Blood supply to the corticospinal tract: A pictorial review with application to cranial surgery and stroke.

The corticospinal tract (CST) is the main neural pathway responsible for conducting voluntary motor function in the central nervous system. The CST condenses into fiber bundles as it descends from the frontoparietal cortex, traveling down to terminate at the anterior horn of the spinal cord. The CST is at risk of injury from vascular insult from strokes and during neurosurgical procedures. The aim of this article is to identify and describe the vasculature associated with the CST from the cortex to the medulla. Dissection of cadaveric specimens was carried out in a manner, which exposed and preserved the fiber tracts of the CST, as well as the arterial systems that supply them. At the level of the motor cortex, the CST is supplied by terminal branches of the anterior cerebral artery and middle cerebral artery. The white matter tracts of the corona radiata and internal capsule are supplied by small perforators including the lenticulostriate arteries and branches of the anterior choroidal artery. In the brainstem, the CST is supplied by anterior perforating branches from the basilar and vertebral arteries. The caudal portions of the CST in the medulla are supplied by the anterior spinal artery, which branches from the vertebral arteries. The non-anastomotic nature of the vessel systems of the CST highlights the importance of their preservation during neurosurgical procedures. Anatomical knowledge of the CST is paramount to clinical diagnosis and treatment of heterogeneity of neurodegenerative, neuroinflammatory, cerebrovascular, and skull base tumors.

Isolated Infarction of the Medullary Pyramid - A Rare Pure Motor Stroke.

Acute pure motor hemiparesis can occur due to a vascular insult along the cortico spinal pathway. Rarely such a stroke can occur as a result of involvement of the pyramids located on the ventral aspect of the medulla. Neurological localization can be difficult in such strokes and moreover they can also pose imaging challenges since they are missed on the CT scans. So far only 4 such cases have been reported in literature. Here we present two cases of pure motor strokes caused by infarction of the medullary pyramids. We have described the anatomical correlates of the symptoms and signs and also highlight the importance of MRI in picking up these rare strokes.

Recovery process of bilaterally injured corticoreticulospinal tracts in a patient with subarachnoid hemorrhage: Case report.

RATIONALE: A few studies using diffusion tensor tractography (DTT) have demonstrated recovery of injured corticoreticulospinal tract (CRT) in patients with intracerebral hemorrhage and infarct. However, no study reported on a patient who showed peri-infarct reorganization of an injured CRT following a middle cerebral artery territory infarct. PATIENT CONCERNS: A 56-year-old right-handed male patient was diagnosed as spontaneous subarachnoid hemorrhage (SAH) and intraventricular hemorrhage (IVH) and underwent clipping for a ruptured anterior communicating artery aneurysm and right frontal extraventricular drainage for IVH at the department of neurosurgery of a university hospital. After onset, he presented with complete weakness of both legs. DIAGNOSES: The patient was diagnosed as spontaneous SAH and IVH. INTERVENTIONS: Clinical assessment and DTT were performed at 1, 3, 6, and 20 months after onset. OUTCOMES: The weakness of both legs showed slow recovery for 10 months until 11 months after onset (medical research council: 6 months; 3/3 and 11 months; 4/4). As a result, he was able to walk independently on an even floor at 6 months and on stairs at 11 months after onset. The discontinued both CRTs on 1-month DTT were restored to the cerebral cortex on 3-month DTT, and then thickened consecutively on 6-month and 20-month DTTs. LESSONS: The recovery process of injured CRTs concurrent with recovery of leg weakness was demonstrated in a patient with SAH using DTT. This study has important implications in terms of regaining gait function by the recovery of bilaterally injured CRTs which was facilitated by the long-term rehabilitation.

Identification of Corticospinal Tract Lesion for Predicting Outcome in Small Perfusion Stroke.

Background and Purpose- Whether patients with small perfusion lesions benefit from thrombolysis remains an uncertainty. We assessed acute ischemic stroke patients with a total perfusion lesion of <15 mL and tested the hypothesis the pattern of corticospinal tract (CST) involvement might predict outcome in thrombolysis-eligible patients. Methods- We used a prospectively collected cohort of acute ischemic stroke patients being assessed for thrombolysis at 7 centers. Three neurologists categorized the presence of hypoperfusion and infarction within CST. Excellent outcome was defined as 90-day modified Rankin Scale score 0 to 1. Results- Of 2654 patients, 407 had a perfusion lesion <15 mL and were clinically eligible for thrombolysis (243 being treated). Median National Institutes of Health Stroke Scale was 5.0, and 312 (76.7%) patients achieved excellent outcome. Alteplase treatment was an independent unfavorable factor for excellent outcome (alteplase-treated 72.0% versus untreated 83.5%; odds ratio, 0.541; P=0.025). For patients with CST hypoperfusion without CST infarction, alteplase treatment was an independent favorable factor for excellent outcome (alteplase-treated 75.6% versus untreated 47.1%; odds ratio, 4.096; P=0.045). Among patients with CST infarction, alteplase treatment was an independent unfavorable factor for excellent outcome (alteplase-treated 30.6% versus untreated 88.9%; odds ratio, 0.002; P=0.003). Among patients without either CST hypoperfusion or CST infarction, alteplase treatment was not an independent influencing factor for excellent outcome (alteplase-treated 80.1% versus untreated 87.7%; P=0.258). Conclusions- Only patients with CST hypoperfusion without CST infarction among eligible acute ischemic stroke patients with small perfusion lesions could benefit from thrombolysis, which needs to be confirmed in future prospective studies. Patient selection, including an assessment of lesion location rather than purely lesion volume, may be ideal.

Impact of perfusion lesion in corticospinal tract on response to reperfusion.

OBJECTIVES: We aimed to examine the impact of corticospinal tract (CST) involvement in acute ischaemic stroke (AIS) patients on functional outcome and the interaction with reperfusion. METHODS: We retrospectively examined data in consecutive anterior circulation AIS patients undergoing thrombolysis. MR perfusion (time to maximum of tissue residue function, Tmax) and apparent diffusion coefficient (ADC) images were transformed into standard space and the volumes of CST involvement by Tmax > 6 s (CST-Tmax) and ADC < 620 × 10-6 mm2/s (CST-ADC) lesions were calculated. Good outcome was defined as modified Rankin scale ≤ 2 at 3 months. Reperfusion was defined as a reduction in Tmax > 6 s lesion volume of ≥70% between baseline and 24 h. RESULTS: 82 patients were included. Binary logistic regression revealed that both CST-Tmax and CST-ADC volume at baseline were significantly associated with poor outcome (p < 0.05). The 24-h CST-ADC volume was correlated with baseline CST-ADC volume in patients with reperfusion (r = 0.79, p < 0.001) and baseline CST-Tmax volume in patients without reperfusion (r = 0.67, p < 0.001). In patients with CST-Tmax volume > 0 mL and CST-ADC volume < 3 mL, the rate of good outcome was higher in patients with reperfusion than those without (70.4% vs 38.1%, p = 0.04). CONCLUSIONS: The use of CST-Tmax in combination with CST-ADC provides prognostic information in patients considered for reperfusion therapies. KEY POINTS: • Examine the impact of corticospinal tract involvement in acute ischaemic stroke patients. • Spatially registered Tmax images can identify corticospinal tract hypoperfusion injury. • Corticospinal tract salvage through reperfusion is associated with improved outcome.

Intraoperative Visualization of Subependymal Arteries at the Atrium Supplying the Descending Motor Pathway.

OBJECTIVE: We previously disclosed that damage to the subependymal arteries (SEAs) caused by coagulation of the choroid plexus at the atrium can result in infarction within the lateral posterior choroidal artery territory, followed by hemiparesis. The present study describes the intraoperative anatomical findings of the SEAs and choroid plexus at the atrium, which were verified only by a few cadaveric studies. METHODS: Locations of the SEA and descending motor pathway were determined with the neuronavigation system and subcortical electrical stimulation in 8 cases of periatrial brain tumor. Indocyanine green videoangiography was performed to verify the blood flow in the choroid plexus and SEAs. RESULTS: Intraoperative visualization of the SEAs was performed successfully in all patients. The neuronavigation system and subcortical electrical stimulation mapping demonstrated that these SEAs penetrated into the descending motor pathway. Indocyanine green depicted the blood flow of the SEAs entering the wall of the lateral ventricle and adjacent brain parenchyma. The blood flow directions between the SEAs and choroid plexus were not uniform, because the SEAs were filled ahead of the choroid plexus in 3 cases, whereas the choroid plexus was filled first in the other 2 cases. CONCLUSIONS: Manipulations to the inner side of the choroid plexus at the transition from the atrium to the body of lateral ventricle can damage the SEAs. Not only coagulation of the SEAs themselves, but also coagulation of choroid plexus itself may reduce the blood flow in the SEAs, resulting in ischemic complications at descending motor pathway.

Preoperative Functional Findings and Surgical Outcomes in Patients with Motor Cortical Arteriovenous Malformation.

OBJECTIVE: The relationship between preoperative functional findings, derived from functional magnetic resonance imaging and diffusion tensor imaging, and surgical outcomes in patients with motor cortical arteriovenous malformations (AVMs) has not been determined. The aim of this study was to determine the relationship between preoperative functional findings and surgical outcomes in patients with motor cortical AVM. METHODS: Fifteen patients with AVM involving the precentral knob and/or paracentral lobule were reviewed. Each motor function involved was examined as an independent object. Preoperative functional findings included cortical reorganization, activation around the nidus, corticospinal tract (CST) reorganization, nidus involving the CST, and the level of the CST involved. The relationship between preoperative functional findings and surgical outcomes was analyzed statistically. A muscle strength of grade 3 or less was defined as a poor outcome after surgery, and a muscle strength of grade 4 or greater was defined as a good outcome. RESULTS: Eighteen objects were created and analyzed. Cortical reorganization (P = 1.000) was not correlated with surgical outcomes. However, nidus involving the CST was significantly associated with poor short-term outcomes (1 week after surgery) (P = 0.028) and permanent deficit in muscle strength (P = 0.042). Most of the objects had good outcomes (16/18, 88.9%) at 6 months after surgery (long-term outcomes). Only 1 patient with CST ruptured at the corona radiata level and 1 patient who had postoperative hemorrhage obtained poor long-term outcomes. CONCLUSIONS: Nidus involving the CST and the level of the CST involved, rather than cortical reorganization, may be associated with surgical outcomes in patients with motor cortical AVM.

Comparison of different tractography algorithms and validation by intraoperative stimulation in a child with a brain tumor.

BACKGROUND: Advanced modalities such as functional magnetic resonance imaging (MRI) and diffusion MR tractography offer in vivo information about brain networks and are therefore increasingly used for neurosurgical planning in children also. AIM: This study aims to study the application of routine and advanced tractography algorithms and its comparison with intraoperative subcortical electrical stimulation. METHOD: Presurgical functional MRI and MR diffusion tractography were performed on a 6-year-old patient presenting with seizures, but no motor symptoms, due to a neuroectodermal tumor in the left central region. Three different tractography algorithms were compared: deterministic diffusion tensor imaging (DTI)-tracking, probabilistic DTI-tracking, and probabilistic constrained spherical deconvolution tracking (pCSD). RESULTS: All three tractography algorithms could localize the core of the corticospinal tract with good agreement. The pCSD-tracking algorithm was more sensitive in revealing the anatomically most realistic fiber distribution and a proportion of fibers traversing a solid part of the tumor. Intraoperative stimulation confirmed these fibers close to the tumor. As a result, only a subtotal resection was performed, preventing postoperative sensorimotor deficits. CONCLUSION: Although, all tractography algorithms successfully identified the core of the corticospinal pathway, deterministic DTI-tractography, as widely used in clinical neuronavigation software, only insufficiently visualized critical fibers here. We believe these results argue for a stronger consideration of advanced tractography approaches in neurosurgical planning.

Factors related to executive dysfunction after acute infarct.

AIM: The aim of this study was to investigate the association of infarct location with post-stroke executive dysfunction. METHODS: One hundred seventy-seven patients hospitalized with acute infarction were enrolled. General information and NIHSS score at admission were recorded. The infarct site was recorded from magnetic resonance T2-W1 and FLAIR images, and the extent of white matter disease was assessed using the Fazekas score. Seven days after symptoms, executive function was assessed using the validated Chinese version of Mattis Dementia Rating Scale (MDRS) Initiation/Perseveration (I/P) [MDRS I/P]. RESULTS: The average MDRS I/P score of the 177 infarction patients was 24.16 ± 5.21, considerably lower than the average score (32.7 ± 3.1) of a control group of normal individuals. Patients with infarcts in the corona radiata or basal ganglia had significantly lower MDRS I/P scores that those without infarcts at these locations. The number of infarcts in the basal ganglia was also significantly associated with low MDRS I/P scores. Male gender and low NIHSS score were significantly associated with low MDRS I/P score, and high-density lipoprotein cholesterol was significantly associated with high MDRS I/P score. The number of infarcts in areas other than the basal ganglia as well as corona radiata and the extent of white matter disease had no influence on this score. CONCLUSIONS: The number of infarcts in the basal ganglia corona radiata, low NIHSS score, and male gender are significantly and independently related to poor executive function (that is, low MDRS I/P score) after acute infarct.

Corticospinal excitability as a predictor of functional gains at the affected upper limb following robotic training in chronic stroke survivors.

BACKGROUND: Robotic training can help improve function of a paretic limb following a stroke, but individuals respond differently to the training. A predictor of functional gains might improve the ability to select those individuals more likely to benefit from robot-based therapy. Studies evaluating predictors of functional improvement after a robotic training are scarce. One study has found that white matter tract integrity predicts functional gains following a robotic training of the hand and wrist. Objective. To determine the predictive ability of behavioral and brain measures in order to improve selection of individuals for robotic training. METHODS: Twenty subjects with chronic stroke participated in an 8-week course of robotic exoskeletal training for the arm. Before training, a clinical evaluation, functional magnetic resonance imaging (fMRI), diffusion tensor imaging, and transcranial magnetic stimulation (TMS) were each measured as predictors. Final functional gain was defined as change in the Box and Block Test (BBT). Measures significant in bivariate analysis were fed into a multivariate linear regression model. RESULTS: Training was associated with an average gain of 6 ± 5 blocks on the BBT (P < .0001). Bivariate analysis revealed that lower baseline motor-evoked potential (MEP) amplitude on TMS, and lower laterality M1 index on fMRI each significantly correlated with greater BBT change. In the multivariate linear regression analysis, baseline MEP magnitude was the only measure that remained significant. CONCLUSION: Subjects with lower baseline MEP magnitude benefited the most from robotic training of the affected arm. These subjects might have reserve remaining for the training to boost corticospinal excitability, translating into functional gains.

Early frontal structural and functional changes in mild white matter lesions relevant to cognitive decline.

White matter lesions (WMLs) are of considerable research interest because of their high prevalence and serious consequences, such as stroke and dementia. Most existing studies of WMLs have focused on severe WMLs, but mild WMLs, which are clinically and fundamentally significant, have been largely neglected. The present study is a comprehensive investigation on the injury pattern and on the anatomical, functional, and cognitive changes related to mild WMLs. These results may provide better understanding mild WMLs. Fifty-one human subjects with mild WMLs and 49 control participants completed serial neuropsychological tests and underwent a 3-T magnetic resonance imaging (MRI) scan that included diffusion tensor imaging, a resting-state functional MRI, and a structural MRI. We found declines in cognitive functions such as global function, executive function, and episodic memory in mild WMLs subjects. The white matter injuries in the mild WMLs subjects were mainly in the fibers that projected to frontal areas, while gray matter structures were relatively intact. The overall resting state function of the frontal area was significantly increased. The integrity of the neural fibers in the inferior fronto-occipital fasciculus and the inferior longitudinal fasciculus was significantly correlated with the cognitive scores in executive function and episodic memory in both the control and the mild WMLs group. These findings demonstrate that mild WMLs subjects exhibit abnormalities in both white matter structure and functional intrinsic brain activity and that such changes are related to several types of cognitive dysfunction.

Anatomical location of the frontopontine fibers in the internal capsule in the human brain: a diffusion tensor tractography study.

The frontopontine fibers (FPFs) originate from the frontal lobe and end in the pontine nuclei. Many neuroanatomy textbooks have described the FPFs as descending through the anterior limb of the internal capsule. However, several studies have reported controversial results. In this study, using diffusion tensor tractography, we investigated the anatomical location of the FPFs in the internal capsule in the human brain. We recruited 53 healthy volunteers for this study. For reconstruction of the FPFs, the seed region of interest was given in the medial cerebral peduncle of the reconstructed corticospinal tract. The target regions of interest were placed in the three cerebral cortices, respectively: Brodmann's area (BA) BA 6, BA 8, and BA 9. The anatomical locations of the FPFs were evaluated using the highest probabilistic location in the internal capsule. We measured the relative distance of the FPFs from the middle point at the genu of the internal capsule to the most posterior point of the lenticular nucleus. The relative mean distances of the highest probabilistic location for the FPFs from BA 9, 8, and 6 were 18.18, 32.08, and 43.83% from the middle point of the genu of the internal capsule, respectively. By contrast, the highest probabilistic location for the corticospinal tract was 74.18%. According to our findings, the FPFs were located at the anterior half of the posterior limb in the internal capsule, in the following order, from the anterior direction: the FPFs from BA 9, BA 8, and BA 6.

Interhemispheric functional connectivity following prenatal or perinatal brain injury predicts receptive language outcome.

Early brain injury alters both structural and functional connectivity between the cerebral hemispheres. Despite increasing knowledge on the individual hemispheric contributions to recovery from such injury, we know very little about how their interactions affect this process. In the present study, we related interhemispheric structural and functional connectivity to receptive language outcome following early left hemisphere stroke. We used functional magnetic resonance imaging to study 14 people with neonatal brain injury, and 25 age-matched controls during passive story comprehension. With respect to structural connectivity, we found that increased volume of the corpus callosum predicted good receptive language outcome, but that this is not specific to people with injury. In contrast, we found that increased posterior superior temporal gyrus interhemispheric functional connectivity during story comprehension predicted better receptive language performance in people with early brain injury, but worse performance in typical controls. This suggests that interhemispheric functional connectivity is one potential compensatory mechanism following early injury. Further, this pattern of results suggests refinement of the prevailing notion that better language outcome following early left hemisphere injury relies on the contribution of the contralesional hemisphere (i.e., the "right-hemisphere-take-over" theory). This pattern of results was also regionally specific; connectivity of the angular gyrus predicted poorer performance in both groups, independent of brain injury. These results present a complex picture of recovery, and in some cases, such recovery relies on increased cooperation between the injured hemisphere and homologous regions in the contralesional hemisphere, but in other cases, the opposite appears to hold.

An intraoperative multimodal neurophysiologic approach to successful resection of precentral gyrus epileptogenic lesions.

Cortical dysplasias (CDs) are highly epileptogenic lesions with a good prognosis of seizure freedom, if totally resected. However, their accurate delineation and resection can be difficult, and depend on the extent of pathology and lesion location. Intraoperative neurophysiologic assessments are valuable in these situations. We present an illustrative case of intractable epilepsy where judicious use of intraoperative neurophysiologic-techniques guided resection of precentral CD, under general anesthesia and in the absence of preoperative electrophysiologic mapping data. Ictal onset was accurately delineated using electrocorticography (ECoG). Phase reversal of the median somatosensory-evoked potentials (MSSEPs) localized the central sulcus (CS). Motor evoked potentials (MEPs) triggered by high-frequency monopolar anodal electrical cortical stimulation at the primary motor cortex (PMC) threshold delineated the PMC. Using this technique, PMC and the corticospinal tract (CST) were continuously monitored during resection. No changes in MEPs from the preresection baseline were seen; no residual abnormal activity was present in the postresection ECoG. The patient emerged from surgery without deficits and has been seizure free during a 10-month follow-up. Staged multimodal intraoperative neurophysiology can be used successfully under general anesthesia to guide resection of epileptogenic lesions within the precentral gyrus, as an add-on or, in certain situations, as a viable alternative to preoperative electrophysiologic mapping.

Ischemic stroke of the pyramidal decussation causing quadriplegia and anarthria.

A 52-year-old man with a history of hypertension and previously irradiated head and neck cancer presented with quadriplegia and anarthria sparing the face and sensory functions. Brain magnetic resonance imaging (MRI) demonstrated acute infarction of the pyramidal decussation. We describe the clinical and radiological characteristics of infarction at the pyramidal decussation and review the arterial supply to this region in the lower brainstem. Although rare, infarction of the pyramidal decussation should be considered in the differential diagnosis when patients present with atraumatic pure motor quadriplegia.

Motor function reorganization in a patient with a brainstem lesion: DTT, fMRI and TMS study.

OBJECTIVE: We report on a hemiparetic patient who showed a new motor pathway posterior to the lesion in the midbrain and upper pons, demonstrated by three combined method of diffusion tensor tractography(DTT)/functional MRI(fMRI)/transcranial magnetic stimulation(TMS). METHODS: A 21-year-old left hemiparetic male who suffered from tuberous meningitis at the age of 12 months after birth. The evaluations were performed at 20 years after onset. Brain MRI showed focal encephalomalatic lesions~due to infarcts in right anterior thalamus, midbrain and upper pons. DTT, fMRI and TMS were performed simultaneously. RESULTS: The contralateral primary sensori-motor cortex was activated during either affected or unaffected hand movements. DTT showed that the motor tracts descended along the known pathway of the CST, with the exception of the motor tract of the affected hemisphere, which descended along the posterior portion to the lesion in the right midbrain and the pons, and then rejoined the CST in the mid-pons. The TMS results suggested that the motor tract of the affected hemisphere had the characteristics of a CST. CONCLUSION: We believe that the motor function of the affected hand in this patient had been recovered through the pathway posterior to the lesion in the midbrain and upper pons.

Location of the corticospinal tract at the corona radiata in human brain.

Little is known about the location of the corticospinal tract (CST) at the corona radiata (CR). In the current study we attempted to elucidate the location of the CST for the hand at the CR using diffusion tensor tractography analysis based on functional MRI activation results. Functional MRI was performed at 1.5-T with timed hand grasp-release movements, and diffusion tensor tractography was performed using a Synergy-L Sensitivity Encoding (SENSE) head coil. Probabilistic mapping was obtained for 16 normal subjects using areas of functional MRI activation as the first region of interest (ROI 1) and the CST area in the lower pons as the second region of interest (ROI 2). The authors measured the antero-posterior and medio-lateral locations of pixels in the CST in two areas of the CR (CR 1 - the first axial image to show the septum pellucidum and the body of the fornix from the vertex, and CR 2 - the axial image showing the insular gyrus). The most probable locations in the medio-lateral direction (from the most medial point of the lateral ventricle wall to the most lateral point of the cerebral cortex) were 24.2% in both CR 1 and 2, and the most probable locations in the antero-posterior direction (from the most anterior point of the lateral ventricle to the most posterior point of the lateral ventricle) were 66.7 and 63.6% in CR 1 and 2, respectively. It was found that the CST for the hand descended through about one quarter (medio-lateral direction) and two-thirds (antero-posterior direction) at the CR.

Rewiring of hindlimb corticospinal neurons after spinal cord injury.

Little is known about the functional role of axotomized cortical neurons that survive spinal cord injury. Large thoracic spinal cord injuries in adult rats result in impairments of hindlimb function. Using retrograde tracers, we found that axotomized corticospinal axons from the hindlimb sensorimotor cortex sprouted in the cervical spinal cord. Mapping of these neurons revealed the emergence of a new forelimb corticospinal projection from the rostral part of the former hindlimb cortex. Voltage-sensitive dye (VSD) imaging and blood-oxygen-level-dependent functional magnetic resonance imaging (BOLD fMRI) revealed a stable expansion of the forelimb sensory map, covering in particular the former hindlimb cortex containing the rewired neurons. Therefore, axotomized hindlimb corticospinal neurons can be incorporated into the sensorimotor circuits of the unaffected forelimb.

Double decussated ipsilateral corticospinal tract in schizencephaly.

We report a patient with left hemiparesis because of schizencephaly affecting the right precentral gyrus and describe a double decussated ipsilateral corticospinal tract detected using the multimodal brain mapping technique. In this patient, we could observe that the unaffected primary motor cortex (M1) controls both hands by functional magnetic resonance imaging and motor-evoked potential study. We were also able to visualize the corticospinal tract originating from the unaffected M1 that passed through the internal capsule and cerebral peduncle on the same side. It then crossed over twice at the brain stem level to go down to the ipsilateral spinal cord. These findings show a unique pattern of brain reorganization in the recovery from early brain injury.