- Email: [email protected]
Does apraxia support spatial and kinematic or mirror neuron approaches to social interaction? A commentary on Binder et al. (2017)
Accepted Manuscript Does apraxia support spatial and kinematic or mirror neuron approaches to social interaction? A commentary on Binder et al. (2017) Arran T. Reader, Matteo Candidi PII:
S0010-9452(17)30366-0
DOI:
10.1016/j.cortex.2017.10.018
Reference:
CORTEX 2167
To appear in:
Cortex
Received Date: 2 June 2017 Revised Date:
22 August 2017
Accepted Date: 21 October 2017
Please cite this article as: Reader AT, Candidi M, Does apraxia support spatial and kinematic or mirror neuron approaches to social interaction? A commentary on Binder et al. (2017), CORTEX (2017), doi: 10.1016/j.cortex.2017.10.018. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT
Does apraxia support spatial and kinematic or mirror neuron approaches to social interaction? A commentary on Binder et al. (2017) Arran T. Reader1* & Matteo Candidi2,3
Language Sciences, University of Reading, Reading, UK
RI PT
1. Centre for Integrative Neuroscience and Neurodynamics, School of Psychology and Clinical
2. Department of Psychology, Sapienza University of Rome, Rome, Italy 3. IRCCS, Fondazione Santa Lucia, Rome, Italy
SC
*Corresponding author: Arran T. Reader, School of Psychology and Clinical Language Sciences, University of Reading, Earley Gate, Whiteknights Road, Reading, RG6 6AL, UK.
M AN U
Telephone: +44 (0)118 378 8522. E-mail: [email protected]
Acknowledgements: This submission was supported by the Economic and Social Research
AC C
EP
TE D
Council (grant number ES/J500148/1 to ATR).
ACCEPTED MANUSCRIPT
In a recent article in Cortex Binder et al. (2017) present data from 44 left-hemisphere stroke
2
patients with (n = 18) and without (n = 26) apraxia. They tested these patients, alongside healthy
3
controls (n = 19), on three experimental tasks (meaningful gesture recognition, comprehension, and
4
imitation), and two control tasks (control recognition, control comprehension). They also performed
5
a voxel-based lesion-symptom mapping (VLSM) in order to associate lesion locations with
6
experimental task performance in patients. They were specifically interested in examining whether
7
regions associated with the putative human mirror neuron system (MNS) are involved critically, and
8
to a similar degree, in recognising, understanding, and imitating actions.
RI PT
1
9
Their results showed that apraxic patients were significantly worse than non-apraxic patients
11
and healthy controls in gesture comprehension, gesture imitation, gesture recognition, as well as in
12
the control recognition task (in which participants had to decide in which of two gestures the hand
13
was closer to the head). Performance in the three experimental tasks was significantly correlated.
14
Defective gesture comprehension was associated with cortical lesions in the operculum, insula, and
15
inferior frontal gyrus (IFG), whilst defective gesture imitation was associated with cortical lesions
16
in the postcentral gyrus, middle temporal gyrus, superior temporal gyrus, intraparietal sulcus,
17
supramarginal gyrus, operculum, and insula. The authors state that the deficits in gesture
18
comprehension are mainly associated with anterior regions of the MNS (IFG), whilst gesture
19
imitation deficits are associated with the posterior MNS (inferior parietal lobule, superior temporal
20
sulcus). They conclude that their data “not only support the notion of [a MNS], but characterize its
21
functional role by showing its relevance for action comprehension and imitation” (p. 135).
M AN U
TE D
22
SC
10
The putative human frontoparietal MNS has strongly influenced discussions of social
24
interaction (Cook & Bird, 2013; Hamilton, 2014; Kilner & Lemon, 2013; Press & Cook, 2015), and
25
Binder et al. (2017) are right to bridge the gap between studies of social interaction in healthy
26
people and neuropsychological research. Whilst we recognise that simulative comparisons between
27
observed and stored actions may have a role to play in action comprehension and imitation, and that
28
these processes are possibly subserved by frontoparietal regions, we believe that the claims of
29
Binder et al. (2017) require further discussion. In particular, we believe that the pattern of results
30
from the study highlights the possible contribution of body-centered spatial representations or
31
kinematics in apraxia, beside that of action simulation mechanisms, and that these functions may
32
also be associated with proposed mirror regions. We aim to make this distinction clear in order to
33
stimulate a deeper understanding of the possible role for the putative human MNS for higher-order
34
action understanding and perception.
AC C
EP
23
1
ACCEPTED MANUSCRIPT
35
Though Binder et al. (2017) claim that “lesions to the core regions of the putative hMNS
37
critically affected key functions ascribed to it” (p. 135), simulative mechanisms are by no means the
38
only essential component of these functions, as has been noted by others (Buxbaum & Kalénine,
39
2010). Similarly, mirror mechanisms are not the only process associated with proposed mirror
40
regions such as the left inferior parietal lobule (IPL). To expand on this point, Binder et al. (2017)
41
found that apraxia patients were also significantly worse than non-apraxic patients and healthy
42
controls in the gesture recognition control task (testing the ability to evaluate the spatial distance
43
between the model’s hand and head). They suggest that the significant effect in this task could be
44
due to proposed left hemisphere apraxia deficits in ‘body part coding’ (Goldenberg & Karnath,
45
2006). This approach to apraxia suggests that the observed deficits can be considered a problem of
46
correctly assessing the spatial relationship between body parts (such as the hand) and other body
47
parts or objects. Thus, they interpret their results in the recognition control task by suggesting that
48
the coding of spatial relationships between body parts may have been impaired in their apraxic
49
patients. However, this may also provide an explanation for the other results observed in this
50
experiment, since an inability to accurately assess the spatial relationships between body parts in
51
different gestures could feasibly make recognition, comprehension, and imitation harder to
52
complete. Unfortunately, the authors do not report whether any lesioned areas were associated with
53
this control task and whether these overlapped with the reported regions predicting the impairments
54
in the experimental tasks.
SC
M AN U
TE D
55
RI PT
36
Notable in Binder and colleague’s (2017) study is the anterior-posterior split between lesions
57
associated with gesture comprehension (anterior) and lesions associated with gesture imitation
58
(posterior). Previous evidence does seem to support a vital role for the left IFG in action
59
understanding (Urgesi et al., 2014), which could be associated with the proposed simulative role of
60
mirror neurons. However, there may be a different explanation for the role of posterior regions in
61
imitation. A VLSM study by Buxbaum et al. (2014) suggests that left IPL damage is associated with
62
deficits in the kinematic aspects of imitation, whereas damage to the posterior temporal lobe is
63
associated with deficits in the postural aspects of imitation. Similar results were reported more
64
recently by Dressing et al. (2016). Since Binder et al. (2017) did not distinguish between the
65
kinematic and postural elements of their imitation task during analysis, it is unclear to what degree
66
these different elements of movement might better explain their results. Discussion on these terms
67
may better account for the fact that left parietal lesions frequently cause deficits in the imitation of
68
novel actions (Goldenberg, 2009). Since mirror approaches to social cognition rely on the idea that
AC C
EP
56
2
ACCEPTED MANUSCRIPT
mirror neurons are involved in visuomotor matching of observed and stored actions (Rizzolatti et
70
al., 2014), it is yet unclear how visuomotor matching is a feasible explanation for defective
71
imitation of novel actions, since there should be no stored action representation to match. On the
72
other hand, both novel and known actions could be coded in terms of the observed postural or
73
kinematic parameters, with novel actions showing a greater reliance on this type of information
74
(Rumiati et al., 2009; Rumiati & Tessari, 2002; Tessari & Rumiati, 2004). It is possible then that in
75
this instance the anterior-posterior split does not necessarily reflect two mirror mechanisms, but
76
rather a distinction between simulative and spatial or kinematic mechanisms for social motor
77
behaviour.
RI PT
69
78
Finally, we are in agreement with Binder et al. (2017) when they state that the “lack of
80
significant result for the VLSM of our Gesture Recognition task is in line with [the claim] that in
81
contrast to gesture comprehension a mere recognition of correctly performed familiar gestures is not
82
a core function of the human MNS” (p. 134). In fact, action recognition could be principally
83
subserved by occipitotemporal regions (Lingnau & Downing, 2015; Peelen & Downing, 2017), as
84
recent evidence suggests that visual representations of body parts and action in this area are
85
organised in terms of semantics, transitivity, and sociality (Bracci et al., 2015; Wurm et al., 2017),
86
and that the structure of these representations could possibly assist in higher-level social cognition
87
in a bottom-up manner (Reader, 2016). Previous VLSM approaches to deficits in gesture
88
recognition, particularly for semantic aspects of action, reflect the importance of these regions
89
(Kalénine et al., 2010).
M AN U
TE D
90
SC
79
In conclusion, whilst Binder et al. (2017) confirm the role of frontoparietal regions in
92
apraxia, there is still much work to be done to fully understand the contribution of these areas to
93
both apraxia and social motor behaviour as a whole. Importantly, deficits following damage to
94
proposed regions of the human mirror network can also provide support for proposed functions of
95
these regions apart from a mirror mechanism. In social interaction we believe it is fundamental to
96
understand the contribution of regions coding for the kinematic, spatial, or postural features of
97
action, over a purely mirror neuron driven approach.
AC C
EP
91
3
ACCEPTED MANUSCRIPT
98
References
99
Binder, E., Dovern, A., Hesse, M.D., Ebke, M., Karbe, H., Saliger, J., Fink, G.R., & Weiss, P.H.
100
(2017). Lesion evidence for a human mirror neuron system. Cortex, 90, 125-137.
101
doi:10.1016/j.cortex.2017.02.008
102 Bracci, S., Caramazza, A., & Peelen, M.V. (2015). Representational similarity of body parts in
104
human occipitotemporal cortex. Journal of Neuroscience, 35(38), 12977-12985.
105
doi:10.1523/JNEUROSCI.4698-14.2015
RI PT
103
106
Buxbaum, L.J., & Kalénine, S. (2010). Action knowledge, visuomotor activation, and embodiment
108
in the two action systems. Annals of the New York Academy of Sciences, 1191, 201-218.
109
doi:10.1111/j.1749-6632.2010.05447.x.
SC
107
M AN U
110 111
Buxbaum, L.J., Shapiro, A.D., & Coslett, H.B. (2014). Critical brain regions for tool-related and
112
imitative actions: a componential analysis. Brain, 137(7), 1971-1985. doi:10.1093/brain/awu111
113 114
Cook, R., & Bird, G. (2013). Do mirror neurons really mirror and do they really code for action
115
goals? Cortex, 49(10), 2944-2945. doi:10.1016/j.cortex.2013.05.006
TE D
116
Dressing, A., Nitschke, K., Kümmerer, D., Bormann, T., Beume, L., Schmidt, C.S.M., Ludwig,
118
V.M., Mader, I., Willmes, K., Rijntjes, M., Kaller, C.P., Weiller, C., & Martin, M. (2016). Distinct
119
contributions of dorsal and ventral streams to imitation of tool-use and communicative gestures.
120
Cerebral Cortex. doi:10.1093/cercor/bhw383
121
EP
117
Goldenberg, G. (2009). Apraxia and the parietal lobes. Neuropsychologia, 47, 1449-1459.
123
doi:10.1016/j.neuropsychologia.2008.07.014
124
AC C
122
125
Goldenberg, G., & Karnath, H. (2006). The neural basis of imitation is body part specific. Journal
126
of Neuroscience, 26(23), 6282-6287. doi:10.1523/JNEUROSCI.0638-06.2006
127 128
Hamilton, A.F. de C. (2014). Cognitive underpinnings of social interaction. Quarterly Journal of
129
Experimental Psychology, 68(3), 417-432. doi:10.1080/17470218.2014.973424
130
4
ACCEPTED MANUSCRIPT
131
Kalénine, S., Buxbaum, L.J., & Coslett, H.B. (2010). Critical brain regions for action recognition:
132
lesion symptom mapping in left hemisphere stroke. Brain, 133(11), 3269-3280.
133
doi:10.1093/brain/awq210
134 Kilner, J.M., & Lemon, R.N. (2013). What we know currently about mirror neurons. Current
136
Biology, 23(23), R1057-1062. doi:10.1016/j.cub.2013.10.051
137
RI PT
135
138
Lingnau, A., & Downing, P.E. (2015). The lateral occipitotemporal cortex in action. Trends in
139
Cognitive Sciences, 19(5), 268-277. doi:10.1016/j.tics.2015.03.006
140
Peelen, M.V., & Downing, P.E. (2017). Category selectivity in human visual cortex: beyond visual
142
object recognition. Neuropsychologia, 17, 30121-30125.
143
doi:10.1016/j.neuropsychologia.2017.03.033
M AN U
144
SC
141
145
Press, C., & Cook, R. (2015). Beyond action-specific simulation: domain-general motor
146
contributions to perception. Trends in Cognitive Sciences, 19(4), 176-178.
147
doi:10.1016/j.tics.2015.01.006
148
Reader, A.T. (2016). Semantic organization of body part representations in the occipitotemporal
150
cortex. Journal of Neuroscience, 36(2), 265-267. doi:10.1523/JNEUROSCI.3766-15.2016
151
TE D
149
Rizzolatti, G., Cattaneo, L., Fabbri-Destro, M., & Rozzi, S. (2014). Cortical mechanisms underlying
153
the organization of goal-directed actions and mirror neuron-based action understanding.
154
Physiological Reviews, 94(2), 655-706. doi:10.1152/physrev.00009.2013
AC C
155
EP
152
156
Rumiati, R.I., Carmo, J.C., & Corradi-Dell’Acqua, C. (2009). Neuropsychological perspectives on
157
the mechanisms of imitation. Philosophical Transactions of the Royal Society of London. Series B,
158
Biological Sciences, 364(1528), 2337-2347. doi:10.1098/rstb.2009.0063
159 160
Rumiati, R.I., & Tessari, A. (2002). Imitation of novel and well-known actions: the role of short-
161
term memory. Experimental Brain Research, 142, 425-433. doi:10.1007/s00221-001-0956-x
162
5
ACCEPTED MANUSCRIPT
163
Tessari, A., & Rumiati, R.I. (2004). The strategic control of multiple routes in imitation of actions.
164
Journal of Experimental Psychology Human Perception and Performance, 30(6), 1107-1116.
165
doi:10.1037/0096-1523.30.6.1107
166 Urgesi, C., Candidi, M., & Avenanti, A. (2014). Neuroanatomical substrates of action perception
168
and understanding: an anatomic likelihood estimation meta-analysis of lesion-symptom mapping
169
studies in brain injured patients. Frontiers in Human Neuroscience, 8(344).
170
doi:10.3389/fnhum.2014.00344
RI PT
167
171
Wurm, M.F., Caramazza, A., & Lingnau, A. (2017). Action categories in lateral occipitotemporal
173
cortex are organized along sociality and transitivity. Journal of Neuroscience, 37(3), 562-575.
174
doi:10.1523/JNEUROSCI.1717-16.2017
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EP
TE D
M AN U
SC
172
6
S0010-9452(17)30366-0
DOI:
10.1016/j.cortex.2017.10.018
Reference:
CORTEX 2167
To appear in:
Cortex
Received Date: 2 June 2017 Revised Date:
22 August 2017
Accepted Date: 21 October 2017
Please cite this article as: Reader AT, Candidi M, Does apraxia support spatial and kinematic or mirror neuron approaches to social interaction? A commentary on Binder et al. (2017), CORTEX (2017), doi: 10.1016/j.cortex.2017.10.018. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT
Does apraxia support spatial and kinematic or mirror neuron approaches to social interaction? A commentary on Binder et al. (2017) Arran T. Reader1* & Matteo Candidi2,3
Language Sciences, University of Reading, Reading, UK
RI PT
1. Centre for Integrative Neuroscience and Neurodynamics, School of Psychology and Clinical
2. Department of Psychology, Sapienza University of Rome, Rome, Italy 3. IRCCS, Fondazione Santa Lucia, Rome, Italy
SC
*Corresponding author: Arran T. Reader, School of Psychology and Clinical Language Sciences, University of Reading, Earley Gate, Whiteknights Road, Reading, RG6 6AL, UK.
M AN U
Telephone: +44 (0)118 378 8522. E-mail: [email protected]
Acknowledgements: This submission was supported by the Economic and Social Research
AC C
EP
TE D
Council (grant number ES/J500148/1 to ATR).
ACCEPTED MANUSCRIPT
In a recent article in Cortex Binder et al. (2017) present data from 44 left-hemisphere stroke
2
patients with (n = 18) and without (n = 26) apraxia. They tested these patients, alongside healthy
3
controls (n = 19), on three experimental tasks (meaningful gesture recognition, comprehension, and
4
imitation), and two control tasks (control recognition, control comprehension). They also performed
5
a voxel-based lesion-symptom mapping (VLSM) in order to associate lesion locations with
6
experimental task performance in patients. They were specifically interested in examining whether
7
regions associated with the putative human mirror neuron system (MNS) are involved critically, and
8
to a similar degree, in recognising, understanding, and imitating actions.
RI PT
1
9
Their results showed that apraxic patients were significantly worse than non-apraxic patients
11
and healthy controls in gesture comprehension, gesture imitation, gesture recognition, as well as in
12
the control recognition task (in which participants had to decide in which of two gestures the hand
13
was closer to the head). Performance in the three experimental tasks was significantly correlated.
14
Defective gesture comprehension was associated with cortical lesions in the operculum, insula, and
15
inferior frontal gyrus (IFG), whilst defective gesture imitation was associated with cortical lesions
16
in the postcentral gyrus, middle temporal gyrus, superior temporal gyrus, intraparietal sulcus,
17
supramarginal gyrus, operculum, and insula. The authors state that the deficits in gesture
18
comprehension are mainly associated with anterior regions of the MNS (IFG), whilst gesture
19
imitation deficits are associated with the posterior MNS (inferior parietal lobule, superior temporal
20
sulcus). They conclude that their data “not only support the notion of [a MNS], but characterize its
21
functional role by showing its relevance for action comprehension and imitation” (p. 135).
M AN U
TE D
22
SC
10
The putative human frontoparietal MNS has strongly influenced discussions of social
24
interaction (Cook & Bird, 2013; Hamilton, 2014; Kilner & Lemon, 2013; Press & Cook, 2015), and
25
Binder et al. (2017) are right to bridge the gap between studies of social interaction in healthy
26
people and neuropsychological research. Whilst we recognise that simulative comparisons between
27
observed and stored actions may have a role to play in action comprehension and imitation, and that
28
these processes are possibly subserved by frontoparietal regions, we believe that the claims of
29
Binder et al. (2017) require further discussion. In particular, we believe that the pattern of results
30
from the study highlights the possible contribution of body-centered spatial representations or
31
kinematics in apraxia, beside that of action simulation mechanisms, and that these functions may
32
also be associated with proposed mirror regions. We aim to make this distinction clear in order to
33
stimulate a deeper understanding of the possible role for the putative human MNS for higher-order
34
action understanding and perception.
AC C
EP
23
1
ACCEPTED MANUSCRIPT
35
Though Binder et al. (2017) claim that “lesions to the core regions of the putative hMNS
37
critically affected key functions ascribed to it” (p. 135), simulative mechanisms are by no means the
38
only essential component of these functions, as has been noted by others (Buxbaum & Kalénine,
39
2010). Similarly, mirror mechanisms are not the only process associated with proposed mirror
40
regions such as the left inferior parietal lobule (IPL). To expand on this point, Binder et al. (2017)
41
found that apraxia patients were also significantly worse than non-apraxic patients and healthy
42
controls in the gesture recognition control task (testing the ability to evaluate the spatial distance
43
between the model’s hand and head). They suggest that the significant effect in this task could be
44
due to proposed left hemisphere apraxia deficits in ‘body part coding’ (Goldenberg & Karnath,
45
2006). This approach to apraxia suggests that the observed deficits can be considered a problem of
46
correctly assessing the spatial relationship between body parts (such as the hand) and other body
47
parts or objects. Thus, they interpret their results in the recognition control task by suggesting that
48
the coding of spatial relationships between body parts may have been impaired in their apraxic
49
patients. However, this may also provide an explanation for the other results observed in this
50
experiment, since an inability to accurately assess the spatial relationships between body parts in
51
different gestures could feasibly make recognition, comprehension, and imitation harder to
52
complete. Unfortunately, the authors do not report whether any lesioned areas were associated with
53
this control task and whether these overlapped with the reported regions predicting the impairments
54
in the experimental tasks.
SC
M AN U
TE D
55
RI PT
36
Notable in Binder and colleague’s (2017) study is the anterior-posterior split between lesions
57
associated with gesture comprehension (anterior) and lesions associated with gesture imitation
58
(posterior). Previous evidence does seem to support a vital role for the left IFG in action
59
understanding (Urgesi et al., 2014), which could be associated with the proposed simulative role of
60
mirror neurons. However, there may be a different explanation for the role of posterior regions in
61
imitation. A VLSM study by Buxbaum et al. (2014) suggests that left IPL damage is associated with
62
deficits in the kinematic aspects of imitation, whereas damage to the posterior temporal lobe is
63
associated with deficits in the postural aspects of imitation. Similar results were reported more
64
recently by Dressing et al. (2016). Since Binder et al. (2017) did not distinguish between the
65
kinematic and postural elements of their imitation task during analysis, it is unclear to what degree
66
these different elements of movement might better explain their results. Discussion on these terms
67
may better account for the fact that left parietal lesions frequently cause deficits in the imitation of
68
novel actions (Goldenberg, 2009). Since mirror approaches to social cognition rely on the idea that
AC C
EP
56
2
ACCEPTED MANUSCRIPT
mirror neurons are involved in visuomotor matching of observed and stored actions (Rizzolatti et
70
al., 2014), it is yet unclear how visuomotor matching is a feasible explanation for defective
71
imitation of novel actions, since there should be no stored action representation to match. On the
72
other hand, both novel and known actions could be coded in terms of the observed postural or
73
kinematic parameters, with novel actions showing a greater reliance on this type of information
74
(Rumiati et al., 2009; Rumiati & Tessari, 2002; Tessari & Rumiati, 2004). It is possible then that in
75
this instance the anterior-posterior split does not necessarily reflect two mirror mechanisms, but
76
rather a distinction between simulative and spatial or kinematic mechanisms for social motor
77
behaviour.
RI PT
69
78
Finally, we are in agreement with Binder et al. (2017) when they state that the “lack of
80
significant result for the VLSM of our Gesture Recognition task is in line with [the claim] that in
81
contrast to gesture comprehension a mere recognition of correctly performed familiar gestures is not
82
a core function of the human MNS” (p. 134). In fact, action recognition could be principally
83
subserved by occipitotemporal regions (Lingnau & Downing, 2015; Peelen & Downing, 2017), as
84
recent evidence suggests that visual representations of body parts and action in this area are
85
organised in terms of semantics, transitivity, and sociality (Bracci et al., 2015; Wurm et al., 2017),
86
and that the structure of these representations could possibly assist in higher-level social cognition
87
in a bottom-up manner (Reader, 2016). Previous VLSM approaches to deficits in gesture
88
recognition, particularly for semantic aspects of action, reflect the importance of these regions
89
(Kalénine et al., 2010).
M AN U
TE D
90
SC
79
In conclusion, whilst Binder et al. (2017) confirm the role of frontoparietal regions in
92
apraxia, there is still much work to be done to fully understand the contribution of these areas to
93
both apraxia and social motor behaviour as a whole. Importantly, deficits following damage to
94
proposed regions of the human mirror network can also provide support for proposed functions of
95
these regions apart from a mirror mechanism. In social interaction we believe it is fundamental to
96
understand the contribution of regions coding for the kinematic, spatial, or postural features of
97
action, over a purely mirror neuron driven approach.
AC C
EP
91
3
ACCEPTED MANUSCRIPT
98
References
99
Binder, E., Dovern, A., Hesse, M.D., Ebke, M., Karbe, H., Saliger, J., Fink, G.R., & Weiss, P.H.
100
(2017). Lesion evidence for a human mirror neuron system. Cortex, 90, 125-137.
101
doi:10.1016/j.cortex.2017.02.008
102 Bracci, S., Caramazza, A., & Peelen, M.V. (2015). Representational similarity of body parts in
104
human occipitotemporal cortex. Journal of Neuroscience, 35(38), 12977-12985.
105
doi:10.1523/JNEUROSCI.4698-14.2015
RI PT
103
106
Buxbaum, L.J., & Kalénine, S. (2010). Action knowledge, visuomotor activation, and embodiment
108
in the two action systems. Annals of the New York Academy of Sciences, 1191, 201-218.
109
doi:10.1111/j.1749-6632.2010.05447.x.
SC
107
M AN U
110 111
Buxbaum, L.J., Shapiro, A.D., & Coslett, H.B. (2014). Critical brain regions for tool-related and
112
imitative actions: a componential analysis. Brain, 137(7), 1971-1985. doi:10.1093/brain/awu111
113 114
Cook, R., & Bird, G. (2013). Do mirror neurons really mirror and do they really code for action
115
goals? Cortex, 49(10), 2944-2945. doi:10.1016/j.cortex.2013.05.006
TE D
116
Dressing, A., Nitschke, K., Kümmerer, D., Bormann, T., Beume, L., Schmidt, C.S.M., Ludwig,
118
V.M., Mader, I., Willmes, K., Rijntjes, M., Kaller, C.P., Weiller, C., & Martin, M. (2016). Distinct
119
contributions of dorsal and ventral streams to imitation of tool-use and communicative gestures.
120
Cerebral Cortex. doi:10.1093/cercor/bhw383
121
EP
117
Goldenberg, G. (2009). Apraxia and the parietal lobes. Neuropsychologia, 47, 1449-1459.
123
doi:10.1016/j.neuropsychologia.2008.07.014
124
AC C
122
125
Goldenberg, G., & Karnath, H. (2006). The neural basis of imitation is body part specific. Journal
126
of Neuroscience, 26(23), 6282-6287. doi:10.1523/JNEUROSCI.0638-06.2006
127 128
Hamilton, A.F. de C. (2014). Cognitive underpinnings of social interaction. Quarterly Journal of
129
Experimental Psychology, 68(3), 417-432. doi:10.1080/17470218.2014.973424
130
4
ACCEPTED MANUSCRIPT
131
Kalénine, S., Buxbaum, L.J., & Coslett, H.B. (2010). Critical brain regions for action recognition:
132
lesion symptom mapping in left hemisphere stroke. Brain, 133(11), 3269-3280.
133
doi:10.1093/brain/awq210
134 Kilner, J.M., & Lemon, R.N. (2013). What we know currently about mirror neurons. Current
136
Biology, 23(23), R1057-1062. doi:10.1016/j.cub.2013.10.051
137
RI PT
135
138
Lingnau, A., & Downing, P.E. (2015). The lateral occipitotemporal cortex in action. Trends in
139
Cognitive Sciences, 19(5), 268-277. doi:10.1016/j.tics.2015.03.006
140
Peelen, M.V., & Downing, P.E. (2017). Category selectivity in human visual cortex: beyond visual
142
object recognition. Neuropsychologia, 17, 30121-30125.
143
doi:10.1016/j.neuropsychologia.2017.03.033
M AN U
144
SC
141
145
Press, C., & Cook, R. (2015). Beyond action-specific simulation: domain-general motor
146
contributions to perception. Trends in Cognitive Sciences, 19(4), 176-178.
147
doi:10.1016/j.tics.2015.01.006
148
Reader, A.T. (2016). Semantic organization of body part representations in the occipitotemporal
150
cortex. Journal of Neuroscience, 36(2), 265-267. doi:10.1523/JNEUROSCI.3766-15.2016
151
TE D
149
Rizzolatti, G., Cattaneo, L., Fabbri-Destro, M., & Rozzi, S. (2014). Cortical mechanisms underlying
153
the organization of goal-directed actions and mirror neuron-based action understanding.
154
Physiological Reviews, 94(2), 655-706. doi:10.1152/physrev.00009.2013
AC C
155
EP
152
156
Rumiati, R.I., Carmo, J.C., & Corradi-Dell’Acqua, C. (2009). Neuropsychological perspectives on
157
the mechanisms of imitation. Philosophical Transactions of the Royal Society of London. Series B,
158
Biological Sciences, 364(1528), 2337-2347. doi:10.1098/rstb.2009.0063
159 160
Rumiati, R.I., & Tessari, A. (2002). Imitation of novel and well-known actions: the role of short-
161
term memory. Experimental Brain Research, 142, 425-433. doi:10.1007/s00221-001-0956-x
162
5
ACCEPTED MANUSCRIPT
163
Tessari, A., & Rumiati, R.I. (2004). The strategic control of multiple routes in imitation of actions.
164
Journal of Experimental Psychology Human Perception and Performance, 30(6), 1107-1116.
165
doi:10.1037/0096-1523.30.6.1107
166 Urgesi, C., Candidi, M., & Avenanti, A. (2014). Neuroanatomical substrates of action perception
168
and understanding: an anatomic likelihood estimation meta-analysis of lesion-symptom mapping
169
studies in brain injured patients. Frontiers in Human Neuroscience, 8(344).
170
doi:10.3389/fnhum.2014.00344
RI PT
167
171
Wurm, M.F., Caramazza, A., & Lingnau, A. (2017). Action categories in lateral occipitotemporal
173
cortex are organized along sociality and transitivity. Journal of Neuroscience, 37(3), 562-575.
174
doi:10.1523/JNEUROSCI.1717-16.2017
AC C
EP
TE D
M AN U
SC
172
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