Yonsei Med J.
2011 Jul;52(4):553-557. 10.3349/ymj.2011.52.4.553.
Somatotopic Arrangement and Location of the Corticospinal Tract in the Brainstem of the Human Brain
- Affiliations
-
- 1Department of Physical Medicine and Rehabilitation, College of Medicine, Yeungnam University, Daegu, Korea. strokerehab@hanmail.net
- KMID: 1727984
- DOI: http://doi.org/10.3349/ymj.2011.52.4.553
Abstract
- The corticospinal tract (CST) is the most important motor pathway in the human brain. Detailed knowledge of CST somatotopy is important in terms of rehabilitative management and invasive procedures for patients with brain injuries. In this study, I conducted a review of nine previous studies of the somatotopical location and arrangement at the brainstem in the human brain. The results of this review indicated that the hand and leg somatotopies of the CST are arranged medio-laterally in the mid to lateral portion of the cerebral peduncle, ventromedial-dorsolaterally in the pontine basis, and medio-laterally in the medullary pyramid. However, few diffusion tensor imaging (DTI) studies have been conducted on this topic, and only nine have been reported: midbrain (2 studies), pons (4 studies), and medulla (1 study). Therefore, further DTI studies should be conducted in order to expand the literature on this topic. In particular, research on midbrain and medulla should be encouraged.
Keyword
MeSH Terms
Cited by 2 articles
-
Characteristics of Corticospinal Tract Area According to Pontine Level
Jeong Pyo Seo, Sung Ho Jang
Yonsei Med J. 2013;54(3):785-787. doi: 10.3349/ymj.2013.54.3.785.Association of Dysphagia With Supratentorial Lesions in Patients With Middle Cerebral Artery Stroke
Bo-Ram Kim, Won-Jin Moon, Hyuntae Kim, Eunhwa Jung, Jongmin Lee
Ann Rehabil Med. 2016;40(4):637-646. doi: 10.5535/arm.2016.40.4.637.
Reference
-
1. Afifi AK, Bergman RA. Functional neuroanatomy: text and atlas. 2005. 2nd ed. New York: Lange Medical Books/McGraw-Hill.2. Cho SH, Kim SH, Choi BY, Cho SH, Kang JH, Lee CH, et al. Motor outcome according to diffusion tensor tractography findings in the early stage of intracerebral hemorrhage. Neurosci Lett. 2007. 421:142–146.
Article3. Davidoff RA. The pyramidal tract. Neurology. 1990. 40:332–339.
Article4. Jang SH. The role of the corticospinal tract in motor recovery in patients with a stroke: a review. NeuroRehabilitation. 2009. 24:285–290.
Article5. Ahn YH, Ahn SH, Kim H, Hong JH, Jang SH. Can stroke patients walk after complete lateral corticospinal tract injury of the affected hemisphere? Neuroreport. 2006. 17:987–990.
Article6. Binkofski F, Seitz RJ, Arnold S, Classen J, Benecke R, Freund HJ. Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke. Ann Neurol. 1996. 39:460–470.
Article7. Hallett M, Wassermann EM, Cohen LG, Chmielowska J, Gerloff C. Cortical mechanisms of recovery of function after stroke. Neurorehabilitation. 1998. 10:131–142.
Article8. Bassetti C, Bogousslavsky J, Barth A, Regli F. Isolated infarcts of the pons. Neurology. 1996. 46:165–175.
Article9. Han BS, Hong JH, Hong C, Yeo SS, Lee D, Cho HK, et al. Location of the corticospinal tract at the corona radiata in human brain. Brain Res. 2010. 1326:75–80.
Article10. Holodny AI, Gor DM, Watts R, Gutin PH, Ulug AM. Diffusion-tensor MR tractography of somatotopic organization of corticospinal tracts in the internal capsule: initial anatomic results in contradistinction to prior reports. Radiology. 2005. 234:649–653.
Article11. Hong JH, Son SM, Jang SH. Somatotopic location of corticospinal tract at pons in human brain: a diffusion tensor tractography study. Neuroimage. 2010. 51:952–955.
Article12. Ino T, Nakai R, Azuma T, Yamamoto T, Tsutsumi S, Fukuyama H. Somatotopy of corticospinal tract in the internal capsule shown by functional MRI and diffusion tensor images. Neuroreport. 2007. 18:665–668.
Article13. Jang SH. A review of corticospinal tract location at corona radiata and posterior limb of the internal capsule in human brain. NeuroRehabilitation. 2009. 24:279–283.
Article14. Kim JS, Pope A. Somatotopically located motor fibers in corona radiata: evidence from subcortical small infarcts. Neurology. 2005. 64:1438–1440.
Article15. Kim YH, Kim DS, Hong JH, Park CH, Hua N, Bickart KC, et al. Corticospinal tract location in internal capsule of human brain: diffusion tensor tractography and functional MRI study. Neuroreport. 2008. 19:817–820.
Article16. Kwon HG, Hong JH, Lee MY, Kwon YH, Jang SH. Somatotopic arrangement of the corticospinal tract at the medullary pyramid in the human brain. Eur Neurol. 2011. 65:46–49.
Article17. Marx JJ, Iannetti GD, Thömke F, Fitzek S, Urban PP, Stoeter P, et al. Somatotopic organization of the corticospinal tract in the human brainstem: a MRI-based mapping analysis. Ann Neurol. 2005. 57:824–831.
Article18. Park JK, Kim BS, Choi G, Kim SH, Choi JC, Khang H. Evaluation of the somatotopic organization of corticospinal tracts in the internal capsule and cerebral peduncle: results of diffusion-tensor MR tractography. Korean J Radiol. 2008. 9:191–195.
Article19. Schmahmann JD, Ko R, MacMore J. The human basis pontis: motor syndromes and topographic organization. Brain. 2004. 127:1269–1291.
Article20. Song YM. Somatotopic organization of motor fibers in the corona radiata in monoparetic patients with small subcortical infarct. Stroke. 2007. 38:2353–2355.
Article21. Tohgi H, Takahashi S, Takahashi H, Tamura K, Yonezawa H. The side and somatotopical location of single small infarcts in the corona radiata and pontine base in relation to contralateral limb paresis and dysarthria. Eur Neurol. 1996. 36:338–342.
Article22. Carpenter MB. Core text of neuroanatomy. 1985. 3rd ed. Baltimore: Williams & Wilkins.23. Bouchareb M, Moulin T, Cattin F, Dietemann JL, Racle A, Verdot H, et al. Wallerian degeneration of the descending tracts. CT and MRI features of the brain stem. J Neuroradiol. 1988. 15:238–252.24. Kobayashi S, Hasegawa S, Maki T, Murayama S. Retrograde degeneration of the corticospinal tract associated with pontine infarction. J Neurol Sci. 2005. 236:91–93.
Article25. Mark VW, Taub E, Perkins C, Gauthier LV, Uswatte G, Ogorek J. Poststroke cerebral peduncular atrophy correlates with a measure of corticospinal tract injury in the cerebral hemisphere. AJNR Am J Neuroradiol. 2008. 29:354–358.
Article26. Mori S, Crain BJ, Chacko VP, van Zijl PC. Three-dimensional tracking of axonal projections in the brain by magnetic resonance imaging. Ann Neurol. 1999. 45:265–269.
Article27. Quiñones-Hinojosa A, Lyon R, Du R, Lawton MT. Intraoperative motor mapping of the cerebral peduncle during resection of a midbrain cavernous malformation: technical case report. Neurosurgery. 2005. 56:E439.
Article28. Stovring J, Fernando LT. Wallerian degeneration of the corticospinal tract region of the brain stem: demonstration by computed tomography. Radiology. 1983. 149:717–720.
Article29. Uchino A, Imada H, Ohno M. MR imaging of wallerian degeneration in the human brain stem after ictus. Neuroradiology. 1990. 32:191–195.
Article30. Uchino A, Onomura K, Ohno M. Wallerian degeneration of the corticospinal tract in the brain stem: MR imaging. Radiat Med. 1989. 7:74–78.31. Warabi T, Miyasaka K, Inoue K, Nakamura N. Computed tomographic studies of the basis pedunculi in chronic hemiplegic patients: topographic correlation between cerebral lesion and midbrain shrinkage. Neuroradiology. 1987. 29:409–415.
Article32. Westerhausen R, Huster RJ, Kreuder F, Wittling W, Schweiger E. Corticospinal tract asymmetries at the level of the internal capsule: is there an association with handedness? Neuroimage. 2007. 37:379–386.
Article33. Yamada K, Kizu O, Kubota T, Ito H, Matsushima S, Oouchi H, et al. The pyramidal tract has a predictable course through the centrum semiovale: a diffusion-tensor based tractography study. J Magn Reson Imaging. 2007. 26:519–524.
Article34. Martinez SN, Bertrand C, Botana-Lopez C. Motor fiber distribution within the cerebral peduncle. Results of unipolar stimulation. Confin Neurol. 1967. 29:117–122.35. Schneider R, Gautier JC. Leg weakness due to stroke. Site of lesions, weakness patterns and causes. Brain. 1994. 117:347–354.
Article36. Waragai M, Watanabe H, Iwabuchi S. The somatotopic localisation of the descending cortical tract in the cerebral peduncle: a study using MRI of changes following Wallerian degeneration in the cerebral peduncle after a supratentorial vascular lesion. Neuroradiology. 1994. 36:402–404.
Article37. Bucy PC, Keplinger JE, Siqueira EB. Destruction of the "Pyramidal Tract" in man. J Neurosurg. 1964. 21:285–298.
Article38. Jane JA, Yashon D, Becker DP, Beatty R, Sugar O. The effect of destruction of the corticospinal tract in the human cerebral peduncle upon motor function and involuntary movements. Report of 11 cases. J Neurosurg. 1968. 29:581–585.
Article39. Mori S, van Zijl PC. Fiber tracking: principles and strategies - a technical review. NMR Biomed. 2002. 15:468–480.
Article40. Newton JM, Ward NS, Parker GJ, Deichmann R, Alexander DC, Friston KJ, et al. Non-invasive mapping of corticofugal fibres from multiple motor areas--relevance to stroke recovery. Brain. 2006. 129:1844–1858.
Article41. Kumral E, Bayülkem G, Evyapan D. Clinical spectrum of pontine infarction. Clinical-MRI correlations. J Neurol. 2002. 249:1659–1670.42. Chen DQ, Quan J, Guha A, Tymianski M, Mikulis D, Hodaie M. Three dimensional in vivo modelling of vestibular schwannomas and surrounding cranial nerves using diffusion imaging tractography. Neurosurgery. 2011.43. Hodaie M, Quan J, Chen DQ. In vivo visualization of cranial nerve pathways in humans using diffusion-based tractography. Neurosurgery. 2010. 66:788–795.
Article
- Full Text Links
-
- Actions
-
Cited
- CITED
-
- Close
- Share
-
- Similar articles
-
- Evaluation of the Somatotopic Organization of Corticospinal Tracts in the Internal Capsule and Cerebral Peduncle: Results of Diffusion-Tensor MR Tractography
- Dysgeusia as Anti-GQ1b Antibody Syndrome with Brainstem Involvement: A Tractography Case Report
- Dysphagia Pattern according to Stroke Location
- Characteristics of Corticospinal Tract Area According to Pontine Level
- Brainstem Auditory Evoked Potential in a Case of Severe Carbon Monoxide Intoxication
