Giovanni Assenza

Modulation of brain plasticity in stroke: a novel model for neurorehabilitation

Noninvasive brain stimulation (NIBS) techniques can be used to monitor and modulate the excitability of intracortical neuronal circuits. Long periods of cortical stimulation can produce lasting effects on brain function, paving the way for therapeutic applications of NIBS in chronic neurological disease. The potential of NIBS in stroke rehabilitation has been of particular interest, because stroke is the main cause of permanent disability in industrial nations, and treatment outcomes often fail to meet the expectations of patients. Despite promising reports from many clinical trials on NIBS for stroke recovery, the number of studies reporting a null effect remains a concern. One possible explanation is that the interhemispheric competition model—which posits that suppressing the excitability of the hemisphere not affected by stroke will enhance recovery by reducing interhemispheric inhibition of the stroke hemisphere, and forms the rationale for many studies—is oversimplified or even incorrect. Here, we critically review the proposed mechanisms of synaptic and functional reorganization after stroke, and suggest a bimodal balance–recovery model that links interhemispheric balancing and functional recovery to the structural reserve spared by the lesion. The proposed model could enable NIBS to be tailored to the needs of individual patients.

Anodal Transcranial Direct Current Stimulation Enhances Procedural Consolidation

The primary motor cortex (M1) area recruitment enlarges while learning a finger tapping sequence. Also M1 excitability increases during procedural consolidation. Our aim was to investigate whether increasing M1 excitability by anodal transcranial DC stimulation (AtDCS) when procedural consolidation occurs was able to induce an early consolidation improvement. Forty-seven right-handed healthy participants were trained in a nine-element serial finger tapping task (SFTT) executed with the left hand. Random series blocks were interspersed with training series blocks. Anodal or sham tDCS was administered over the right M1 after the end of the training session. After stimulation, the motor skills of both trained and a new untrained sequential series blocks were tested again. For each block, performance was estimated as the median execution time of correct series. Early consolidation of the trained series, assessed by the performance difference between the first block after and the last block before stimulation normalized by the random, was enhanced by anodal and not by sham tDCS. Stimulation did not affect random series execution. No stimulation effect was found on the on-line learning of the trained and new untrained series. Our results suggest that AtDCS applied on M1 soon after training improves early consolidation of procedural learning. Our data highlight the importance of neuromodulation procedures for understanding learning processes and support their use in the motor rehabilitation setting, focusing on the timing of the application.

Decoding of grasping information from neural signals recorded using peripheral intrafascicular interfaces

BackgroundThe restoration of complex hand functions by creating a novel bidirectional link between the nervous system and a dexterous hand prosthesis is currently pursued by several research groups. This connection must be fast, intuitive, with a high success rate and quite natural to allow an effective bidirectional flow of information between the users nervous system and the smart artificial device. This goal can be achieved with several approaches and among them, the use of implantable interfaces connected with the peripheral nervous system, namely intrafascicular electrodes, is considered particularly interesting.MethodsThin-film longitudinal intra-fascicular electrodes were implanted in the median and ulnar nerves of an amputees stump during a four-week trial. The possibility of decoding motor commands suitable to control a dexterous hand prosthesis was investigated for the first time in this research field by implementing a spike sorting and classification algorithm.ResultsThe results showed that motor information (e.g., grip types and single finger movements) could be extracted with classification accuracy around 85% (for three classes plus rest) and that the user could improve his ability to govern motor commands over time as shown by the improved discrimination ability of our classification algorithm.ConclusionsThese results open up new and promising possibilities for the development of a neuro-controlled hand prosthesis.

Fractal Dimension of EEG Activity Senses Neuronal Impairment in Acute Stroke

The brain is a self-organizing system which displays self-similarities at different spatial and temporal scales. Thus, the complexity of its dynamics, associated to efficient processing and functional advantages, is expected to be captured by a measure of its scale-free (fractal) properties. Under the hypothesis that the fractal dimension (FD) of the electroencephalographic signal (EEG) is optimally sensitive to the neuronal dysfunction secondary to a brain lesion, we tested the FD’s ability in assessing two key processes in acute stroke: the clinical impairment and the recovery prognosis. Resting EEG was collected in 36 patients 4–10 days after a unilateral ischemic stroke in the middle cerebral artery territory and 19 healthy controls. National Health Institute Stroke Scale (NIHss) was collected at T0 and 6 months later. Highuchi FD, its inter-hemispheric asymmetry (FDasy) and spectral band powers were calculated for EEG signals. FD was smaller in patients than in controls (1.447±0.092 vs 1.525±0.105) and its reduction was paired to a worse acute clinical status. FD decrease was associated to alpha increase and beta decrease of oscillatory activity power. Larger FDasy in acute phase was paired to a worse clinical recovery at six months. FD in our patients captured the loss of complexity reflecting the global system dysfunction resulting from the structural damage. This decrease seems to reveal the intimate nature of structure-function unity, where the regional neural multi-scale self-similar activity is impaired by the anatomical lesion. This picture is coherent with neuronal activity complexity decrease paired to a reduced repertoire of functional abilities. FDasy result highlights the functional relevance of the balance between homologous brain structures’ activities in stroke recovery.

Cortical Neuromodulation Modifies Cerebral Vasomotor Reactivity

Background and Purpose— Cerebral vasomotor reactivity (VMR) is a capability of cerebral vessels to dilate in response to hypercapnia. Transcranial direct current stimulation (tDCS) effects on cerebral hemodynamics have been poorly studied. Methods and Results— Ten healthy subjects underwent anodal/cathodal tDCS on the left motor cortex. Before and after tDCS, VMR assessment by transcranial Doppler and an electrocardiogram were performed. Normalized low-frequency band power of heart rate variability and its reactivity from basal to VMR condition (LFNreact) were estimated as relative markers of sympathetic activation. tDCS exerted a polarity-specific effect on both VMR (P=0.0001) and LFNreact (P=0.001). Anodal tDCS decreased VMR by 3.4%/mm Hg CO2 bilaterally and increased LFNreact, whereas cathodal tDCS increased VMR by 0.8%/mm Hg CO2 bilaterally and reduced LFNreact. Conclusions— Cerebral VMR is modified by tDCS. Based on the consensual changes with heart rate variability, we can hypothesize that the sympathetic nervous system could modulate the bihemispheric modification of VMR. Further studies are needed to confirm this hypothesis.

The myth of the 'unaffected' side after unilateral stroke: Is reorganisation of the non-infarcted corticospinal system to re-establish balance the price for recovery?

Background Bilateral changes in the hemispheric reorganisation have been observed chronically after unilateral stroke. Our hypotheses were that activity dependent competition between the lesioned and non-lesioned corticospinal systems would result in persisting asymmetry and be associated with poor recovery. Methods Eleven subjects (medium 6.5 years after stroke) were compared to 9 age-matched controls. The power spectral density (PSD) of the sensorimotor electroencephalogram (SM1-EEG) and electromyogram (EMG) and corticomuscular coherence (CMC) were studied during rest and isometric contraction of right or left opponens pollicis (OP). Global recovery was assessed using NIH score. Findings There was bilateral loss of beta frequency activity in the SM1-EEGs and OP-EMGs in strokes compared to controls. There was no difference between strokes and controls in symmetry indices estimated between the two corticospinal systems for SM1-EEG, OP-EMG and CMC. Performance correlated with preservation of beta frequency power in OP-EMG in both hands. Symmetry indices for the SM1-EEG, OP-EMG and CMC correlated with recovery. Interpretation Significant changes occurred at both cortical and spinomuscular levels after stroke but to the same degree and in the same direction in both the lesioned and non-lesioned corticospinal systems. Global recovery correlated with the degree of symmetry between corticospinal systems at all three levels — cortical and spinomuscular levels and their connectivity (CMC), but not with the absolute degree of abnormality. Re‐establishing balance between the corticospinal systems may be important for overall motor function, even if it is achieved at the expense of the non-lesioned system.

A contralesional EEG power increase mediated by interhemispheric disconnection provides negative prognosis in acute stroke

BACKGROUND AND PURPOSE Despite similar clinical onset, recovery from stroke can be largely variable. We searched for electrophysiological prognostic indices, believing that they can guide future neuromodulation treatments boosting clinical recovery. METHODS 19-channels resting electroencephalogram (EEG) was collected in 42 patients after 4-10 days (t0) from a unilateral ischemic stroke in the middle cerebral artery (MCA) territory and 20 controls. National Health Institute Stroke Scale (NIHSS) was collected at t0 and 6 months later (t1). Standard spectral band powers and interhemispheric coherences between homologous MCA regions were calculated in both hemispheres. RESULTS Total spectral, delta and theta band powers were higher bilaterally in patients than in controls and directly correlated with NIHSSt0 in both hemispheres. A linear regression model including each EEG patients variable differing from those of controls and correlating with effective recovery [ER = (NIHSSt0-NIHSSt1)/(NIHSSt0-NIHSS in healthy conditions)] showed contralesional delta power as the only valid predictor of ER. A further regression model including also NIHSSt0 confirmed that contralesional delta power can add prognostic information to acute clinical impairment. Contralesional delta activity increase was best explained, in addition to the increasing ipsilesional delta activity, by a reduction of interhemispheric functional coupling--which did not explain a significantly portion of effective recovery variability by itself. CONCLUSIONS Contralesional EEG delta activity retains relevant negative prognostic information in acute stroke patients. Present results point to the interhemispheric interplay as a decisive target in setting up enriched rehabilitations.

Neuronal functionality assessed by magnetoencephalography is related to oxidative stress system in acute ischemic stroke

The hypoxic brain damage induced by stroke is followed by an ischemia-reperfusion injury modulated by oxidative stress. Magnetoencephalographic (MEG) recording of rest and evoked cortical activities is a sensitive method to analyse functional changes following the acute ischemic damage. We aimed at investigating whether MEG signals are related to oxidative stress compounds in acute stroke. Eighteen stroke patients and 20 controls were enrolled. All subjects underwent MEG assessment to record background activity and somatosensory evoked responses (M20 and M30) of rolandic regions, neurological examination assessed by National Institute of Health Stroke Scale (NIHSS) and plasmatic measurement of copper, iron, zinc, ceruloplasmin, transferrin, total peroxides and Total Anti-Oxidant Status. Magnetic Resonance was performed to estimate the lesion site and volume. Delta power and M20 equivalent current dipole (ECD) strength in the affected hemisphere (AH) correlated with NIHSS scores (respectively, rho=.692, p=.006 and rho=-.627, p=.012) and taken together explained 67% of NIHSS variability (p=.004). Higher transferrin and lower peroxides levels correlated with better clinical status (respectively, rho=-.600, p=.014 and rho=.599, p=.011). Transferrin also correlated with AH M20 ECD strength (rho=.638 p=.014) and inversely with AH delta power (rho=-.646 p=.023) and the lesion volume, especially in cortico-subcortical stroke (p=.037). Our findings strengthen MEG reliability in honing the evaluation of neuronal damage in acute ischemic stroke also demonstrating an association between the MEG parameters most representing the clinical status and the oxidative stress compounds. Our results meet at a possible protective role of transferrin in limiting the oxidative damage in acute stroke.

Wakefulness delta waves increase after cortical plasticity induction

OBJECTIVE Delta waves (DW) are present both during sleep and in wakefulness. In the first case, DW are considered effectors of synaptic plasticity, while in wakefulness, when they appear in the case of brain lesions, their functional meaning is not unanimously recognized. To throw light on the latter, we aimed to investigate the impact on DW exerted by the cortical plasticity-inducing protocol of intermittent theta burst stimulation (iTBS). METHODS Twenty healthy subjects underwent iTBS (11 real iTBS and nine sham iTBS) on the left primary motor cortex with the aim of inducing long-term potentiation (LTP)-like phenomena. Five-minute resting open-eye 32-channel EEG, right opponens pollicis motor-evoked potentials (MEPs), and alertness behavioral scales were collected before and up to 30 min after the iTBS. Power spectral density (PSD), interhemispheric coherence between homologous sensorimotor regions, and intrahemispheric coherence were calculated for the frequency bands ranging from delta to beta. RESULTS Real iTBS induced a significant increase of both MEP amplitude and DW PSD lasting up to 30 min after stimulation, while sham iTBS did not. The DW increase was evident over frontal areas ipsilateral and close to the stimulated cortex (electrode F3). Neither real nor sham iTBS induced significant modifications in the PSD of theta, alpha, and beta bands and in the interhemispheric coherence. Behavioral visuo-analogic scales score did not demonstrate changes in alertness after stimulations. No correlations were found between MEP amplitude and PSD changes in the delta band. CONCLUSIONS Our data showed that LTP induction in the motor cortex during wakefulness, by means of iTBS, is accompanied by a large and enduring increase of DW over the ipsilateral frontal cortex. SIGNIFICANCE The present results are strongly in favor of a prominent role of DW in the neural plasticity processes taking place during the awake state.

The detection of neural autoantibodies in patients with antiepileptic-drug-resistant epilepsy predicts response to immunotherapy

The detection of antibodies binding neural antigens in patients with epilepsy has led to the definition of ‘autoimmune epilepsy’. Patients with neural antibodies not responding to antiepileptic drugs (AEDs) may benefit from immunotherapy. Aim of this study was to evaluate the frequency of autoantibodies specific to neural antigens in patients with epilepsy and their response to immunotherapy.