Table 1.
Cerebellar functional anatomy related to functions associated with the forward model and the sense of agency.
| Function | Article | Experimental design | Cerebellar region involved |
|---|---|---|---|
| Diedrichsen et al. (2005) | fMRI correlate of target error (unpredictable change in target location) | Lobules V, VI, VIII and dentate nucleus | |
| Detection of sensory prediction errors | fMRI correlate of target error (unpredictable change in target location) fMRI correlate of execution error (alteration of visual feedback) | Lobules V, VI, VIII and dentate nucleus | |
| Schlerf et al. (2012) | Error detection | Lobules V and VI | |
| Blakemore et al. (2001) | Correlation of cerebellar activity with the abnormal delay of sensory feedbacks | Border of lobule VI and crus II | |
| van Kemenade et al. (2019) | Correlation of cerebellar activity with the abnormal delay of sensory feedbacks | Lobule V | |
| Nahab et al. (2011) | Correlation with the loss of control | Left cerebellar tonsil, left cerebellar pyramid | |
| On-line motor control | Miall et al. (2007) | Cerebellar stimulation with TMS impairs on-line motor control | Lateral cerebellum |
| Sensory attenuation | Blakemore et al. (1998) | Decreased cerebellar activation in response to self-generated tactile stimulus | Right anterior cerebellar cortex |
| Brooks and Cullen (2013) | Electrophysiological recordings in the cerebellum of non-human primates suggest a role in the cancellation of self-produced afferences | ||
| Cao et al. (2017) | Cerebellar stimulation with TMS alters the cortical sensory attenuation of self-generated sounds | Lateral cerebellum | |
| Visuomotor adaptation | Bernard and Seidler (2013) | A Meta-analysis of fMRI and PET study exploring visuomotor adaptation | Lobule IV |
| Küper et al. (2014) | fMRI study of visuomotor adaptation | Lobule VIII and caudal dentate nucleus | |
| Tzvi et al. (2020) | fMRI study of visuomotor adaptation | Lobule VIII, crus II, lobule VI, crus I | |
| Galea et al. (2011) | tDCS over the cerebellum causes faster adaptation during visuomotor adaptation | Right cerebellar cortex | |
| Yavari et al. (2016) | tDCS over the cerebellum alters localization of the hand after a movement without visual feedback | Right cerebellar cortex | |
| Conditional learning | Carta et al. (2019) | In mice, cerebellar nuclei send projections to the VTA and modulate the reward pathway | Deep cerebellar nuclei |
| Rogers et al. (2011) | In mice, stimulation of the cerebellar nuclei triggers. Dopamine release in the medial prefrontal cortex | Dentate nucleus | |
| Heffley et al. (2018) | In mice, climbing fibers responses in the lateral cerebellum encode reward prediction | Lateral cerebellum | |
| Kostadinov et al. (2019) | In mice, the cerebellum encodes reward prediction | Lobule simplex | |
| Anticipation | Tesche and Karhu (2000) | MEG study exploring the event-related potential during sensory ommission | Lateral cerebellum + vermis |
| Cui et al. (2000) | Event-related during a delayed sequential finger movement task | Cerebellum lobules VI | |
| Sense of agency | Seghezzi et al. (2019) | A Meta-analysis of fMRI study exploring the sense of agency | Right cerebellum lobule VI |
| Zapparoli et al. (2020b) | fMRI study of the cerebral regions which activity correlates with the intentional binding | Cerebellum lobules IV and V |
Anatomical specifications of the different cerebellar structures involved in the references listed in the manuscript.