP, Zhu D, Costello MG, Stanford TR, Salinas E (2011) Tracking the temporal evolution of a perceptual judgment using a compelled-response task. J Neurosci 31:8406–8421. [pdf] [doi]

18. Salinas E, Shankar S, Costello MG, Zhu D, Stanford TR (2010) Waiting is the hardest part: comparison of two computational strategies for performing a compelled-response task. Front Comput Neurosci 4:153. [pdf] [doi]

19. Stanford TR, Salinas E (2010) Clocking perceptual processing speed: from chance to 75% correct in less than 30 milliseconds. Commun Integr Biol 3:287–289. [pdf] [doi]

20. Stanford TR, Shankar S, Massoglia DP, Costello MG, Salinas E (2010) Perceptual decision making in less than 30 milliseconds. Nat Neurosci 13:379–385. [pdf] [doi]

Publications by Emilio Salinas

For a full list, see the profile in Google Scholar or in ORCID.

Publications by Terry Stanford

For a full list, see the profile in Google Scholar.