Reading List 305
Trainees and PIs from the Sensorimotor Superlab at Western University contribute to this reading list. Here are the articles that have interested us this week.
Enjoy!
—the superlab
1
Selective presynaptic inhibition of leg proprioception in behaving Drosophila
Dallmann CJ, Luo Y, Agrawal S, Mamiya A, Chou GM, Cook A, Sustar A, Brunton BW, Tuthill JC
Nature:1–9
2
Recurrent pattern completion drives the neocortical representation of sensory inference
Shin H et al.
bioRxiv:2023.06.05.543698
3
A comparison of movement-related neuronal activities in cerebellar- and basal ganglia-recipient regions of the macaque thalamus
Kase D, Zimnik AJ, Pearce T, Turner RS
bioRxiv:2025.09.12.675921
4
Transitions in dynamical regime and neural mode during perceptual decisions
Luo TZ, Kim TD, Gupta D, Bondy AG, Kopec CD, Elliott VA, DePasquale B, Brody CD
Nature:1–11
5
The dimensions of dimensionality
Roads BD, Love BC
Trends Cogn Sci 28:1118–1131
6
Discrete and sequential critical periods organise the development of task-specific sensorimotor circuits in mice
Andreoli L, Constantinescu AM, Garai A, Black CJ, Koch SC
bioRxiv:2025.09.18.676788
7
Arm position estimates derived from motor biases
Abishek K, Muzammall H, Lee H, Buneo CA
bioRxiv:2025.07.26.664535
8
Embodied sensorimotor control: computational modeling of the neural control of movement
Almani MN, John L, Jeff W, Shreya S
arXiv [q-bioNC]
9
A hardwired neural circuit for temporal difference learning
Campbell MG, Ra Y, Chen Z, Xu S, Burrell M, Matias S, Watabe-Uchida M, Uchida N
bioRxiv:2025.09.18.677203
10
Encoding of motor sequences in primate globus pallidus and motor cortex: Uniform preference for ordinal position
Harsch DR, Cox KM, Wright KKM, Rice PJ, Pasquerau B, Turner RS
bioRxiv:2025.09.15.676392
11
Neural mechanisms underlying the recovery of voluntary control of motoneurons after paralysis with spinal cord stimulation
Balaguer J-M et al.
Neuron
12
Multitasking recurrent networks utilize compositional strategies for control of movement
Lazzari J, Saxena S
bioRxiv:2025.09.10.675375
13
Optimal foraging requires coordinating decisions with movements
Saleri C, Gardechaux G, Foncelle A, Thura D
bioRxiv:2025.09.19.677254
14
Evidence for an active handoff between hemispheres during target tracking
Broschard MB, Roy JE, Brincat SL, Mahnke MK, Miller EK
J Neurosci:e0841252025
15
Can you learn not to respond to irrelevant motion while making fast arm movements?
Brenner E, de Jonge LM, Tiems NJJ, Rosenquist G, Wiggers T, Smeets JBJ, Crowe EM
PLoS One 20:e0332171
16
A mechanistic theory of planning in prefrontal cortex
Jensen KT, Doohan P, Sablé-Meyer M, Reinert S, Baram A, Akam T, Behrens TEJ
bioRxiv:2025.09.23.677709
17
EPFL-Smart-Kitchen-30: Densely annotated cooking dataset with 3D kinematics to challenge video and language models
Bonnetto A, Qi H, Leong F, Tashkovska M, Rad M, Shokur S, Hummel F, Micera S, Pollefeys M, Mathis A
arXiv [csCV]
18
Spinal dI3 neurons are involved in sustained motor adaptation elicited by low-threshold cutaneous afferents
Khan EU, Nasiri S, Chiasson SA, Couvrette LJ, Laliberte AM, Bui TV
bioRxiv:2025.09.22.677841
19
Arousal as a universal embedding for spatiotemporal brain dynamics
Raut RV, Rosenthal ZP, Wang X, Miao H, Zhang Z, Lee J-M, Raichle ME, Bauer AQ, Brunton SL, Brunton BW, Kutz JN
Nature:1–8
Archive
You can look at an archive of our previous posts here: https://superlab.ca
Disclaimer
Articles appear on this list because they caught our eye, but their appearance here is not necessarily an endorsement of the work. We hope that you find something on this list you might not otherwise have come across—but, as always, please read with a critical eye.