Dynamic changes in spatial representation within the posterior parietal cortex in response to visuomotor adaptation.

Recent studies used functional magnetic resonance imaging (fMRI) population receptive field (pRF) mapping to demonstrate that retinotopic organization extends from the primary visual cortex to ventral and dorsal visual pathways, by quantifying visual field maps, receptive field size, and laterality throughout multiple areas. Visuospatial representation in the posterior parietal cortex (PPC) is modulated by attentional deployment, raising the question of whether spatial representation in the PPC is dynamic and flexible, and whether this flexibility contributes to visuospatial learning. To answer this question, changes in spatial representation within the PPC and early visual cortex were recorded with pRF mapping before and after prism adaptation (PA)-a well-established visuomotor technique that modulates visuospatial attention according to the direction of the visual displacement. As predicted, results showed that adaptation to left-shifting prisms increases pRF size in left PPC, while leaving space representation in the early visual cortex unchanged. This is the first evidence that PA drives a dynamic reorganization of response profiles in the PPC. These findings show that spatial representations in the PPC not only reflect changes driven by attentional deployment but dynamically change in response to modulation of external factors such as manipulation of the visuospatial input during visuomotor adaptation.

Impact of tDCS on performance and learning of target detection: interaction with stimulus characteristics and experimental design.

We have previously found that transcranial direct current stimulation (tDCS) over right inferior frontal cortex (RIFC) enhances performance during learning of a difficult visual target detection task (Clark et al., 2012). In order to examine the cognitive mechanisms of tDCS that lead to enhanced performance, here we analyzed its differential effects on responses to stimuli that varied by repetition and target presence, differences related to expectancy by comparing performance in single- and double-blind task designs, and individual differences in skin stimulation and mood. Participants were trained for 1h to detect target objects hidden in a complex virtual environment, while anodal tDCS was applied over RIFC at 0.1 mA or 2.0 mA for the first 30 min. Participants were tested immediately before and after training and again 1h later. Higher tDCS current was associated with increased performance for all test stimuli, but was greatest for repeated test stimuli with the presence of hidden-targets. This finding was replicated in a second set of subjects using a double-blind task design. Accuracy for target detection discrimination sensitivity (d'; Z(hits)-Z(false alarms)) was greater for 2.0 mA current (1.77) compared with 0.1 mA (0.95), with no differences in response bias (ß). Taken together, these findings indicate that the enhancement of performance with tDCS is sensitive to stimulus repetition and target presence, but not to changes in expectancy, mood, or type of blinded task design. The implications of these findings for understanding the cognitive mechanisms of tDCS are discussed.

Gustatory cortical lesions affect motivation for snack foods.

Most neuropsychological research using food as a reward uses single-bid auctions. We wished to determine whether focal brain lesions would affect the ability and motivation to win snack food items in a computerized auction allowing multiple bids. This allowed us to assess participants' abilities under more complex conditions. We enrolled 154 male penetrating traumatic brain injury (pTBI) veterans, mean age 58, from the Vietnam Head Injury Study registry, and 53 male uninjured veterans, mean age 59. We used voxel-based lesion symptom mapping (VLSM) to identify effects of brain lesions on the ability to win items and on participants' answers to statements regarding their level of motivation and evaluation of how well they performed. Number of items won was not significantly associated with any lesions; however, lesions in gustatory cortex (GC) affected motivation and self-evaluation. Our findings provide further evidence of the primary GC's role in motivation for food and drink.

Executive dysfunction in frontotemporal dementia and corticobasal syndrome.

OBJECTIVE: To determine the pattern of executive dysfunction in frontotemporal dementia (FTD) and corticobasal syndrome (CBS) and to determine the brain areas associated with executive dysfunction in these illnesses. METHOD: We administered the Delis-Kaplan Executive Function System (D-KEFS), a collection of standardized executive function tests, to 51 patients with behavioral-variant FTD and 50 patients with CBS. We also performed a discriminant analysis on the D-KEFS to determine which executive function tests best distinguished the clinical diagnoses of FTD and CBS. Finally, we used voxel-based morphometry (VBM) to determine regional gray matter volume loss associated with executive dysfunction. RESULTS: Patients with FTD and patients with CBS showed executive dysfunction greater than memory dysfunction. Executive function was better preserved in the patients with CBS than the patients with FTD with the exception of tests that required motor, visuospatial ability, or both. In patients with CBS, dorsal frontal and parietal and temporal-parietal cortex was associated with executive function. In FTD, tests with a language component (Verbal Fluency) were associated with left perisylvian cortex, sorting with the left dorsolateral prefrontal cortex, and reasoning (the Twenty Questions task) with the left anterior frontal cortex. The Twenty Questions test best distinguished the clinical diagnoses of CBS and FTD. CONCLUSIONS: The neuroanatomic findings (especially in frontotemporal dementia [FTD]) agree with the previous literature on this topic. Patients with FTD and patients with corticobasal syndrome (CBS) show disparate performance on higher-order executive functions, especially the Twenty Questions test. It may be difficult to distinguish motor and visuospatial ability from executive function in patients with CBS using tests with significant motor and visuospatial demands such as Trail Making.

Opposite effects of high and low frequency rTMS on mood in depressed patients: relationship to baseline cerebral activity on PET.

BACKGROUND: Optimal parameters of rTMS for antidepressant efficacy in general, or within patients, have not been adequately delineated. METHODS: Using a double-blind, sham-controlled, cross-over design, 22 adult patients with treatment refractory major depression (n=9; bipolar disorder, depressed phase) were randomized to active rTMS (20-Hz or 1-Hz) or sham rTMS conditions and given 5 rTMS treatments per week for two weeks. Repetitive TMS was administered at 100% of motor threshold for 1600 pulses over the left prefrontal cortex using a figure-eight coil. Patients initially randomized to sham rTMS were then exposed to two weeks of active rTMS with each frequency under blinded conditions. Those who received active 20-Hz and 1-Hz rTMS were crossed over to the opposite frequency for two weeks. Improvement in Hamilton Depression ratings were assessed after each two-week treatment phase. PET imaging was used to evaluate the patient's baseline absolute regional cerebral activity (blood flow and metabolism) as potential predictor of clinical response. RESULTS: Changes in depression severity on 1-Hz and 20-Hz rTMS were inversely correlated. PET scans with baseline hypoperfusion (but not hypometabolism) were associated with better improvement on 20-Hz rTMS as predicted. LIMITATIONS: The magnitude of the clinical change with either frequency at 100% motor threshold was not robust, and larger studies with higher intensities of rTMS for longer durations of time should be explored. CONCLUSIONS: High and low frequency rTMS exerts differential effects on depressed mood within individual subjects. The brain activity predictors and correlates of an optimal antidepressant response to rTMS remain to be better defined.

Clinicopathologic features of frontotemporal dementia with progranulin sequence variation.

BACKGROUND: Frontotemporal lobar degeneration with ubiquitin-immunoreactive (ub-ir) inclusions (FTLD-U) has been associated with frontotemporal dementia (FTD) and ALS. Recently, mutations in Progranulin (PGRN), predicted to cause premature truncation of the PGRN coding sequence, were found in patients with inherited FTLD-U and ub-ir neuronal intranuclear inclusions (NII). OBJECTIVE: To describe clinical, pathologic, and genetic features of three FTD patients having either a family history of FTD (A.III.1 and B.II.1) or of ALS (C.III.1). METHODS: Patients underwent a single clinical assessment, MRI, and [(18)F]fluorodeoxyglucose PET brain scan. Neuropathologic examination and genetic analyses were carried out. RESULTS: Patients presented clinically with the behavioral variant of FTD. Language dysfunctions were marked with comprehension being particularly affected. Neuroimaging revealed frontotemporal atrophy and glucose hypometabolism, with predominant left-side involvement, in Patients A.III.1 and B.II.1. Subject C.III.1 displayed mild atrophy and symmetric anterior hypometabolism. All patients were neuropathologically diagnosed with FTLD-U. Ub-ir NII were noted in Patients A.III.1 and B.II.1 but were absent in Patient C.III.1. The following PGRN sequence variations were found: IVS6-2A-->G (A.III.1), R493X (B.II.1), and R433W (C.III.1). IVS6-2A-->G may lead to skipping of exon 7 with consequent frameshift of the coding sequence and premature termination of PGRN translation. CONCLUSIONS: We have found two PGRN mutations associated with FTD, in affected individuals who are members of families with possible autosomal dominant FTD. A third PGRN sequence variation (R433W) was found in an FTD patient with family history of ALS.

Driving abilities in frontotemporal dementia patients.

OBJECTIVE: To evaluate driving competency and the relationship between neuropsychiatric symptoms and driving behavior in frontotemporal dementia (FTD) patients. METHODS: Fifteen patients with a diagnosis of FTD and 15 healthy controls were administered a driving simulation task. Measures of driving performance and neuropsychiatric symptoms were assessed. RESULTS: The FTD patients received more speeding tickets, ran more stop signs and were involved in more off-road crashes and collisions than the controls. The patients' overall average speed was significantly higher. Driving performance was correlated with agitated behavior. CONCLUSIONS: Behavioral changes characteristic of FTD patients have an impact on their driving skills leading to inappropriate driving behavior.

Magnetic instabilities in Fe3C cementite particles observed with Fe K-edge x-ray circular dichroism under pressure.

The ferromagnetic interstitial iron compound Fe(3)C (cementite) is expected to have Invar properties, whereby a high-moment to low-moment transition should occur when the atomic volume is reduced below a critical value. We, therefore, examine the pressure dependence of the Fe K-edge x-ray magnetic circular dichroism in Fe(3)C at ambient temperature and pressures up to 20 GPa. We find clear evidence for a high-moment to low-moment transition around 10 GPa.

Safety and cognitive effect of frontal DC brain polarization in healthy individuals.

BACKGROUND: Data from the human motor cortex suggest that, depending on polarity, direct current (DC) brain polarization can depress or activate cortical neurons. Activating effects on the frontal lobe might be beneficial for patients with frontal lobe disorders. This phase 1 study tested the safety of frontal DC, including its effects on frontal and other brain functions. METHODS: The authors applied 20 minutes of anodal, cathodal, or sham DC to the left prefrontal cortex in three groups of right-handed subjects and looked for effects on global measures of processing and psychomotor speed, emotion, and verbal fluency, a measure of local cortical function. In one experiment (n = 30), the authors tested before and after 1 mA DC and monitored EEG in 9 subjects. In two other experiments using 1 mA (n = 43) and 2 mA (n = 30), the authors tested before and then starting 5 minutes after the onset of DC. RESULTS: All subjects tolerated DC well. There were no significant effects on performance with 1 mA DC. At 2 mA, verbal fluency improved significantly with anodal and decreased mildly with cathodal DC. There were no clinically significant effects on the other measures. CONCLUSIONS: Limited exposure to direct current polarization of the prefrontal cortex is safe and can enhance verbal fluency selectively in healthy subjects. As such, it deserves consideration as a procedure to improve frontal lobe function in patients.

Cortical correlates of neuromotor development in healthy children.

OBJECTIVE: To examine the relationship between acquisition of fine motor skills in childhood and development of the motor cortex. METHODS: We measured finger tapping speed and mirror movements in 43 healthy right-handed subjects (6-26 years of age). While recording surface electromyographic activity from right and left first dorsal interosseus, we delivered focal transcranial magnetic stimulation (TMS) over the hand areas of each motor cortex. We measured motor evoked potential (MEP) threshold, and ipsilateral (iSP) and contralateral (CSP) silent periods. RESULTS: As children got older, finger speeds got faster, MEP threshold decreased, iSP duration increased and latency decreased. Finger tapping speed got faster as motor thresholds and iSP latency decreased, but was unrelated to CSP duration. In all subjects right hemisphere MEP thresholds were higher than those on the left and duration of right hemisphere CSP was longer than that on the left. Children under 10 years of age had higher left hand mirror movement scores, and fewer left hemisphere iSPs which were of longer duration. CONCLUSIONS: Maturation of finger tapping skills is closely related to developmental changes in the motor threshold and iSP latency. Studies are warranted to explore the relationship between these measures and other neuromotor skills in children with motor disorders. SIGNIFICANCE: TMS can provide important insights into certain functional aspects of neurodevelopment in children.

Motor cortex excitability correlates with an anxiety-related personality trait.

BACKGROUND: In an earlier study comparing obsessive-compulsive disorder (OCD) patients to psychiatrically screened normals, we found lowered motor evoked potential (MEP) threshold to transcranial magnetic stimulation (TMS) and decreased intracortical inhibition in OCD. We sought to determine whether this pattern was specific to OCD. METHODS: We measured the threshold and amplitude of MEPs to single and paired (subthreshold-suprathreshold; 3, 4, 10, 15 msec intervals) TMS in 46 healthy volunteers (23 women, 23 men) who were given the NEO-PI-R personality inventory. Nineteen of the men also received cognitive and motor tests. RESULTS: The paired-pulse conditioned/unconditioned MEP amplitude ratios correlated with Neuroticism (N), a stable measure of trait-level anxiety and other negative emotions, in the whole sample (r = 0.48; p = 0.0006), and in the men (r = 0.63; p = 0.0009). There were no other significant correlations. CONCLUSIONS: This relationship reflects a factor that contributes to both personality and cortical regulation. It was not statistically significant in women, probably because of confounding hormonal influences on excitability. Decreased intracortical inhibition may be related more to trait anxiety and depression, which are high in OCD, than to OCD itself. However, the MEP threshold (significantly lowered in OCD) was unrelated to N.

Transcranial magnetic stimulation (TMS) as a research tool in Tourette syndrome and related disorders.

TMS is a technology with much promise for understanding brain function in health and disease. This chapter has reviewed the physics and safety of this new tool. Much basic work remains to be done in order to understand exactly how TMS affects neurons, and the roles that intensity, frequency, and location have on brain activity. Recent work combining TMS with imaging is showing the method for future advances. In the area of TS, TMS has already had a significant impact; 3 studies have hinted that TS patients have a deficient inhibitory system. Other investigators are exploring whether TMS might be used in a therapeutic manner to alter the behavior of dysfunctional circuits. These areas of applying TMS to understanding and perhaps treating TS show much promise. Nonetheless, a great deal of basic work is likely needed before TMS can be fully used as a research tool or treatment modality for TS.

Therapeutic application of repetitive transcranial magnetic stimulation: a review.

Transcranial magnetic stimulation (TMS), a non-invasive means of electrically stimulating neurons in the human cerebral cortex, is able to modify neuronal activity locally and at distant sites when delivered in series or trains of pulses. Data from stimulation of the motor cortex suggest that the type of effect on the excitability of the cortical network depends on the frequency of stimulation. These data, as well as results from studies in rodents, have been generalized across brain areas and species to provide rationales for using repetitive TMS (rTMS) to treat various brain disorders, most notably depression. Research into clinical applications for TMS remains active and has the potential to provide useful data, but, to date, the results of blinded, sham-controlled trials do not provide clear evidence of beneficial effects that replace or even match the effectiveness of conventional treatments in any disorder. In this review, we discuss the clinical and scientific bases for using rTMS as treatment, and review the results of trials in psychiatric and neurological disorders to date.

Acute mood and thyroid stimulating hormone effects of transcranial magnetic stimulation in major depression.

BACKGROUND: Repetitive transcranial magnetic stimulation (rTMS) has recently been demonstrated to have antidepressant effects. Some work suggests that rTMS over prefrontal cortex administered to healthy individuals produces acute elevations of mood and serum thyroid-stimulating hormone (TSH). We sought to determine whether single rTMS sessions would produce acute mood and serum TSH elevations in subjects with major depressions. METHODS: Under double-blind conditions et al 14 medication-free subjects with major depression received individual sessions of either active or sham rTMS. rTMS was administered over the left prefrontal cortex at 10 Hz et al 100% of motor threshold, 20 trains over 10 min. Immediately before and after rTMS sessions, subjects' mood was rated with the Profile of Mood States (POMS) and the 6-Item Hamilton Depression Scale, and blood was drawn for later analysis of TSH. Subjects and raters were blind to treatment assignment. RESULTS: The group receiving active stimulation manifested significantly greater improvement on the POMS subscale of Depression (p < or = .0055) and a trend toward greater improvement on the modified Hamilton Rating (.05 < p < or =.1). No hypomania was induced. The change in TSH from pre- to post-rTMS was significantly different between active and sham sessions. CONCLUSIONS: This blinded, placebo-controlled trial documents that individual rTMS sessions can acutely elevate mood and stimulate TSH release in patients experiencing major depressive episodes.

Side effects of repetitive transcranial magnetic stimulation.

The side effects of repetitive transcranial magnetic stimulation are largely unexplored and the limits of safe exposure have not been determined except as regards the acute production of seizures. Although tissue damage is unlikely, however, cognitive and other adverse effects have been observed and the possibility of unintended long-term changes in brain function are theoretically possible.

Motor cortex excitability in patients with cerebellar degeneration.

OBJECTIVES: To study motor cortex (M1) excitability and the effect of subthreshold transcranial magnetic stimulation (TMS) in patients with cerebellar degeneration and normals performing a reaction time (RT) task. METHODS: Time to wrist flexion after a visual go-signal was measured. TMS was always delivered at 90% of resting motor evoked potential (MEP) threshold. In one experiment, test TMS was delivered at various intervals after the go-signal. In half the trials priming TMS was also given with the go-signal. A second experiment examined the effect on RT of M1 and occipital priming stimulation alone. RESULTS: M1 excitability, measured as the likelihood of producing MEPs in the wrist flexor muscles, increased immediately after the go-signal in the patients and stayed high until movement. In controls, excitability rose gradually. This difference was largely eliminated by priming TMS. RT was longer in the patient group, but improved with priming TMS. Occipital priming produced less effect on RT than M1 stimulation in both controls (P=0.008) and patients (P=0.0004). CONCLUSIONS: M1 excitability prior to movement in an RT task increases abnormally early in cerebellar patients. This may reflect compensation for deficient thalamocortical drive. Subthreshold TMS can partially normalize the prolonged RT and abnormal excitability rise in cerebellar patients.

BOLD-f MRI response to single-pulse transcranial magnetic stimulation (TMS).

Five healthy volunteers were studied using interleaved transcranial magnetic stimulation/functional magnetic resonance imaging (TMS/fMRI) and an averaged single trial (AST) protocol. Blood oxygenation level-dependent (BOLD)-fMRI response to single TMS pulses over the motor cortex was detectable in both the ipsilateral motor cortex under the TMS coil and the contralateral motor cortex, as well as bilaterally in the auditory cortex. The associated BOLD signal increase showed the typical fMRI hemodynamic response time course. The brain's response to a single TMS pulse over the motor cortex at 120% of the level required to induce thumb movement (1.0%-1.5% signal increase) was comparable in both level and duration to the auditory cortex response to the sound accompanying the TMS pulse (1.5% -2.0% signal increase).

Human corticospinal excitability evaluated with transcranial magnetic stimulation during different reaction time paradigms.

The aim of this study was to evaluate corticospinal excitability of both hemispheres during the reaction time (RT) using transcranial magnetic stimulation (TMS). Nine right-handed subjects performed right and left thumb extensions in simple (SRT), choice (CRT) and go/no-go auditory RT paradigms. TMS, inducing motor-evoked potentials (MEPs) simultaneously in the extensor pollicis brevis muscles bilaterally, was applied at different latencies from the tone. For all paradigms, MEP amplitudes on the side of movement increased progressively in the 80-120 ms before EMG onset, while the resting side showed inhibition. The inhibition was significantly more pronounced for right than for left thumb movements. For the left SRT, significant facilitation occurred on the right after EMG onset. Initial bilateral facilitation occurred in SRT trials with slow RT. After no-go tones, bilateral inhibition occurred at a time corresponding to the mean RT to go tones. The timing of the corticospinal rise in excitability on the side of movement was independent of task difficulty and RT. This suggests that corticospinal activation is, to some extent, in series and not in parallel with stimulus processing and response selection. Corticospinal inhibition on the side not to be moved implies that suppression of movement is an active process. This inhibition is more efficient for right- than for left-side movements in right-handed subjects, possibly because of left hemispheric dominance for movement.