Normalized activation in the somatosensory cortex 30 years following nerve repair in children: an fMRI study

The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In 28 patients with a complete median nerve injury sustained at the ages of 1–13 years (n = 13)...

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Published inThe European journal of neuroscience Vol. 42; no. 4; pp. 2022 - 2027
Main Authors Chemnitz, Anette, Weibull, Andreas, Rosén, Birgitta, Andersson, Gert, Dahlin, Lars B., Björkman, Anders
Format Journal Article
LanguageEnglish
Published France Blackwell Publishing Ltd 01.08.2015
Subjects
Adolescent
Age Factors
Basic Medicine
Child
Child, Preschool
cortical plasticity
Electric Stimulation
Female
Functional Laterality - physiology
functional recovery
Humans
Image Processing, Computer-Assisted
Infant
Longitudinal Studies
Magnetic Resonance Imaging
Male
Medical and Health Sciences
Medicin och hälsovetenskap
Medicinska och farmaceutiska grundvetenskaper
MRI
Neural Conduction - physiology
Neurosciences
Neurovetenskaper
Oxygen - blood
Peripheral Nerve Injuries - pathology
Peripheral Nerve Injuries - physiopathology
Peripheral Nerve Injuries - surgery
peripheral nerve injury
Recovery of Function - physiology
Retrospective Studies
Severity of Illness Index
Somatosensory Cortex - blood supply
Somatosensory Cortex - physiopathology
Young Adult
cortical plasticity
peripheral nerve injury
functional recovery
MRI
Online AccessGet full text
ISSN0953-816X
1460-9568
1460-9568
DOI10.1111/ejn.12917

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Abstract The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In 28 patients with a complete median nerve injury sustained at the ages of 1–13 years (n = 13) and 14–20 years (n = 15), the cortical activation during tactile finger stimulation of the injured and healthy hands was monitored at a median time since injury of 28 years using functional magnetic resonance imaging (fMRI) at 3 Tesla. The results from the fMRI were compared with the clinical outcome and electroneurography. The cortical activation pattern following sensory stimulation of the median nerve‐innervated fingers was dependent on the patient's age at injury. Those injured at a young age (1–13 years) had an activation pattern similar to that of healthy controls. Furthermore, they showed a clinical outcome significantly superior (P = 0.001) to the outcome in subjects injured at a later age; however, electroneurographical parameters did not differ between the groups. In subjects injured at age 14–20 years, a more extended activation of the contralateral hemisphere was seen in general. Interestingly, these patients also displayed changes in the ipsilateral hemisphere where a reduced inhibition of somatosensory areas was seen. This loss of ipsilateral inhibition correlated to increasing age at injury as well as to poor recovery of sensory functions in the hand. In conclusion, cerebral changes in both brain hemispheres may explain differences in clinical outcome following a median nerve injury in childhood or adolescence. Cortical activation was assessed, using fMRI at 3T, 28 years after a median nerve injury. The cortical activation pattern was compared with clinical outcome and electroneurography. Patients injured before the age of 14 years had an activation pattern similar to healthy controls and an excellent clinical outcome. Those injured at age 14–20 years showed more extended activation of contralateral somatosensory areas, as well as loss of ipsilateral inhibition and poor clinical outcome. Electroneurographical parameters did not differ between the two age groups. Cerebral changes in both hemispheres may explain the superior clinical outcome following a median nerve injury in childhood.
AbstractList The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In 28 patients with a complete median nerve injury sustained at the ages of 1-13 years (n = 13) and 14-20 years (n = 15), the cortical activation during tactile finger stimulation of the injured and healthy hands was monitored at a median time since injury of 28 years using functional magnetic resonance imaging (fMRI) at 3 Tesla. The results from the fMRI were compared with the clinical outcome and electroneurography. The cortical activation pattern following sensory stimulation of the median nerve-innervated fingers was dependent on the patient's age at injury. Those injured at a young age (1-13 years) had an activation pattern similar to that of healthy controls. Furthermore, they showed a clinical outcome significantly superior (P = 0.001) to the outcome in subjects injured at a later age; however, electroneurographical parameters did not differ between the groups. In subjects injured at age 14-20 years, a more extended activation of the contralateral hemisphere was seen in general. Interestingly, these patients also displayed changes in the ipsilateral hemisphere where a reduced inhibition of somatosensory areas was seen. This loss of ipsilateral inhibition correlated to increasing age at injury as well as to poor recovery of sensory functions in the hand. In conclusion, cerebral changes in both brain hemispheres may explain differences in clinical outcome following a median nerve injury in childhood or adolescence.
The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In 28 patients with a complete median nerve injury sustained at the ages of 1-13 years (n = 13) and 14-20 years (n = 15), the cortical activation during tactile finger stimulation of the injured and healthy hands was monitored at a median time since injury of 28 years using functional magnetic resonance imaging (fMRI) at 3 Tesla. The results from the fMRI were compared with the clinical outcome and electroneurography. The cortical activation pattern following sensory stimulation of the median nerve-innervated fingers was dependent on the patient's age at injury. Those injured at a young age (1-13 years) had an activation pattern similar to that of healthy controls. Furthermore, they showed a clinical outcome significantly superior (P = 0.001) to the outcome in subjects injured at a later age; however, electroneurographical parameters did not differ between the groups. In subjects injured at age 14-20 years, a more extended activation of the contralateral hemisphere was seen in general. Interestingly, these patients also displayed changes in the ipsilateral hemisphere where a reduced inhibition of somatosensory areas was seen. This loss of ipsilateral inhibition correlated to increasing age at injury as well as to poor recovery of sensory functions in the hand. In conclusion, cerebral changes in both brain hemispheres may explain differences in clinical outcome following a median nerve injury in childhood or adolescence.The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In 28 patients with a complete median nerve injury sustained at the ages of 1-13 years (n = 13) and 14-20 years (n = 15), the cortical activation during tactile finger stimulation of the injured and healthy hands was monitored at a median time since injury of 28 years using functional magnetic resonance imaging (fMRI) at 3 Tesla. The results from the fMRI were compared with the clinical outcome and electroneurography. The cortical activation pattern following sensory stimulation of the median nerve-innervated fingers was dependent on the patient's age at injury. Those injured at a young age (1-13 years) had an activation pattern similar to that of healthy controls. Furthermore, they showed a clinical outcome significantly superior (P = 0.001) to the outcome in subjects injured at a later age; however, electroneurographical parameters did not differ between the groups. In subjects injured at age 14-20 years, a more extended activation of the contralateral hemisphere was seen in general. Interestingly, these patients also displayed changes in the ipsilateral hemisphere where a reduced inhibition of somatosensory areas was seen. This loss of ipsilateral inhibition correlated to increasing age at injury as well as to poor recovery of sensory functions in the hand. In conclusion, cerebral changes in both brain hemispheres may explain differences in clinical outcome following a median nerve injury in childhood or adolescence.
The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In twenty-eight patients with a complete median nerve injury sustained at the ages of 1-13 years (n=13) and 14-20 years (n=15), the cortical activation during tactile finger stimulation of the injured and healthy hands was monitored at a median time since injury of 28 years using functional magnetic resonance imaging (fMRI) at 3 Tesla. The results from the fMRI were compared with the clinical outcome and electroneurography. The cortical activation pattern following sensory stimulation of the median nerve innervated fingers was dependent on the patient's age at injury. Those injured at a young age (1-13 years) had an activation pattern similar to that of healthy controls. Furthermore, they showed a clinical outcome significantly superior (p=0.001) to the outcome in subjects injured at a later age, however, electroneurographical parameters did not differ between the groups. In subjects injured at age 14-20 years, a more extended activation of the contralateral hemisphere was seen in general. Interestingly, these patients also displayed changes in the ipsilateral hemisphere where a reduced inhibition of somatosensory areas was seen. This loss of ipsilateral inhibition correlated to increasing age at injury as well as to poor recovery of sensory functions in the hand. In conclusion, cerebral changes in both brain hemispheres may explain differences in clinical outcome following a median nerve injury in childhood or adolescence. This article is protected by copyright. All rights reserved.
The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In 28 patients with a complete median nerve injury sustained at the ages of 1–13 years (n = 13) and 14–20 years (n = 15), the cortical activation during tactile finger stimulation of the injured and healthy hands was monitored at a median time since injury of 28 years using functional magnetic resonance imaging (fMRI) at 3 Tesla. The results from the fMRI were compared with the clinical outcome and electroneurography. The cortical activation pattern following sensory stimulation of the median nerve‐innervated fingers was dependent on the patient's age at injury. Those injured at a young age (1–13 years) had an activation pattern similar to that of healthy controls. Furthermore, they showed a clinical outcome significantly superior (P = 0.001) to the outcome in subjects injured at a later age; however, electroneurographical parameters did not differ between the groups. In subjects injured at age 14–20 years, a more extended activation of the contralateral hemisphere was seen in general. Interestingly, these patients also displayed changes in the ipsilateral hemisphere where a reduced inhibition of somatosensory areas was seen. This loss of ipsilateral inhibition correlated to increasing age at injury as well as to poor recovery of sensory functions in the hand. In conclusion, cerebral changes in both brain hemispheres may explain differences in clinical outcome following a median nerve injury in childhood or adolescence. Cortical activation was assessed, using fMRI at 3T, 28 years after a median nerve injury. The cortical activation pattern was compared with clinical outcome and electroneurography. Patients injured before the age of 14 years had an activation pattern similar to healthy controls and an excellent clinical outcome. Those injured at age 14–20 years showed more extended activation of contralateral somatosensory areas, as well as loss of ipsilateral inhibition and poor clinical outcome. Electroneurographical parameters did not differ between the two age groups. Cerebral changes in both hemispheres may explain the superior clinical outcome following a median nerve injury in childhood.
The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the mechanism behind this difference is unknown. In 28 patients with a complete median nerve injury sustained at the ages of 1–13 years ( n  = 13) and 14–20 years ( n  = 15), the cortical activation during tactile finger stimulation of the injured and healthy hands was monitored at a median time since injury of 28 years using functional magnetic resonance imaging ( fMRI ) at 3 Tesla. The results from the fMRI were compared with the clinical outcome and electroneurography. The cortical activation pattern following sensory stimulation of the median nerve‐innervated fingers was dependent on the patient's age at injury. Those injured at a young age (1–13 years) had an activation pattern similar to that of healthy controls. Furthermore, they showed a clinical outcome significantly superior ( P  = 0.001) to the outcome in subjects injured at a later age; however, electroneurographical parameters did not differ between the groups. In subjects injured at age 14–20 years, a more extended activation of the contralateral hemisphere was seen in general. Interestingly, these patients also displayed changes in the ipsilateral hemisphere where a reduced inhibition of somatosensory areas was seen. This loss of ipsilateral inhibition correlated to increasing age at injury as well as to poor recovery of sensory functions in the hand. In conclusion, cerebral changes in both brain hemispheres may explain differences in clinical outcome following a median nerve injury in childhood or adolescence.
Author Dahlin, Lars B.
Rosén, Birgitta
Björkman, Anders
Andersson, Gert
Chemnitz, Anette
Weibull, Andreas
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functional recovery
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References Lundborg, G. & Rosen, B. (2001) Sensory relearning after nerve repair. Lancet, 358, 809-810.
Ragert, P., Nierhaus, T., Cohen, L.G. & Villringer, A. (2011) Interhemispheric int eractions between the human primary somatosensory cortices. PLoS One, 6, e16150.
Iwamura, Y., Iriki, A. & Tanaka, M. (1994) Bilateral hand representation in the postcentral somatosensory cortex. Nature, 369, 554-556.
Allan, C.H. (2000) Functional results of primary nerve repair. Hand Clin., 16, 67-72.
Hlushchuk, Y. & Hari, R. (2006) Transient suppression of ipsilateral primary somatosensory cortex during tactile finger stimulation. J. Neurosci., 26, 5819-5824.
Taylor, K.S., Anastakis, D.J. & Davis, K.D. (2009) Cutting your nerve changes your brain. Brain, 132, 3122-3133.
Li, N., Downey, J.E., Bar-Shir, A., Gilad, A.A., Walczak, P., Kim, H., Joel, S.E., Pekar, J.J., Thakor, N.V. & Pelled, G. (2011) Optogenetic-guided cortical plasticity after nerve injury. Proc. Natl. Acad. Sci. USA, 108, 8838-8843.
Chemnitz, A., Bjorkman, A., Dahlin, L.B. & Rosen, B. (2013b) Functional outcome thirty years after median and ulnar nerve repair in childhood and adolescence. J. Bone Joint Surg. Am., 95, 329-337.
Rosen, B. & Lundborg, G. (2003) A new model instrument for outcome after nerve repair. Hand Clin., 19, 463-470.
Johnston, M.V. (2009) Plasticity in the developing brain: implications for rehabilitation. Dev. Disabil. Res. Rev., 15, 94-101.
Pascual-Leone, A., Freitas, C., Oberman, L., Horvath, J.C., Halko, M., Eldaief, M., Bashir, S., Vernet, M., Shafi, M., Westover, B., Vahabzadeh-Hagh, A.M. & Rotenberg, A. (2011) Characterizing brain cortical plasticity and network dynamics across the age-span in health and disease with TMS-EEG and TMS-fMRI. Brain Topogr., 24, 302-315.
Pestronk, A., Drachman, D.B. & Griffin, J.W. (1980) Effects of aging on nerve sprouting and regeneration. Exp. Neurol., 70, 65-82.
Jaquet, J.B., Luijsterburg, A.J., Kalmijn, S., Kuypers, P.D., Hofman, A. & Hovius, S.E. (2001) Median, ulnar, and combined median-ulnar nerve injuries: functional outcome and return to productivity. J. Trauma, 51, 687-692.
Ruijs, A.C., Jaquet, J.B., Kalmijn, S., Giele, H. & Hovius, S.E. (2005) Median and ulnar nerve injuries: a meta-analysis of predictors of motor and sensory recovery after modern microsurgical nerve repair. Plast. Reconstr. Surg., 116, 484-494.
Buhmann, C., Glauche, V., Sturenburg, H.J., Oechsner, M., Weiller, C. & Buchel, C. (2003) Pharmacologically modulated fMRI-cortical responsiveness to levodopa in drug-naive hemiparkinsonian patients. Brain, 126, 451-461.
Weibull, A., Bjorkman, A., Hall, H., Rosen, B., Lundborg, G. & Svensson, J. (2008) Optimizing the mapping of finger areas in primary somatosensory cortex using functional MRI. Magn. Reson. Imaging, 26, 1342-1351.
Westerhausen, R., Luders, E., Specht, K., Ofte, S.H., Toga, A.W., Thompson, P.M., Helland, T. & Hugdahl, K. (2010) Structural and functional reorganization of the corpus callosum between the age of 6 and 8 years. Cereb. Cortex, 21, 1012-1017.
Hoke, A. & Brushart, T. (2010) Introduction to special issue: challenges and opportunities for regeneration in the peripheral nervous system. Exp. Neurol., 223, 1-4.
Almquist, E.E., Smith, O.A. & Fry, L. (1983) Nerve conduction velocity, microscopic, and electron microscopy studies comparing repaired adult and baby monkey median nerves. J. Hand. Surg.-Am., 8, 406-410.
Asato, M.R., Terwilliger, R., Woo, J. & Luna, B. (2010) White matter development in adolescence: a DTI study. Cereb. Cortex, 20, 2122-2131.
Schafer, K., Blankenburg, F., Kupers, R., Gruner, J.M., Law, I., Lauritzen, M. & Larsson, H.B. (2012) Negative BOLD signal changes in ipsilateral primary somatosensory cortex are associated with perfusion decreases and behavioral evidence for functional inhibition. NeuroImage, 59, 3119-3127.
Frykman, G.K. (1976) Peripheral nerve injuries in children. Orthop. Clin. N. Am., 7, 701-716.
Chemnitz, A., Andersson, G., Rosen, B., Dahlin, L.B. & Bjorkman, A. (2013a) Poor electroneurography but excellent hand function 31 years after nerve repair in childhood. NeuroReport, 24, 6-9.
Fornander, L., Nyman, T., Hansson, T., Ragnehed, M. & Brismar, T. (2009) Age- and time-dependent effects on functional outcome and cortical activation pattern in patients with median nerve injury: a functional magnetic resonance imaging study. J. Neurosurg., 113, 122-128.
Talairach, J. & Tournoux, P. (1988) Co-Planar Stereotaxic Atlas of the Human Brain: An Approach to Cerebral Imaging. G. Thieme; Thieme Medical Publishers, Stuttgart, New York.
Vordemvenne, T., Langer, M., Ochman, S., Raschke, M. & Schult, M. (2007) Long-term results after primary microsurgical repair of ulnar and median nerve injuries. A comparison of common score systems. Clin. Neurol. Neurosur., 109, 263-271.
Hansson, T. & Brismar, T. (2003) Loss of sensory discrimination after median nerve injury and activation in the primary somatosensory cortex on functional magnetic resonance imaging. J. Neurosurg., 99, 100-105.
Kaas, J.H. (1991) Plasticity of sensory and motor maps in adult mammals. Annu. Rev. Neurosci., 14, 137-167.
Lundborg, G., Rosen, B., Dahlin, L., Holmberg, J. & Rosen, I. (2004) Tubular repair of the median or ulnar nerve in the human forearm: a 5-year follow-up. J. Hand. Surg.-Brit. Eur., 29, 100-107.
Iwamura, Y. (2000) Bilateral receptive field neurons and callosal connections in the somatosensory cortex. Philos. T. Roy. Soc. B., 355, 267-273.
1991; 14
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2010; 21
2010; 20
1994; 369
2011; 108
2000; 16
2013a; 24
2006; 26
2008; 26
2011; 24
2003; 126
2001; 51
2009; 15
2001; 358
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References_xml – reference: Johnston, M.V. (2009) Plasticity in the developing brain: implications for rehabilitation. Dev. Disabil. Res. Rev., 15, 94-101.
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– reference: Fornander, L., Nyman, T., Hansson, T., Ragnehed, M. & Brismar, T. (2009) Age- and time-dependent effects on functional outcome and cortical activation pattern in patients with median nerve injury: a functional magnetic resonance imaging study. J. Neurosurg., 113, 122-128.
– reference: Iwamura, Y. (2000) Bilateral receptive field neurons and callosal connections in the somatosensory cortex. Philos. T. Roy. Soc. B., 355, 267-273.
– reference: Chemnitz, A., Andersson, G., Rosen, B., Dahlin, L.B. & Bjorkman, A. (2013a) Poor electroneurography but excellent hand function 31 years after nerve repair in childhood. NeuroReport, 24, 6-9.
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– reference: Ragert, P., Nierhaus, T., Cohen, L.G. & Villringer, A. (2011) Interhemispheric int eractions between the human primary somatosensory cortices. PLoS One, 6, e16150.
– reference: Jaquet, J.B., Luijsterburg, A.J., Kalmijn, S., Kuypers, P.D., Hofman, A. & Hovius, S.E. (2001) Median, ulnar, and combined median-ulnar nerve injuries: functional outcome and return to productivity. J. Trauma, 51, 687-692.
– reference: Hlushchuk, Y. & Hari, R. (2006) Transient suppression of ipsilateral primary somatosensory cortex during tactile finger stimulation. J. Neurosci., 26, 5819-5824.
– reference: Pascual-Leone, A., Freitas, C., Oberman, L., Horvath, J.C., Halko, M., Eldaief, M., Bashir, S., Vernet, M., Shafi, M., Westover, B., Vahabzadeh-Hagh, A.M. & Rotenberg, A. (2011) Characterizing brain cortical plasticity and network dynamics across the age-span in health and disease with TMS-EEG and TMS-fMRI. Brain Topogr., 24, 302-315.
– reference: Allan, C.H. (2000) Functional results of primary nerve repair. Hand Clin., 16, 67-72.
– reference: Rosen, B. & Lundborg, G. (2003) A new model instrument for outcome after nerve repair. Hand Clin., 19, 463-470.
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– reference: Ruijs, A.C., Jaquet, J.B., Kalmijn, S., Giele, H. & Hovius, S.E. (2005) Median and ulnar nerve injuries: a meta-analysis of predictors of motor and sensory recovery after modern microsurgical nerve repair. Plast. Reconstr. Surg., 116, 484-494.
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– reference: Hansson, T. & Brismar, T. (2003) Loss of sensory discrimination after median nerve injury and activation in the primary somatosensory cortex on functional magnetic resonance imaging. J. Neurosurg., 99, 100-105.
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– reference: Talairach, J. & Tournoux, P. (1988) Co-Planar Stereotaxic Atlas of the Human Brain: An Approach to Cerebral Imaging. G. Thieme; Thieme Medical Publishers, Stuttgart, New York.
– reference: Frykman, G.K. (1976) Peripheral nerve injuries in children. Orthop. Clin. N. Am., 7, 701-716.
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– reference: Hoke, A. & Brushart, T. (2010) Introduction to special issue: challenges and opportunities for regeneration in the peripheral nervous system. Exp. Neurol., 223, 1-4.
– reference: Weibull, A., Bjorkman, A., Hall, H., Rosen, B., Lundborg, G. & Svensson, J. (2008) Optimizing the mapping of finger areas in primary somatosensory cortex using functional MRI. Magn. Reson. Imaging, 26, 1342-1351.
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Snippet The clinical outcome following a peripheral nerve injury in the upper extremity is generally better in young children than in teenagers and in adults, but the...
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pubmed
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wiley
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SourceType Open Access Repository
Aggregation Database
Index Database
Enrichment Source
Publisher
StartPage 2022
SubjectTerms Adolescent
Age Factors
Basic Medicine
Child
Child, Preschool
cortical plasticity
Electric Stimulation
Female
Functional Laterality - physiology
functional recovery
Humans
Image Processing, Computer-Assisted
Infant
Longitudinal Studies
Magnetic Resonance Imaging
Male
Medical and Health Sciences
Medicin och hälsovetenskap
Medicinska och farmaceutiska grundvetenskaper
MRI
Neural Conduction - physiology
Neurosciences
Neurovetenskaper
Oxygen - blood
Peripheral Nerve Injuries - pathology
Peripheral Nerve Injuries - physiopathology
Peripheral Nerve Injuries - surgery
peripheral nerve injury
Recovery of Function - physiology
Retrospective Studies
Severity of Illness Index
Somatosensory Cortex - blood supply
Somatosensory Cortex - physiopathology
Young Adult
Title Normalized activation in the somatosensory cortex 30 years following nerve repair in children: an fMRI study
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https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fejn.12917
https://www.ncbi.nlm.nih.gov/pubmed/25865600
https://www.proquest.com/docview/1705009910
Volume 42
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