Functional Activation Patterns Research Articles

Functional near-infrared spectroscopy and vagus somatosensory evoked potentials add to the power of established parameters such as poor cognitive performance, dsyosmia and APOe genotype to predict cognitive decline over 8 years in the elderly

AbstractAlzheimer’s dementia is the main cause of cognitive impairment in people over the age of 65, with Alzheimer’s disease starting presumably 10–15 years before the onset of clinical symptoms. It is therefore important to recognize dementia at an early stage and identify possible predictors. The existing methods, like different parameters of ß-Amyloid and Tau quantification in cerebrospinal fluid (CSF) or the living brain by measure of PET, are invasive and expensive. Therefore, the present study investigates the predictive value of a battery of clinical, neuropsychological, and blood parameters as well as two neurophysiological methods (functional near-infrared spectroscopy [fNIRS] and vagus somatosensory evoked potentials [VSEP]) which are easy to perform, less invasive and cost-efficient, for developing cognitive impairments in the elderly.In this longitudinal, prospective study, we enrolled 604 healthy participants between 70 and 77 years of age. The participants were invited back after a mean time interval of 3 years and 11 months, and after 7 years and 8 months, and their cognitive impairments were determined.Here we show that the development of cognitive impairments after approximately 8 years can be predicted not only by previously known risk factors such as ApoE4 risk alleles, dysosmia, or poor cognitive performance at baseline but that latency prolongation in the VSEP and altered functional activation patterns measured by NIRS at baseline also provide additional predictive value.We therefore suggest that both neurophysiological parameters, VSEP and NIRS, should be included in future studies, investigating the prediction of dementia.Dementia ClinicalTrials.gov Identifier: NCT02224326.

Comparative Analysis of Brain Coping Mechanisms in Small Left-Hemisphere Lesions: Incidental vs. Symptomatic Gliomas.

Incidentally discovered low-grade gliomas (iLGGs) are very rare and little is still known about their associated functional imaging activation patterns, white-matter status, and plasticity potential. Recent studies shed light on several clinical factors responsible for the good clinical status observed in these patients versus those with their symptomatic counterpart (sLGGs), including small volume. Comparisons were typically carried out by comparing iLGGs with the wider and more heterogeneous sLGG group. In this study, we investigated whether iLGGs affect the brain differently from comparably small sLGGs. Starting from a sample of 13 patients with iLGG, in the current comparative cross-sectional study, we identified a group of patients with sLGGs, primarily matched by lesion volume. We looked for potential differences between the two groups in language-related functional and structural parameters (the fMRI network associated with naming and white-matter fascicles). The t-test did not show significant differences in the fMRI network, but these emerged when performing masking. No significant differences were observed at the white-matter level. Given that small volumes characterized both groups and that demographic variables were comparable, too, we hypothesized that differences between the two groups could be attributed to alternative lesion-related parameters. We discussed these findings from clinical and neurosurgical perspectives.

Resting-State Brain Function Alteration in Colorectal Cancer Patients.

To investigate the abnormal pattern of altered functional activity in the brain and the neuroimaging mechanisms underlying the cognitive impairment of patients with colorectal cancer (CRC) via resting-state functional magnetic resonance imaging (rs-fMRI). CRC patients (n = 56) and healthy controls (HCs) (n = 50) were studied. The participants underwent rs-fMRI scans and the Montreal Cognitive Assessment (MoCA). The amplitude of low-frequency fluctuations (ALFF), degree centrality (DC), regional homogeneity (ReHo), and MoCA scores, were calculated for participants. The scores of executives, visuospatial, memory, language and attention were lower in CRC patients. ReHo and ALFF values in the left postcentral gyrus, ReHo values in the right postcentral gyrus, ALFF and DC values in the left middle occipital gyrus, ReHo and DC values in the right lingual gyrus, DC values in the right angular gyrus and precuneus, and ALFF values in the left middle temporal gyrus decreased conspicuously in the CRC patients. CRC patients have abnormal resting state function, mainly in the brain areas involved in cognitive function. The overlapping brain regions with abnormal functional indicators are in the middle occipital gyrus, postcentral gyrus, and lingual gyrus. This study reveals the potential biological pathways involved in brain impairment and neurocognitive decline in patients with CRC.

Different baseline functional patterns of the frontal cortex in amyotrophic lateral sclerosis patients with Corticospinal tract hyperintensity

Nearly half of the amyotrophic lateral sclerosis (ALS) patients showed hyperintensity of the corticospinal tract (CST+), yet whether brain functional pattern differs between CST+and CST- patients remains obscure. In the current study, 19 ALS CST+, 41 ALS CST- patients and 37 healthy controls (HC) underwent resting state fMRI scans. We estimated local activity and connectivity patterns via the Amplitude of Low Frequency Fluctuations (ALFF) and the Network-Based Statistic (NBS) approaches respectively. The ALS CST+patients did not differ from the CST- patients in amyotrophic lateral sclerosis functional rating scale revised (ALSFRS-R) score and disease duration. ALFF of the superior frontal gyrus (SFG) and the inferior frontal gyrus pars opercularis (OIFG) were highest in the HC and lowest in the ALS CST- patients, resulting in significant group differences (PFWE<0.05). NBS analysis revealed a frontal network consisting of connections between SFG, OIFG, orbital frontal gyrus, middle cingulate cortex and the basal ganglia, which exhibited HC>ALS CST+ > ALS CST- group differences (PFWE=0.037) as well. The ALFF of the OIFG was significantly correlated with ALSFRS-R (R=0.34, P=0.028) and mean connectivity of the frontal network was trend-wise significantly correlated with disease duration (R=-0.31, P=0.052) in the ALS CST- patients. However, these correlations were insignificant in ALS CST+patients (P values > 0.8). In conclusion, The ALS CST+patients exhibited different patterns of baseline functional activity and connectivity in the frontal cortex which may indicate a functional compensatory effect.

Social support for functional dependence, activity patterns, and chronic pain outcomes: A cross-lagged mediation panel study.

Received social support undermining engagement in life activities of individuals with chronic pain (e.g., solicitousness, support for functional dependence) is consistently correlated with worse physical functioning, pain severity, and disability. Whether such responses lead to worse pain outcomes (operant model of pain) or the latter lead to more supportive responses undermining activity engagement (social communication and empathy models of pain) is unknown, given the lack of cross-lagged panel studies. Furthermore, the mediating role of activity patterns in such relationships over time is entirely unclear. This study aimed to bridge these gaps. This was a 3-month prospective study with three waves of data collection (T1-T3; 6-week lag in-between), including 130 older adults (71% women; Mage = 78.26) with musculoskeletal chronic pain attending day-care centers. At every time point, participants filled out self-report measures of staff social support for functional dependence, activity patterns, physical functioning, pain severity, and interference. Scales showed good/very good test-retest reliability (ICC = .74-.96) and internal consistency (all α > .90). Parsimonious cross-lagged panel mediation models showed the best fit (χ²/df < 2.44; CFI > .96; GFI > .93; RMSEA < .09). Bidirectional effects were found over time, but poorer pain outcomes at T1 (higher pain severity/interference, lower physical functioning) more consistently predicted higher social support for functional dependence than vice versa. Poorer pain outcomes (T1) predicted more avoidance/less overdoing (T3), via increased received support for functional dependence (T2). Further research on the cyclical relationships between the study variables across chronic pain trajectories is needed to harness the power of interpersonal relationships in future self-management interventions. (PsycInfo Database Record (c) 2024 APA, all rights reserved).

Mesial temporal lobe spiking reveals distinct patterns of blood oxygen level-dependent functional magnetic resonance imaging activation using simultaneous intracranial electroencephalography-functional magnetic resonance imaging.

Temporal lobe epilepsy (TLE) has a high probability of becoming drug resistant and is frequently considered for surgical intervention. However, 30% of TLE cases have nonlesional magnetic resonance imaging (MRI) scans, which is associated with worse surgical outcomes. Characterizing interactions between temporal and extratemporal structures in these patients may help understand these poor outcomes. Simultaneous intracranial electroencephalography-functional MRI (iEEG-fMRI) can measure the hemodynamic changes associated with interictal epileptiform discharges (IEDs) recorded directly from the brain. This study was designed to characterize the whole brain patterns of IED-associated fMRI activation recorded exclusively from the mesial temporal lobes of patients with nonlesional TLE. Eighteen patients with nonlesional TLE undergoing iEEG monitoring with mesial temporal IEDs underwent simultaneous iEEG-fMRI at 3 T. IEDs were marked, and statistically significant clusters of fMRI activation were identified. The locations of IED-associated fMRI activation for each patient were determined, and patients were grouped based on the location and pattern of fMRI activation. Two patterns of IED-associated fMRI activation emerged: primarily localized (n = 7), where activation was primarily located within the ipsilateral temporal lobe, and primarily diffuse (n = 11), where widespread bilateral extratemporal activation was detected. The primarily diffuse group reported significantly fewer focal to bilateral tonic-clonic seizures and had better postsurgical outcomes. Simultaneous iEEG-fMRI can measure the hemodynamic changes associated with focal IEDs not visible on scalp EEG, such as those arising from the mesial temporal lobe. Significant fMRI activation associated with these IEDs was observed in all patients. Two distinct patterns of IED-associated activation were seen: primarily localized to the ipsilateral temporal lobe and more widespread, bilateral activation. Patients with widespread IED associated-activation had fewer focal to bilateral tonic-clonic seizures and better postsurgical outcome, which may suggest a neuroprotective mechanism limiting the spread of ictal events.

Multimodal imaging investigation of structural rich club alterations in Alzheimer's disease and mild cognitive impairment: Amyloid deposition, structural atrophy, and functional activation differences.

Alzheimer's disease (AD) is characterized by significant cerebral dysfunction, including increased amyloid deposition, gray matter atrophy, and changes in brain function. The involvement of highly connected network hubs, known as the "rich club," in the pathology of the disease remains inconclusive despite previous research efforts. In this study, we aimed to systematically assess the link between the rich club and AD using a multimodal neuroimaging approach. We employed network analyses of diffusion magnetic resonance imaging (MRI), longitudinal assessments of gray matter atrophy, amyloid deposition measurements using positron emission tomography (PET) imaging, and meta-analytic data on functional activation differences. Our study focused on evaluating the role of both the structural brain network's core and extended rich club regions in individuals with mild cognitive impairment (MCI) and those diagnosed with AD. Our findings revealed that structural rich club regions exhibited accelerated gray matter atrophy and increased amyloid deposition in both MCI and AD. Importantly, these regions remained unaffected by altered functional activation patterns observed outside the core rich club regions. These results shed light on the connection between two major AD biomarkers and the rich club, providing valuable insights into AD as a potential disconnection syndrome.

Functional and structural reorganization in brain tumors: a machine learning approach using desynchronized functional oscillations

Neuroimaging studies have allowed for non-invasive mapping of brain networks in brain tumors. Although tumor core and edema are easily identifiable using standard MRI acquisitions, imaging studies often neglect signals, structures, and functions within their presence. Therefore, both functional and diffusion signals, as well as their relationship with global patterns of connectivity reorganization, are poorly understood. Here, we explore the functional activity and the structure of white matter fibers considering the contribution of the whole tumor in a surgical context. First, we find intertwined alterations in the frequency domain of local and spatially distributed resting-state functional signals, potentially arising within the tumor. Second, we propose a fiber tracking pipeline capable of using anatomical information while still reconstructing bundles in tumoral and peritumoral tissue. Finally, using machine learning and healthy anatomical information, we predict structural rearrangement after surgery given the preoperative brain network. The generative model also disentangles complex patterns of connectivity reorganization for different types of tumors. Overall, we show the importance of carefully designing studies including MR signals within damaged brain tissues, as they exhibit and relate to non-trivial patterns of both structural and functional (dis-)connections or activity.

Role of the Cerebellum in Bipolar Disorder: A Systematic Literature Review.

The aim of this systematic literature review was to investigate the role of the cerebellum in the affective symptoms observed in patients with bipolar disorder. The present systematic literature review included clinical studies conducted from 2013-2023 among adult populations with bipolar I and II disorders, along with their specifiers. With regard to cerebellar pathology, it was found that those with bipolar disorder performed worse than their healthy counterparts in their ability to comprehend the mental states of others and in identifying negative mental states. Additionally, individuals with bipolar disorder had reduced gray matter loss in regions such as lobules I-IX, crus I, and crus II, different functional activation patterns of the thalamus, striatum, and hippocampus on functional magnetic resonance imaging (fMRI), and increased cortical thickness. Cerebro-cerebellar functional connectivities were altered in patients with bipolar disorder. The effects of lamotrigine and lithium on cerebellar volume and abnormalities are also discussed in this paper. The present systematic literature review illustrates the emerging involvement of the cerebellum in bipolar disorder and its affective symptoms and paves the way for future research and a better understanding of bipolar disorder.

Neuroimaging research progress of acupuncture treatment for patients with functional dyspepsia.

Neuroimaging technology provides objective and visualized research tool to study the mechanisms of acupuncture effects. Building on a systematic review of previous clinical studies on acupuncture treatment for functional dyspepsia using neuroimaging technology, this paper summarizes and synthesizes past researches from 4 aspects： acupoint-specific effects, factors influencing the effects, different physiological responses, and predictive factors for acupuncture efficacy. It suggests that acupuncture treatment for FD involves central integration with disease-targeted (acupuncture treatment can target and regulate abnormal brain functional activity patterns in patients with FD), meridian-specific (stimulation of specific acupuncture points along the stomach meridian can significantly regulate abnormal brain functional activity patterns in FD patients), and dynamic conditional features(the effects of acupuncture treatment for FD are influenced by multiple factors). Lastly, considering the current research status, this paper outlines prospects in terms of research subjects, influencing factors, and result validation, aiming to provide references for future in-depth research.

Abstract WP293: Elucidating the Neuronal Basis of Diaschisis in Stroke Recovery

Numerous studies have shown that focal ischemic stroke changes cortical activity patterns, metabolism and blood flow not only in peri-infarct regions, but also in remote regions connected to the ischemic core. This phenomenon known as “diaschesis”, was predicted over 100 years ago and is presumed to play an important role in dictating the extent of stroke recovery. Although regional brain imaging studies provide some support to this idea (with caveats), direct examination of the structure and function of neurons connected to neurons lost in the infarct core, has not been adequately addressed. One reason for our lack of a detailed understanding is the methodologies to trace connected neurons and track their function/activity patterns over weeks and months time after stroke, did not exist until recently. To address this issue, we injected adeno-associated virus (AAV) into the adult mouse primary forelimb somatosensory cortex (FLS1) 2-3 weeks before induction of photothrombotic stroke. These AAVs could either be transported in a retrograde fashion to label neural inputs to the FLS1 (retro pAAV.CAG.GFP), or conversely move in an anterograde, trans-synaptic manner (AAV.Syn.Cre) to label neurons downstream of FLS1 neurons, such as in motor cortex. In the latter case, we utilized a transgenic mouse that co-expressed a cre-recombinase dependent fluorescent reporter (tdTomato), as well as a genetically encoded calcium sensor (GCaMP6s) in neurons. These dual reporters (tdTomato and GCaMP6s) allowed us to examine changes in dendritic structure as well as functional activity patterns in downstream motor neurons. Our initial findings using confocal microscopy to assess dendritic structure, indicate subtle changes in spine density in neuronal inputs and outputs of the FLS1, within the first week after stroke. Repeated in vivo imaging of calcium transients in downstream motor cortex neurons in awake mice before and after FLS1 cortex stroke, suggested a long lasting disruption in neuronal and ensemble activity patterns. These preliminary findings provide direct evidence that neurons in remotely connected brain regions suffer long-lasting impairments after stroke, thereby providing another potential target or substrate for future therapeutics to consider.

Supplemental Material for Social Support for Functional Dependence, Activity Patterns, and Chronic Pain Outcomes: A Cross-Lagged Mediation Panel Study

Supplemental Material for Social Support for Functional Dependence, Activity Patterns, and Chronic Pain Outcomes: A Cross-Lagged Mediation Panel Study

INVESTIGATING THE NEURAL CORRELATES OF SOCIAL AND INDIVIDUAL SINGING IN PERSONS WITH DEMENTIA

Abstract Music interventions for persons with Alzheimer’s Disease and related dementias (PwADRD) have documented psychological benefits; however, the neurological correlates underlying these advantages remain less certain. Using functional near infrared spectroscopy (fNIRS), the present study i) investigated within-person patterns of cortical oxygenation during choral vs. individual singing; ii) explored how singing context (choral vs. individual) modulated patterns of functional connectivity (FC) within and across frontal and parietal cortices; and iii) leveraged these functional activations as predictors of cognitive status (degree of impairment) in a series of discriminant function analyses (DFA). Participants were 13 PwADRD who volunteered from a larger, ongoing social-cognitive choir intervention. fNIRS data were collected using a TechEn Cw6 system during both choral and individual singing conditions. Paired sample t-tests evaluated differences in activation patterns between singing conditions, with DFA used to determine whether these activations and neuropsychological function were predictive of between-person differences in cognitive impairment. Significant differences in cerebral oxygenation were identified in the right anterior PFC, with individual singing associated with significantly greater cortical oxygenation relative to group singing. Although not significant, individual singing was also associated with bilateral increases in cortical oxygenation across the majority of fNIRS channels, as well as increased FC, relative to group singing. The DFA analyses were not significant. This novel study is the first to examine differences in music-cognition correlates across environmental contexts for PwADRD. Patterns of functional activation suggest that choral singing in particular may represent an optimal lifestyle activity, placing comparatively fewer demands on cognitive function.

Common and distinct neural correlates of emotional processing in individuals at familial risk for major depressive disorder and bipolar disorder: A comparative meta-analysis

Individuals at familial risk for mood disorders exhibit deficits in emotional processing and associated brain dysfunction prior to illness onset. However, such brain-behavior abnormalities related to familial predisposition remain poorly understood. To investigate robust abnormal functional activation patterns during emotional processing in unaffected at-risk relatives of patients with major depressive disorder (UAR-MDD) and bipolar disorder (UAR-BD), we performed a meta-analysis of task-based functional magnetic resonance imaging studies using Seed-based d Mapping (SDM) toolbox. Common and distinct patterns of abnormal functional activation between UAR-MDD and UAR-BD were detected via conjunction and differential analyses. A total of 17 studies comparing 481 UAR and 670 healthy controls (HC) were included. Compared with HC, UAR-MDD exhibited hyperactivation in the parahippocampal gyrus, amygdala and cerebellum, while UAR-BD exhibited parahippocampal hyperactivation and hypoactivation in the striatum and middle occipital gyrus (MOG). Conjunction analysis revealed shared hyperactivated PHG in both groups. Differential analysis indicated that the activation patterns of amygdala and MOG significantly differed between UAR-MDD and UAR-BD. These findings provide novel insights into common and distinct neural phenotypes for familial risk and associated risk mechanisms in MDD and BD, which may have implications in guiding precise prevention strategies tailored to the family context.

Altered patterns of brain activity during a fMRI memory task in cognitively normal adults carrying the APOE ε4 allele

AbstractBackgroundThe ε4 allele of the Apolipoprotein E gene (APOE) is a well‐established risk factor for Alzheimer’s disease (AD), ε4 carriers showing earlier onset and more severe memory impairment than non‐carriers. Neuroimaging evidence suggests that APOEε4 may modulate neural activity in AD since early stages. The purpose of this study was to determine whether APOEε4 influences brain activity in the memory circuit in older cognitively unimpaired individuals.MethodThirty cognitively unimpaired participants (n = 10 APOEε4 heterozygous carriers, age = 65± 5 years, 50% females, MMSE score = 29±1; n = 20 APOEε4 non‐carriers, age = 68±5 years, 35% females, MMSE score = 30±1) were recruited and underwent multidomain (i.e., memory, visuospatial abilities, language, attention) neuropsychological exams and functional MRI scan during an associative memory task, which consisted of two phases: (i) encoding of face‐name associations; (ii) recognition of the name associated to each face. Image preprocessing and voxel‐wise comparisons were conducted using the Statistical Parametric Mapping (SPM, v12). Clusters were considered significant at an uncorrected threshold of p&lt;0.001.ResultParticipants were comparable for demographic and cognitive features (p&gt;0.10) and performed similarly on the in‐scanner face‐name association memory task (p&gt;0.10). Compared to ε4 non‐carriers, carriers showed (i) greater activation during the encoding task in the left temporo‐occipital cortex/fusiform gyrus, (ii) greater activation during the recognition task in the middle temporal gyrus/temporo‐occipital cortex bilaterally and in the right cerebellum, and (iii) lower activation during the recognition task in the medial supplementary motor area.ConclusionThese preliminary results confirm that the APOE ε4 allele is associated with a different pattern of brain functional activity during an associative memory task in cognitively unimpaired older. Given the similar cognitive performance between groups, higher activation in temporo‐occipital regions might reflect a compensatory process in regions vulnerable to AD pathology.

Altered patterns of brain activity during a fMRI memory task in cognitively normal adults carrying the APOE ε4 allele

AbstractBackgroundThe e4 allele of the Apolipoprotein E gene (APOE) is a well‐established risk factor for Alzheimer’s disease (AD), e4 carriers showing earlier onset and more severe memory impairment than non‐carriers. Neuroimaging evidence suggests that APOEe4 may modulate neural activity in AD since early stages. The purpose of this study was to determine whether APOEe4 influences brain activity in the memory circuit in older cognitively unimpaired individuals.MethodThirty cognitively unimpaired participants (n = 10 APOEe4 heterozygous carriers, age = 65± 5 years, 50% females, MMSE score = 29±1; n = 20 APOEe4 non‐carriers, age = 68±5 years, 35% females, MMSE score = 30±1) were recruited and underwent multidomain (i.e., memory, visuospatial abilities, language, attention) neuropsychological exams and functional MRI scan during an associative memory task, which consisted of two phases: (i) encoding of face‐name associations; (ii) recognition of the name associated to each face. Image preprocessing and voxel‐wise comparisons were conducted using the Statistical Parametric Mapping (SPM, v12). Clusters were considered significant at an uncorrected threshold of p&lt;0.001.ResultParticipants were comparable for demographic and cognitive features (p&gt;0.10) and performed similarly on the in‐scanner face‐name association memory task (p&gt;0.10). Compared to e4 non‐carriers, carriers showed (i) greater activation during the encoding task in the left temporo‐occipital cortex/fusiform gyrus, (ii) greater activation during the recognition task in the middle temporal gyrus/temporo‐occipital cortex bilaterally and in the right cerebellum, and (iii) lower activation during the recognition task in the medial supplementary motor area.ConclusionThese preliminary results confirm that the APOE e4 allele is associated with a different pattern of brain functional activity during an associative memory task in cognitively unimpaired older. Given the similar cognitive performance between groups, higher activation in temporo‐occipital regions might reflect a compensatory process in regions vulnerable to AD pathology.

A guide to ERK dynamics, part 2: downstream decoding.

Signaling by the extracellular signal-regulated kinase (ERK) pathway controls many cellular processes, including cell division, death, and differentiation. In this second installment of a two-part review, we address the question of how the ERK pathway exerts distinct and context-specific effects on multiple processes. We discuss how the dynamics of ERK activity induce selective changes in gene expression programs, with insights from both experiments and computational models. With a focus on single-cell biosensor-based studies, we summarize four major functional modes for ERK signaling in tissues: adjusting the size of cell populations, gradient-based patterning, wave propagation of morphological changes, and diversification of cellular gene expression states. These modes of operation are disrupted in cancer and other related diseases and represent potential targets for therapeutic intervention. By understanding the dynamic mechanisms involved in ERK signaling, there is potential for pharmacological strategies that not only simply inhibit ERK, but also restore functional activity patterns and improve disease outcomes.

Working Memory-Related Neurofunctional Correlates Associated with the Frontal Lobe in Children with Familial vs. Non-Familial Attention Deficit/Hyperactivity Disorder.

Attention deficit/hyperactivity disorder (ADHD) is a neurodevelopmental disorder with high prevalence, heritability, and heterogeneity. Children with a positive family history of ADHD have a heightened risk of ADHD emergence, persistence, and executive function deficits, with the neural mechanisms having been under investigated. The objective of this study was to investigate working memory-related functional brain activation patterns in children with ADHD (with vs. without positive family histories (ADHD-F vs. ADHD-NF)) and matched typically developing children (TDC). Voxel-based and region of interest analyses were conducted on two-back task-based fMRI data of 362 subjects, including 186, 96, and 80 children in groups of TDC, ADHD-NF, and ADHD-F, respectively. Relative to TDC, both ADHD groups had significantly reduced activation in the left inferior frontal gyrus (IFG). And the ADHD-F group demonstrated a significant positive association of left IFG activation with task reaction time, a negative association of the right IFG with ADHD symptomatology, and a negative association of the IFG activation laterality index with the inattention symptom score. These results suggest that working memory-related functional alterations in bilateral IFGs may play distinct roles in ADHD-F, with the functional underdevelopment of the left IFG significantly informing the onset of ADHD symptoms. Our findings have the potential to assist in tailored diagnoses and targeted interventions in children with ADHD-F.

Females exhibit smaller volumes of brain activation and lower inter-subject variability during motor tasks

Past work has shown that brain structure and function differ between females and males. Males have larger cortical and sub-cortical volume and surface area (both total and subregional), while females have greater cortical thickness in most brain regions. Functional differences are also reported in the literature, yet to date little work has systematically considered whether patterns of brain activity indexed with functional magnetic resonance imaging (fMRI) differ between females and males. The current study sought to remediate this issue by employing task-based whole brain motor mapping analyses using an openly available dataset. We tested differences in patterns of functional brain activity associated with 12 voluntary movement patterns in females versus males. Results suggest that females exhibited smaller volumes of brain activation across all 12 movement tasks, and lower patterns of variability in 10 of the 12 movements. We also observed that females had greater cortical thickness, which is in alignment with previous analyses of structural differences. Overall, these findings provide a basis for considering biological sex in future fMRI research and provide a foundation of understanding differences in how neurological pathologies present in females vs males.

Functional imaging of deep brain stimulation in dystonia: a review

Much remains to be learned about the mechanism of benefit of deep brain stimulation in movement disorders in general and dystonia specifically. A full accounting of the pathophysiology of dystonia additionally remains unclear. Given its ability to evaluate whole-brain network changes, functional neuroimaging is an important tool to advance understanding of the effects of deep brain stimulation, which in turn could offer insight into the pathophysiology of dystonia and suggest novel deep brain stimulation targets for the disorder. This review surveys the published literature of functional neuroimaging studies evaluating deep brain stimulation effects in dystonia, including PET, SPECT, and functional MRI studies. To date, study cohorts have been relatively small, though several general patterns emerge when studies are viewed collectively, including reduced functional activation patterns with stimulation turned on during motor tasks, particularly in frontal cortical regions. During rest with stimulation on, several studies showed areas of relatively decreased perfusion only in those participants who experienced clinical benefit from deep brain stimulation. Future research may benefit from larger cohorts with more homogeneous forms of dystonia, potentially enabled by multi-center initiatives. Additional benefits may result from more detailed longitudinal assessments and greater use of functional MRI, with study designs that take into account the technical limitations of this modality in the context of movement disorders and deep brain stimulation.