Fact-checked by Grok 2 weeks ago

Brain mapping

Brain mapping is the interdisciplinary process of generating detailed, three-dimensional representations of the brain's anatomical structures, functional networks, and neural connectivity, using advanced imaging, computational modeling, and data integration techniques to reveal how neurons and circuits underpin cognition, behavior, and disease states across species including humans, nonhuman primates, and rodents.^[1] This field encompasses both structural brain mapping, which delineates physical features like gray and white matter organization via methods such as magnetic resonance imaging (MRI) and diffusion tensor imaging (DTI), and functional brain mapping, which localizes active regions during tasks or at rest using tools like functional MRI (fMRI) to detect blood-oxygen-level-dependent (BOLD) signals, positron emission tomography (PET) for metabolic changes, electroencephalography (EEG) for electrical activity, and magnetoencephalography (MEG) for magnetic fields generated by neuronal currents.^[2]^[3] These techniques allow for the visualization of brain activity at multiple scales, from individual synapses to whole-brain networks, addressing limitations of earlier invasive methods like electrical stimulation during surgery.^[3] Historically rooted in 19th-century lesion studies and 20th-century electrophysiological recordings, brain mapping accelerated in the 1990s with the advent of noninvasive neuroimaging during the "Decade of the Brain," leading to initiatives like the Human Connectome Project for high-resolution connectivity mapping.^[1]^[4] The field has since advanced through the ongoing NIH BRAIN Initiative, launched in 2013, with its 2023 BRAIN 2.0 report continuing to prioritize scalable technologies for circuit diagrams, cell-type censuses, and large-scale monitoring of millions of neurons to produce dynamic models of brain function at millisecond temporal resolution.^[5]^[6] Brain mapping plays a pivotal role in clinical applications, such as preoperative planning in neurosurgery to identify eloquent areas for language, motor control, and sensation, thereby reducing risks in tumor resections and epilepsy surgeries, and in research to uncover circuit alterations in disorders like Alzheimer's, depression, and stroke.^[3]^[2] Progress includes precision individual-specific parcellations from extended fMRI sessions, revealing unique network topologies that outperform group averages for personalized diagnostics, alongside BRAIN Initiative-funded efforts yielding comprehensive cell atlases and electron microscopy-based connectomes for translational insights into neural diversity and dysfunction.^[7]^[5]

Introduction

Definition and Scope

Brain mapping refers to the comprehensive process of generating detailed spatial representations of the brain's anatomical structure, functional activity, and neural connectivity through advanced imaging and analytical techniques. This involves quantifying and visualizing biological properties—such as gene expression, cellular distributions, and physiological signals—onto three-dimensional models of the brain across various scales and states, including development and pathology.^[1]^[8] The scope of brain mapping extends from microscopic levels, such as individual neurons and molecular features, to macroscopic whole-brain networks, encompassing anatomical mapping (e.g., gray matter volumes), functional mapping (e.g., task-related activations), and connectomic mapping (e.g., white matter tracts).^[8]^[9] As a subfield of neuroscience focused on creating spatial representations of brain structure and function, brain mapping integrates multimodal data from sources like genomics, histology, and neuroimaging, while differing from neurology, the medical specialty centered on clinical diagnosis and treatment of nervous system disorders.^[10] Neuroimaging techniques, such as MRI and PET, form a cornerstone for achieving these representations noninvasively in humans.^[11] At its core, brain mapping aims to delineate specific brain regions, pathways, and dynamic processes to establish causal links between neural architecture and complex phenomena like behavior, cognition, and disease progression.^[12]^[8] These objectives facilitate the discovery of organizational principles, such as hierarchical gradients from sensory to associative cortices, enabling predictions about brain function in health and impairment.^[8] As a multidisciplinary endeavor, brain mapping draws on expertise from biology for neuroanatomical insights, computer science for data processing and modeling, physics for imaging modalities, and advanced statistical analysis for pattern interpretation.^[1]^[11] This integration supports collaborative efforts to standardize and share large-scale datasets, accelerating discoveries across basic research and clinical applications.^[8]

Historical Context and Importance

The concept of brain mapping traces its origins to the 19th century, when phrenology, developed by Franz Joseph Gall, proposed mapping mental faculties to specific regions of the skull based on its shape; however, this approach was extensively critiqued as pseudoscientific due to its lack of empirical validation and reliance on superficial correlations.^[13] These criticisms spurred more anatomically grounded methods, culminating in Korbinian Brodmann's seminal 1909 work on cytoarchitectonics, which systematically divided the human cerebral cortex into 52 areas based on differences in neuronal organization and layering, laying foundational principles for modern brain parcellation.^[14]^[15] Brain mapping holds profound importance for medical advancements, particularly in enabling personalized medicine through detailed neural profiles that guide targeted therapies for conditions like Alzheimer's disease, where it identifies vulnerable cell types and protein accumulation patterns in memory-related circuits.^[16]^[17] By elucidating the neural underpinnings of such disorders, it facilitates the creation of AI-inspired models that replicate brain connectivity and dynamics, improving computational efficiency in artificial neural networks.^[18] Economically, the neurotechnology sector fueled by these mapping innovations is valued at approximately USD 15.8 billion as of 2025 projections.^[19] Societally, brain mapping bridges the longstanding mind-body divide by revealing intrinsic neural mechanisms underlying conscious experience and emotional processing, integrating biological insights with psychological phenomena.^[20] It informs educational strategies by illuminating developmental trajectories of cognition and attention, and influences mental health policies through evidence on circuit-level disruptions in disorders like anxiety and depression.^[21] The BRAIN Initiative, through reports like BRAIN 2025, emphasizes dynamic mapping—capturing real-time brain activity and developmental changes—underscoring its ongoing relevance for addressing these challenges.^[22]^[23]

Techniques

Structural Techniques

Structural techniques in brain mapping focus on elucidating the brain's physical architecture, including the segmentation of gray and white matter, the tracing of neural fiber tracts, and the reconstruction of synaptic connections at various scales. These methods provide static representations of brain anatomy and connectivity, essential for understanding organizational principles without measuring dynamic activity. High-resolution imaging and histological approaches enable detailed visualization, from macroscopic structures to ultrastructural details. Diffusion tensor imaging (DTI) is a non-invasive magnetic resonance imaging (MRI) technique that maps white matter tracts by modeling the diffusion of water molecules, which is anisotropic in organized fiber bundles. In brain tissue, water diffuses preferentially along axonal fibers, allowing reconstruction of major pathways such as the corpus callosum and corticospinal tract. A key metric in DTI is fractional anisotropy (FA), which quantifies the degree of diffusion directionality and serves as an indicator of white matter integrity, with values ranging from 0 (isotropic diffusion) to 1 (highly anisotropic). The FA is calculated as

\text{FA} = \sqrt{ \frac{3}{2} \frac{ (\lambda_1 - \bar{\lambda})^2 + (\lambda_2 - \bar{\lambda})^2 + (\lambda_3 - \bar{\lambda})^2 }{ \lambda_1^2 + \lambda_2^2 + \lambda_3^2 } }

where \lambda_1, \lambda_2, \lambda_3 are the eigenvalues of the diffusion tensor and \bar{\lambda} is their mean. DTI has been instrumental in clinical applications, such as identifying tract disruptions in neurological disorders.^[24] Variants of structural MRI, including high-resolution T1-weighted imaging, facilitate the segmentation of gray and white matter to delineate brain regions and quantify volumes. These images achieve sub-millimeter resolution, enabling the identification of cortical layers and subcortical nuclei. Voxel-based morphometry (VBM) extends this by performing statistical analyses on normalized gray matter density across voxels, detecting regional volume differences without a priori hypotheses about location. VBM involves tissue classification, spatial normalization to a template, and smoothing, making it widely used for studying atrophy in aging and disease. For instance, it has revealed gray matter reductions in specific brain areas associated with cognitive decline.^[25]^[26] Histological methods provide cellular-level resolution through post-mortem tissue preparation, involving fixation, sectioning, and staining to visualize brain architecture. Traditional techniques like Nissl staining target ribosomal RNA in neuronal somata, producing purple hues that highlight cell bodies and cytoarchitecture, aiding in the demarcation of cortical layers and nuclear groups. This method, developed in the late 19th century but refined for modern mapping, supports automated registration to atlases for large-scale analysis. Electron microscopy complements this by imaging ultrathin sections to resolve synaptic connections, revealing details such as vesicle release sites and membrane appositions at nanometer scales. These approaches are foundational for validating in vivo imaging and creating reference maps.^[27]^[28] Connectomics approaches employ serial section electron microscopy (ssEM) to generate comprehensive wiring diagrams of neural circuits, capturing every synapse in a volume. In ssEM, tissue is embedded, ultrathin-sectioned (typically 40-50 nm thick), and imaged sequentially with transmission electron microscopes, followed by computational alignment and segmentation. Pioneering efforts in the Drosophila melanogaster brain have produced dense connectomes, such as a full adult female brain volume encompassing over 130,000 neurons and 50 million synapses, enabling analysis of circuit motifs and connectivity patterns. These reconstructions, achieved through automated tape-collecting ultramicrotomy and high-throughput imaging, provide unprecedented insights into neural organization and have informed models of behavior in simpler organisms.^[29]^[30]

Functional Techniques

Functional techniques in brain mapping focus on capturing dynamic neural activity, revealing how brain regions engage during cognitive tasks, sensory processing, or motor functions by measuring physiological correlates such as blood flow, electrical potentials, or metabolic changes. These methods provide temporal resolution ranging from milliseconds to seconds, enabling the study of brain function in relation to behavior and pathology, often integrated with structural maps for comprehensive localization. Unlike static anatomical imaging, functional approaches emphasize activity-dependent signals to infer neural computations and connectivity. Functional magnetic resonance imaging (fMRI) is a cornerstone technique that indirectly measures neural activity through changes in blood oxygenation. It relies on the blood-oxygen-level-dependent (BOLD) contrast, where activated neurons increase oxygen consumption, leading to reduced deoxyhemoglobin levels and altered magnetic susceptibility in venous blood, which modulates the MRI signal. The approximate relationship is given by:

\frac{\Delta S}{S} \approx k \cdot \Delta [\text{deoxyHb}]

where \Delta S / S is the relative signal change, k is a proportionality constant, and \Delta [\text{deoxyHb}] represents the change in deoxyhemoglobin concentration. This non-invasive method achieves spatial resolution of 1-3 mm and temporal resolution of seconds, making it ideal for mapping task-evoked responses in humans, such as language processing or visual perception. Seminal work demonstrated BOLD's sensitivity to physiological oxygenation variations in vivo. fMRI's widespread adoption stems from its ability to scan entire brain volumes repeatedly without radiation, though it is limited by hemodynamic delays that lag behind neural firing by 2-6 seconds. Electroencephalography (EEG) and magnetoencephalography (MEG) offer high temporal resolution for mapping brain activity by recording extracranial electrical or magnetic fields generated by postsynaptic currents in neuronal populations. EEG, pioneered in humans by recording alpha rhythms from scalp electrodes, detects voltage fluctuations with millisecond precision, suitable for studying event-related potentials during attention or sleep stages. MEG complements EEG by measuring magnetic fields, which are less distorted by skull and tissue conductivity, providing better source localization for dipolar currents. Both techniques face the inverse problem: reconstructing intracranial sources from surface measurements, often solved using models like minimum norm estimation or beamformers that assume current distributions. EEG/MEG excel in real-time applications, such as brain-computer interfaces, but spatial resolution is coarser (typically 5-10 mm) compared to fMRI. Optogenetics and calcium imaging enable precise, cell-type-specific functional mapping, primarily in animal models, by leveraging light-sensitive proteins to monitor or manipulate neural activity. Optogenetics uses microbial opsins, such as channelrhodopsin-2, expressed via genetic targeting to depolarize or hyperpolarize neurons with blue light pulses, allowing causal inference of circuit functions like fear conditioning in mice. This technique achieves millisecond temporal control and specificity to genetically defined populations, revolutionizing behavioral neuroscience. Calcium imaging, often paired with optogenetics, employs fluorescent indicators like GCaMP that bind intracellular calcium ions during action potentials, reporting activity as brightness changes under two-photon microscopy. In vivo implementations have visualized population dynamics in cortical layers, revealing synchronized firing patterns during sensory stimuli. These methods provide subcellular resolution but are invasive, limiting human use to preclinical studies of learning and memory. Positron emission tomography (PET) maps functional activity by tracing radiotracer uptake, particularly with 18F-fluorodeoxyglucose (FDG) to quantify regional glucose metabolism as a proxy for neural energy demands. FDG, a glucose analog, is transported and phosphorylated in cells but not further metabolized, accumulating proportionally to metabolic rate via the Sokoloff operational equation derived from deoxyglucose kinetics. PET detects annihilation photons from positron decay, yielding 4-6 mm spatial resolution and images averaged over 30-60 minutes, useful for steady-state conditions like resting metabolism in Alzheimer's research. This technique's quantitative nature supports absolute rate measurements, though its lower temporal resolution suits chronic rather than transient activity mapping.

History

Early Developments

The early developments in brain mapping emerged in the 19th century with attempts to localize mental functions within specific brain regions, beginning with the pseudoscientific theory of phrenology proposed by Franz Joseph Gall in 1796. Gall posited that the brain consisted of independent organs corresponding to distinct mental faculties, such as memory or morality, and that the external shape of the skull reflected the underlying brain structure, allowing for personality assessment through craniometry.^[31] This localizationist approach gained popularity but was fundamentally flawed due to its reliance on superficial skull measurements rather than direct brain observation.^[31] Phrenology faced significant criticism in the early 19th century, particularly from Pierre Flourens, who through ablation experiments on animal brains in the 1820s demonstrated that removing specific cortical areas did not eliminate isolated faculties but instead produced diffuse impairments, supporting a more holistic view of brain function where higher cognition was distributed across the cerebrum.^[32] Flourens' work, detailed in his 1824 publication Recherches expérimentales sur les propriétés et les fonctions du système nerveux, refuted strict localization by showing that while the cerebellum coordinated motor activity and the cerebrum handled perception and intelligence, no precise modular organs existed as Gall claimed.^[33] These critiques shifted emphasis toward integrative brain models, influencing later neuroscientific inquiry. Advancements in lesion studies during the mid-19th century provided empirical evidence for cortical specialization, notably Paul Broca's 1861 identification of the left inferior frontal gyrus—now known as Broca's area—through postmortem examination of patient Louis Leborgne, who suffered from expressive aphasia despite intact comprehension after a stroke.^[34] Broca's findings, presented at the Société d'Anthropologie de Paris, linked damage in this region to impaired speech production, establishing a foundation for associating specific brain locales with language functions.^[35] Complementing this, Carl Wernicke in 1874 described a posterior superior temporal gyrus area in the left hemisphere, identified via autopsy of patients with fluent but incomprehensible speech, indicating its role in language comprehension and leading to the concept of sensory aphasia.^[36] Wernicke's seminal monograph Der aphasische Symptomencomplex integrated these observations into a connectionist model, proposing pathways between Broca's and Wernicke's areas for fluid language processing.^[37] By the early 20th century, microscopic techniques enabled more precise parcellation of the cortex through cytoarchitectonics, pioneered by Korbinian Brodmann in his 1909 work Vergleichende Lokalisationslehre der Großhirnrinde, which delineated 52 distinct areas based on variations in neuronal layering, density, and arrangement across the cerebral cortex.^[15] Brodmann's map, derived from histological analysis of human and primate brains, provided a structural framework for correlating cytoarchitecture with potential functions, such as area 17 for primary visual processing.^[15] Concurrently, Cécile and Oskar Vogt advanced myeloarchitectonics, mapping cortical regions by staining myelin fibers to reveal connectivity patterns; their 1919 atlas of the human frontal cortex identified subregions like the prefrontal area based on fiber arrangements, offering complementary insights into white matter organization.^[38] Rudimentary imaging techniques in the 1920s marked the transition to non-invasive visualization of gross brain structures. Pneumoencephalography, introduced by Walter Dandy in 1919 and refined in the 1920s, involved replacing cerebrospinal fluid with air via lumbar puncture to outline ventricles and detect abnormalities like tumors through X-ray imaging, though it was painful and carried risks of infection.^[39] Similarly, cerebral angiography, pioneered by Egas Moniz in 1927, utilized contrast agents injected into carotid arteries to radiographically depict vascular structures, enabling indirect assessment of brain displacements or lesions for the first time.^[40] These methods laid groundwork for later diagnostic tools by demonstrating the feasibility of in vivo brain outlining.

Key Milestones and Achievements

The invention of computed tomography (CT) by Godfrey Hounsfield in 1971 marked a pivotal advancement in brain mapping, allowing for the first non-invasive, cross-sectional imaging of the brain using X-rays and computer reconstruction.^[41] This breakthrough, demonstrated with the first clinical brain scan in October 1971 at Atkinson Morley's Hospital, enabled detailed visualization of brain structures without surgery, revolutionizing diagnostic capabilities.^[42] Building on this, Paul Lauterbur's development of magnetic resonance imaging (MRI) in 1973 introduced a non-ionizing method for generating high-contrast, three-dimensional images of brain anatomy and pathology. Lauterbur's technique, which used magnetic field gradients to encode spatial information in nuclear magnetic resonance signals, produced the first 2D MRI images of water-filled tubes and laid the foundation for soft-tissue differentiation essential to brain mapping.^[43] Together, CT and MRI shifted brain mapping from invasive procedures to precise, in vivo structural analysis, facilitating subsequent functional studies. The Human Connectome Project (HCP), launched in 2010 by the National Institutes of Health (NIH), represented a landmark effort to comprehensively map human brain connectivity across over 1,200 healthy young adults using multimodal imaging techniques including diffusion MRI, resting-state fMRI, and magnetoencephalography.^[44] This initiative generated open-access datasets that revealed individual variability in structural and functional networks, advancing understanding of brain wiring and its relation to cognition and behavior.^[45] In 2013, the BRAIN Initiative was established by President Barack Obama with an initial $100 million in federal funding to accelerate the development of innovative technologies for mapping and manipulating neural circuits.^[46] The program's 2014 BRAIN 2025 scientific vision outlined priorities for achieving whole-brain recording of dynamic neural activity at cellular resolution, fostering tools like high-density electrode arrays and optogenetics to capture real-time brain function.^[47] Under the BRAIN Initiative, the MICrONS (Machine Intelligence from Cortical Networks) project—a collaborative effort involving institutions including Princeton University—achieved a major milestone in 2025 by releasing a detailed functional connectome of mouse visual cortex, integrating electron microscopy reconstructions with calcium imaging data from approximately 75,000 neurons to map around 523 million synaptic connections.^[48] This dataset, combining structural wiring with activity patterns during visual tasks and produced through advanced serial-section electron microscopy and AI-assisted reconstruction, provided unprecedented insights into circuit-level computations underlying perception. These achievements underscore the rapid progress toward scalable, high-resolution brain atlases that bridge anatomy and function.^[49]

Applications

Clinical Applications

Brain mapping has revolutionized clinical neurology by enabling precise localization of pathological activity, guiding interventions for disorders like epilepsy. In epilepsy surgery planning, techniques such as EEG-fMRI integrate electrophysiological data with functional imaging to delineate epileptogenic networks, improving seizure control outcomes by up to 70% in refractory cases. This multimodal approach identifies resection zones while preserving eloquent areas, as demonstrated in studies where preoperative mapping reduced postoperative deficits. For Parkinson's disease, brain mapping informs deep brain stimulation (DBS) targeting, particularly the subthalamic nucleus (STN), where diffusion tensor imaging (DTI) and functional connectivity analysis refine electrode placement to optimize motor symptom relief. High-resolution mapping reveals individualized STN subregions, correlating with symptom-specific improvements, such as reductions of 70-90% in tremor severity post-DBS.^[50] These advancements stem from probabilistic atlases that account for anatomical variability, enhancing therapeutic precision. In psychiatric conditions, brain mapping provides biomarkers for diagnosis and treatment monitoring. Functional MRI (fMRI) identifies aberrant connectivity in the default mode network (DMN) in schizophrenia, where disrupted patterns predict symptom severity and response to antipsychotics, with studies showing 60-80% accuracy in classifying patient subgroups. Similarly, for major depressive disorder, resting-state fMRI detects hyperconnectivity in the subgenual cingulate, serving as a biomarker for treatment-resistant cases and guiding transcranial magnetic stimulation (TMS) protocols. Neuro-oncology benefits from brain mapping through intraoperative MRI (iMRI), which provides real-time structural and functional updates during tumor resection, significantly increasing the rate of gross total resection, with rates up to 70-80% in high-grade gliomas depending on the study, while minimizing neurological deficits.^[51] Diffusion imaging, including DTI, aids in glioma grading by quantifying white matter tract invasion, with fractional anisotropy metrics distinguishing low- from high-grade tumors with 85% sensitivity. Rehabilitation leverages brain mapping for stroke recovery, where task-based fMRI maps perilesional reorganization to tailor therapies, such as constraint-induced movement, enhancing motor function by 20-30% in chronic patients. Recent developments using connectome-based predictive modeling enable personalized rehabilitation plans that predict recovery trajectories with approximately 70% accuracy.^[52] In 2025, FDA authorization was granted for AI-based software that maps functional brain areas like speech and vision using resting-state fMRI in just 12 minutes, aiding surgical planning.^[53] These applications draw on functional techniques for non-invasive diagnostics, underscoring their translational value in patient care.

Research Applications

Brain mapping has significantly advanced cognitive neuroscience by enabling precise localization and analysis of neural networks underlying complex processes such as language comprehension and production. Magnetoencephalography (MEG) has been instrumental in mapping language networks, revealing dynamic interactions between regions like the superior temporal gyrus and inferior frontal gyrus during verbal tasks. For instance, studies using MEG to examine auditory word recognition have identified critical hubs in the temporal and frontal lobes that support receptive and expressive language functions, with peak activations occurring within 200-400 milliseconds post-stimulus.^[54] In parallel, optogenetics has revolutionized the study of memory formation and retrieval, particularly through the identification of memory engrams in the hippocampus. Seminal work demonstrated that optogenetic reactivation of specific hippocampal neuron ensembles labeled during fear conditioning can elicit full memory recall, establishing engrams as sparse, distributed cellular traces that encode episodic memories. This approach has further elucidated how engram cells in the dentate gyrus and CA1 regions consolidate contextual information, providing a cellular basis for long-term potentiation and synaptic plasticity in memory storage.^[55] Animal studies have leveraged brain mapping to uncover fundamental principles of neural circuitry, with the mouse connectome projects of the 2010s revealing recurrent motifs such as feedforward inhibition and balanced excitation-inhibition that underpin sensory processing. High-resolution tracing from the Allen Mouse Brain Connectivity Atlas, encompassing over 100 brain regions, highlighted motifs like disynaptic inhibitory loops in the visual cortex, which stabilize network activity and facilitate feature selectivity. These findings have informed models of cortical computation, showing how local circuit motifs scale to support adaptive behaviors. More recently, complete wiring diagrams of smaller brains have accelerated behavior modeling, as exemplified by the 2024 fruit fly connectome, which maps approximately 140,000 neurons and 50 million synapses across the adult Drosophila brain. This synapse-resolution diagram has enabled the identification of dedicated circuits for innate behaviors, such as locomotion and olfactory navigation, revealing motifs like parallel pathways that integrate sensory inputs for decision-making. By simulating these circuits computationally, researchers have predicted how synaptic weights modulate responses to environmental cues, bridging neural architecture to ethological outcomes.^[30] Evolutionary neuroscience benefits from brain mapping through comparative analyses of cortical expansion, where voxel-based morphometry (VBM) quantifies volumetric differences between primate species. VBM studies comparing human and chimpanzee brains have shown several-fold expansions (up to 4-fold) in prefrontal regions relative to chimpanzees, correlating with enhanced executive functions.^[56] These mappings, derived from MRI data normalized to stereotaxic templates, underscore how gyrification and areal proliferation in the association cortices diverged evolutionarily, informing hypotheses on the neural basis of abstract reasoning. The integration of neural data from brain mapping into artificial intelligence has inspired novel machine learning architectures. Connectomic datasets have informed biologically inspired models, such as those mimicking neural circuits to improve AI performance in tasks like sequence prediction.

Current Initiatives and Tools

Major Mapping Projects

The BRAIN Initiative, launched by the U.S. government in 2013 and ongoing as of 2025, represents a flagship effort to accelerate the development of innovative neurotechnologies for mapping and understanding the brain. With over $3 billion invested since 2014 to support more than 1,300 projects, the initiative emphasizes large-scale recording and modulation of neural activity. Its 2025 goals include advancing technologies for dynamic recording of neuronal activity across complete neural networks in all brain areas, enabling high-resolution insights into brain function over extended periods.^[57]^[47]^[58] The Human Brain Project, funded by the European Union from 2013 to 2023 with €607 million across 123 partners, focused on creating multiscale simulated brain models to integrate neuroscience data and simulate neural networks. This effort pioneered digital reconstructions of brain structures and functions, contributing to understandings of consciousness and artificial neural networks. Upon its conclusion, the project transitioned its outputs to the EBRAINS platform, a sustainable research infrastructure for sharing brain datasets, simulation tools, and high-performance computing resources to support ongoing neuroscience collaboration.^[59]^[59] The Blue Brain Project, based in Switzerland at the École Polytechnique Fédérale de Lausanne, worked from 2005 until its conclusion in December 2024 on digital reconstructions of the rodent neocortex to advance simulation neuroscience. By 2024, the project achieved a major milestone with the completion of multi-scale simulations modeling neurons, glia, synapses, and connectomes at the neuron-to-neuron level, enabling whole-brain simulations on supercomputers. This effort produced approximately 300 peer-reviewed publications and 18 million lines of open-source code, establishing biologically detailed models as a complementary tool for brain research.^[60] Other significant global initiatives include China's Brain Project, launched in 2016 as a 15-year national plan titled "Brain Science and Brain-Inspired Intelligence," which prioritizes non-human primate models for studying high-level cognition such as self-recognition and empathy. Leveraging extensive primate resources, including large macaque colonies at institutions like the Kunming Institute of Zoology, the project employs advanced techniques like single-neuron connectomics and CRISPR gene editing to model brain diseases. In November 2025, a major collaboration was launched to map primate brains, producing detailed neuron projections in the macaque prefrontal cortex.^[61]^[61]^[62] Japan's Brain/MINDS project, initiated in 2014 with ¥40 billion in funding and now in its Brain/MINDS 2.0 phase, targets comprehensive mapping of the common marmoset brain to bridge rodent and human neuroscience for understanding brain disorders. Organized across 65 laboratories, it develops multiscale atlases from macro- to micro-levels, transgenic disease models, and neurotechnologies like high-field MRI and tissue-clearing methods. The initiative has produced resources such as the 3D Digital Marmoset Brain Atlas to facilitate structural and functional brain mapping.^[63]^[63]^[64]

Digital Atlases and Databases

Digital atlases and databases serve as essential repositories for brain mapping data, enabling researchers to access, visualize, and integrate high-resolution structural, functional, and molecular information across species and modalities. These resources prioritize open access and interoperability, facilitating collaborative analysis through standardized formats and user-friendly interfaces that support tasks from data exploration to advanced computational modeling. The Allen Brain Atlas, developed by the Allen Institute for Brain Science, provides comprehensive multi-species maps of gene expression patterns and neural connectivity, covering the mouse, human, and nonhuman primate brains. It integrates transcriptomic data with anatomical references, allowing users to query expression levels in specific brain regions via an interactive web portal that supports 3D visualization and cross-species comparisons. In 2025, the atlas was updated with first drafts of developing mammalian brain cell atlases, incorporating single-cell transcriptomic data from human fetal and postnatal samples to map cell-type diversity and developmental trajectories.^[65] These enhancements improve usability by enabling seamless integration with other genomic datasets, aiding studies in neurodevelopment and disease. BigBrain offers an ultrahigh-resolution 3D reconstruction of the human brain, derived from serial histological sections of a postmortem specimen, achieving nearly cellular resolution at 20 μm isotropic voxels. This model captures detailed cytoarchitectonic features across the entire brain volume, serving as a reference atlas for aligning multimodal imaging data such as MRI and electron microscopy. Its open-access portal allows for downloadable volumes and tools for registration, promoting integration with functional datasets to study microstructure-function relationships.^[66] Connectome databases like the Human Connectome Project (HCP) portal provide large-scale, multimodal datasets including diffusion MRI for white matter tractography and resting-state functional MRI for connectivity mapping, derived from over 1,200 healthy young adults. The portal's ConnectomeDB interface enables querying and downloading preprocessed data with standardized pipelines, enhancing usability through web-based visualization and integration with tools for network analysis. Complementing this, the Neuroimaging Informatics Tools and Resources Clearinghouse (NITRC) hosts repositories of software such as FreeSurfer, which performs automated cortical surface reconstruction and parcellation for surface-based mapping of functional and structural data. NITRC's platform streamlines tool discovery and installation, fostering interoperability across neuroimaging workflows.^[4]^[67] Open-source software further supports data handling in these atlases. AFNI (Analysis of Functional NeuroImages) is a suite for processing and analyzing fMRI data, featuring tools for motion correction, statistical modeling, and 3D visualization that integrate well with atlas spaces like the Talairach or MNI templates. Similarly, ITK-SNAP facilitates interactive segmentation of brain structures in 3D and 4D images, using active contour methods and manual editing to delineate regions for mapping applications, with exports compatible to formats used in HCP and Allen resources. These tools emphasize user accessibility through graphical interfaces and scripting options, enabling efficient data integration without proprietary dependencies.^[68]^[69]

Challenges and Future Directions

Technical and Methodological Challenges

One of the primary technical challenges in brain mapping is the inherent trade-off between spatial resolution and coverage. Techniques such as serial section electron microscopy (ssEM) enable nanoscale imaging to visualize synaptic connections and fine neural structures, but they are constrained to small tissue volumes, typically on the order of hundreds of cubic microns, due to the labor-intensive sectioning and imaging processes required.^[70] In contrast, efforts to map entire brains or large regions often rely on lower-resolution methods like light-sheet microscopy, which provide broader coverage but lack the detail needed to resolve individual synapses or subcellular features.^[71] This dichotomy limits the ability to create comprehensive, high-fidelity maps that integrate both local circuitry and global architecture.^[72] The generation of brain mapping data also produces enormous volumes, often reaching petabyte scales even for modest tissue samples, posing significant hurdles in storage and processing. For instance, reconstructing a single cubic millimeter of human cerebral cortex at nanoscale resolution requires over 1 petabyte of raw data, overwhelming traditional computing infrastructure and necessitating specialized cloud-based systems for efficient access and analysis.^[71] These petascale datasets demand scalable solutions for data management, such as hierarchical storage and parallel input/output operations, to handle the computational burden of segmentation, reconstruction, and querying.^[73] In functional mapping modalities like electroencephalography (EEG), processing challenges are exacerbated by the ill-posed inverse problem in source localization, where multiple neural configurations can produce identical scalp signals, requiring regularization and assumptions about head conductivity to constrain solutions and reduce ambiguity.^[74] Integrating multi-modal data streams further complicates brain mapping, particularly when aligning structural images from magnetic resonance imaging (MRI) with histological sections. Differences in acquisition—such as tissue deformation during fixation and sectioning in histology, versus in vivo distortions in MRI—hinder precise registration, often necessitating landmarks or blockface imaging to correct for z-axis shifts and nonlinear warping.^[75] Artifacts from subject motion in MRI scans or inter-individual variability in postmortem tissue properties, including autolysis and fixation-induced contrast changes, introduce additional inconsistencies that propagate errors in fused maps.^[75] These alignment issues are compounded by spatiotemporal resolution mismatches between modalities, demanding computationally intensive algorithms to achieve coherent, multi-scale representations.^[76] Recent advancements in predictive modeling highlight ongoing methodological limitations, particularly in youth populations. Brain age prediction models, which estimate biological age from neuroimaging to detect deviations, exhibit inaccuracies in children and adolescents due to high developmental noise, including nonlinear trajectories and inter-individual variability in regional maturation patterns like cortical surface area peaking around ages 10–11.^[77] This noise can mask subtle pathological signals and reduce model reliability in narrow age ranges, underscoring the need for age-specific training data and regional analyses to improve precision.^[77]

Ethical and Societal Considerations

Brain mapping technologies generate vast amounts of neurodata, which can serve as unique biometric identifiers capable of revealing sensitive cognitive, emotional, and behavioral patterns. This raises significant privacy risks, as neural data's permanence and specificity make it difficult to anonymize, potentially enabling unauthorized re-identification even from aggregated datasets. For instance, cognitive biometrics derived from brain activity can infer mental states like intentions or preferences, exposing individuals to misuse in surveillance contexts where governments or employers monitor neural responses without consent. Similarly, neuromarketing applications exploit such data for targeted advertising, with companies using EEG and fMRI to predict consumer behavior, often bypassing robust consent mechanisms and heightening risks of psychological manipulation.^[78]^[79]^[78] Equity concerns in brain mapping are exacerbated by access disparities, particularly in the Global South, where limited infrastructure and funding restrict participation in large-scale projects, leading to higher dementia burdens—such as 8.7% prevalence in North Africa and the Middle East compared to 4.7% in Central Europe—without corresponding research investment. Datasets predominantly drawn from Global North populations introduce biases, underrepresenting diverse ethnic groups and resulting in models that poorly generalize; for example, only 1.5% of participants in some repositories like iSTAGING are Asian Americans, skewing AI-driven analyses of neurological diseases and perpetuating healthcare inequalities. These imbalances not only hinder accurate brain health insights for underrepresented populations but also amplify structural inequities, as seen in lower brain volumes linked to country-level inequality in temporoparietal regions across global cohorts.^[80]^[81]^[82] Neuroethics in brain mapping encompasses critical issues around consent for brain-computer interfaces (BCIs), where invasive enhancements raise questions about informed agreement amid uncertainties like long-term neural alterations or "brainjacking" risks from data breaches. Mapping consciousness through advanced neuroimaging challenges definitions of selfhood, potentially blurring lines between natural cognition and artificial augmentation, while cognitive enhancement via BCIs could foster a "cognitive divide" by privileging those with access, thereby undermining authenticity and social equality. These concerns extend to ethical imperatives for commercialization, emphasizing the need for safeguards against third-party manipulation of thoughts or emotions without explicit, revocable consent.^[83]^[84]^[83] In 2025, policy frameworks address these issues through regulations like extensions of the EU AI Act to neurotech, classifying neural data as high-risk biometric information under proposed GDPR revisions and mandating transparency, opt-in consent, and privacy-by-design for devices. The Act's provisions, effective from August 2025 for general-purpose AI models, prohibit manipulative neurotech applications and require risk assessments for BCIs, with compliance deadlines extending to 2027 for high-impact systems. Complementing this, the Organization for Human Brain Mapping (OHBM) guidelines via the COBIDAS framework promote responsible data sharing in neuroimaging by advocating open practices, reproducibility, and ethical anonymization to mitigate privacy risks while enabling global collaboration. Additionally, the European Charter for Responsible Neurotechnology Development outlines principles for equitable access and secure data handling, urging proportionality and minimization in neural data processing.^[85]^[86]^[87]^[88]

References

[1]
Summary - Mapping the Brain and Its Functions - NCBI Bookshelf
The Brain Mapping Initiative proposed in this report will allow investigators studying the brain to view data in new ways, to communicate data to each other ...
[2]
Mapping structure-function relationships in the brain - PMC
In this review, we examine recently developed methods for EC mapping in animals in combination with optogenetics. We focus on techniques employing hemoglobin as ...
[3]
https://www.neurologyindia.com/text.asp?2018/66/4/1010/235852
[4]
BRAIN 2025: A Scientific Vision | BRAIN Initiative
Below is a merged summary of the BRAIN Initiative goals and achievements in brain mapping, consolidating all information from the provided segments into a comprehensive response. To maximize detail and clarity, I will use a structured table format in CSV style for key priorities and achievements, followed by an overview and additional details in narrative form. This ensures all information is retained while maintaining readability.
[5]
Precision functional mapping of individual human brains - PMC
Highly-sampled fMRI data allow reliable, individual-specific, and externally valid descriptions of brain organization. Descriptions of an individual's brain ...Missing: credible sources
[6]
https://braininitiative.nih.gov/vision/nih-brain-initiative-reports/brain-20-report-cells-circuits-toward-cures
[7]
neuromaps: structural and functional interpretation of brain maps
Oct 6, 2022 · Here we introduce neuromaps, a toolbox for accessing, transforming and analyzing structural and functional brain annotations.
[8]
What is the Difference Between Neurology and Neuroscience?
Neuroscience describes the scientific study of the mechanics of the central nervous system such as its structure, function, genetics and physiology.
[9]
Focus on human brain mapping | Nature Neuroscience
Feb 23, 2017 · Neuroscientists endeavor to understand how the brain develops and controls our perception of the world and our interactions with it. Animal ...
[10]
Brain Mapping - Neurology - UCLA Health
The mission of Brain Mapping is to define the structure and function of the human brain in health and disease.
[11]
An empirical, 21st century evaluation of phrenology - PMC
Phrenology was a nineteenth century endeavour to link personality traits with scalp morphology, which has been both influential and fiercely criticised.
[12]
The anatomy of the brain – learned over the centuries - PMC
Following the analysis of the history of the study of neuroanatomy, we find the founder of anatomical mapping of the brain, Korbinian Brodmann (1868–1918).
[13]
Brodmann: a pioneer of human brain mapping—his impact on ...
Oct 25, 2018 · Brodmann's work is a paradigmatic shift from functional considerations in the succession of phrenology as used by Gall, Meynert, and Flechsig ...
[14]
The Road to Personalized Medicine in Alzheimer's Disease - NIH
Jan 29, 2022 · Neuroimaging represents a crucial tool on the characterization of AD. MRI images allow for the evaluation of the structural status of the brain ...
[15]
New brain mapping technique identifies cells vulnerable to ...
Mar 6, 2025 · A new brain-mapping technique to identify memory-related brain cells vulnerable to protein buildup, a key factor in the development of Alzheimer's disease.
[16]
University of Surrey researchers mimic brain wiring to improve AI
Nov 2, 2025 · According to a study published in Neurocomputing, mimicking the brain's neural wiring can significantly improve the performance of artificial ...
[17]
Neurotechnology Market Size, Share & Industry Forecast, 2025-2030
Jun 11, 2025 · The neurotechnology market size is estimated at USD 15.77 billion in 2025, and is expected to reach USD 29.74 billion by 2030, at a CAGR of ...
[18]
Mind-body connection is built into brain, study suggests
A new study by researchers at Washington University School of Medicine in St. Louis reveals that a connection between the body and mind is built into the ...
[19]
Growing Brains, Nurturing Minds—Neuroscience as an Educational ...
This review takes a neuroscientific lens to explore central concepts in education (eg, mindset, motivation, meaning-making, and attention)
[20]
Priority Areas | BRAIN Initiative - NIH
Jan 22, 2025 · BRAIN 2025 Recommendation: The brain in action: Produce a dynamic picture of the functioning brain by developing and applying improved ...
[21]
A look back on the BRAIN Initiative in 2024 (and what's coming in ...
The end-of-year recap below has more on the latest research and advancements from the BRAIN Initiative, and a first look at what's to come in 2025. Advancements ...
[22]
Diffusion tensor imaging (DTI)-based white matter mapping in brain ...
Diffusion tensor imaging (DTI) has become one of the most popular MRI techniques in brain research, as well as in clinical practice.
[23]
Voxel-based morphometry--the methods - PubMed
This paper describes the steps involved in VBM, with particular emphasis on segmenting gray matter from MR images with nonuniformity artifact. We provide ...Missing: original | Show results with:original
[24]
Voxel-Based Morphometry: An Automated Technique for Assessing ...
It uses statistics to identify differences in brain anatomy between groups of subjects, which in turn can be used to infer the presence of atrophy.
[25]
An Automated Mapping Method for Nissl-stained Mouse Brain ...
Oct 1, 2018 · The automated method uses the Allen Brain Atlas to map brain regions on digitized Nissl-stained sections, identifying neuroanatomic structures.
[26]
Nissl Staining - an overview | ScienceDirect Topics
Nissl staining is a technique used to highlight cell types and neuron structures, especially under light microscopy, for brain architecture mapping.
[27]
A Complete Electron Microscopy Volume of the Brain of Adult ...
Jul 19, 2018 · To meet the challenge of acquiring a whole fly brain, we used a variation of classical serial section TEM (ssTEM), in which images are acquired ...
[28]
Neuronal wiring diagram of an adult brain - Nature
Oct 2, 2024 · Images of an entire adult female fly brain (Fig. 1e,f) were previously acquired by serial section transmission electron microscopy and released ...Missing: ssEM | Show results with:ssEM
[29]
Franz Joseph Gall's non‐cortical faculties and their organs - NIH
Sep 9, 2019 · Franz Joseph Gall (1758–1828) is remembered for his claims that behavior results from a large number of independent mental faculties, and that these faculties ...
[30]
Pierre Flourens - LITFL
Jan 28, 2022 · Flourens, through a series of ablation experiments in animals, determined that the 'mind' was located in the brain, and not the heart.
[31]
(PDF) Flourens, Pierre - ResearchGate
... Phrenology's strongest early critic was Pierre Flourens, who in the early 1820s experimentally ablated or extirpated parts of the brains of frogs, rabbits, ...Missing: critique holistic
[32]
Re-establishing Broca's Initial Findings - PMC - NIH
In 1861, Broca described Leborgne, a patient ... The greatest lesion overlap among AOS patients was found in LAIns, with less involvement of Broca's area.
[33]
Chapter 8: Higher Cortical Functions: Language
In 1861, Broca described a patient named Leborgne who could understand language but could not speak. He had no motor deficits to account for his inability to ...
[34]
Carl Wernicke of the Wernicke Area: A Historical Review
Wernicke based his theory of language on 3 main points: the cerebral cortex being the organ of consciousness, specific parts of the brain holding particular ...
[35]
Carl Wernicke • LITFL • Medical Eponym Library
Jun 18, 2025 · Wernicke's area. Wernicke identified the posterior superior temporal gyrus of the dominant hemisphere as essential for language comprehension.Biography · Medical Eponyms · Wernicke's Area
[36]
The myeloarchitectonic studies on the human cerebral cortex of the ...
Oct 18, 2012 · At the beginning of the twentieth century, two young investigators, Oskar and Cécile Vogt founded a centre for brain research, aimed to be ...
[37]
Cerebral pneumography and the 20th century localization of brain ...
Feb 6, 2018 · One century has passed since Walter Dandy invented the techniques of ventriculography and pneumoencephalography, which provided an invaluable ...
[38]
Egas Moniz: 90 Years (1927–2017) from Cerebral Angiography - NIH
Sep 19, 2017 · The year 2017 marks the 90th anniversary of the pioneer discovery of cerebral angiography, the original imaging technique used for visualizing cerebral blood ...
[39]
Sir Godfrey Hounsfield - PMC - NIH
Engineer who invented computed tomography and won the Nobel prize for medicine. ... The first patient was scanned in September 1971 at Atkinson Morley's Hospital ...
[40]
How CT happened: the early development of medical computed ...
On Friday, October 1, 1971, a new procedure was performed to image a live patient's brain. After a (lengthy) computer processing reconstruction delay, a ...
[41]
Magnetic Resonance Imaging: The Nuclear Option - PMC - NIH
Lauterbur first demonstrated MR imaging in 1973, in which he published NMR images of two tubes of water. In the same year, and Sir Peter Mansfield ...
[42]
Human Connectome Project (HCP) - National Institute of Mental ...
The Human Connectome Project was launched in 2009 as part of the NIH Blueprint Grand Challenges . The Blueprint Grand Challenges were intended to promote major ...
[43]
The Human Connectome Project: A Retrospective - PMC
The Human Connectome Project (HCP) was launched in 2010 as an ambitious effort to accelerate advances in human neuroimaging, particularly for measures of ...
[44]
Fact Sheet: BRAIN Initiative - Obama White House Archives
Apr 2, 2013 · Launched with approximately $100 million in the President's Fiscal Year 2014 Budget, the BRAIN (Brain Research through Advancing Innovative ...
[45]
https://pmc.ncbi.nlm.nih.gov/articles/PMC9387634/
[46]
Functional connectomics spanning multiple areas of mouse visual ...
Apr 9, 2025 · Here we introduce the MICrONS functional connectomics dataset with dense calcium imaging of around 75,000 neurons in primary visual cortex (VISp) ...
[47]
Scientists map the half-billion connections that allow mice to see
Apr 9, 2025 · The map of every neuron in a cubic millimeter of mouse brain promises to accelerate the study of normal brain function as well as deepen the study of brain ...Missing: 2024 | Show results with:2024
[48]
Mapping Critical Hubs of Receptive and Expressive Language ...
Nov 1, 2019 · We examined MEG and fMRI data from 12 healthy young adults (age 20-37 years) completing covert auditory word-recognition task (WRT) and covert ...
[49]
Optogenetic stimulation of a hippocampal engram activates fear ...
Here we show that optogenetic reactivation of hippocampal neurons activated during fear conditioning is sufficient to induce freezing behavior.Missing: seminal | Show results with:seminal
[50]
Genetic mapping and evolutionary analysis of human-expanded ...
Oct 24, 2019 · Cortical morphometry of the chimpanzee and human cortex was assessed using a surface-to-surface mapping of 3D reconstructions of the cortical ...
[51]
Decoding the brain: From neural representations to mechanistic ...
Oct 17, 2024 · In this perspective, we detail important concepts of neural encoding and decoding and highlight the mathematical tools used to measure them, including deep ...
[52]
The BRAIN Initiative® and NIDCD
Feb 6, 2025 · Since 2014, the BRAIN Initiative has invested more than $3 billion to fund more than 1,300 projects.Missing: total | Show results with:total
[53]
RFA-NS-25-018: BRAIN Initiative - NIH Grants & Funding
Sep 24, 2024 · This NOFO seeks applications for proof-of-concept testing and development of new technologies and novel approaches for recording and modulation ...
[54]
Human Brain Project & EBRAINS
EBRAINS is now transitioning into a sustainable infrastructure that will remain available to the scientific community as a lasting contribution of the Human ...
[55]
Blue Brain Project ‐ EPFL
The Blue Brain Project, a Swiss initiative, aimed to build digital mouse brain simulations to understand the brain using simulation neuroscience.Missing: scale | Show results with:scale
[56]
China Brain Project: Basic Neuroscience, Brain Diseases, and Brain ...
Nov 2, 2016 · ... non-human primates (NHPs). These high-level cognitive functions are ... Primate Resource Center, potentially the largest NHP research resource in ...Main Text · Neural Circuit Mechanisms Of... · Early Diagnosis And...
[57]
A Japanese National Brain Project for Marmoset Neuroscience
Nov 2, 2016 · The project aims to build a multiscale marmoset brain map, develop new technologies for experimentalists, create transgenic lines for brain disease modeling.
[58]
Scientists complete first drafts of developing mammalian brain cell ...
Nov 5, 2025. Multiple mouse and human brain atlases track the emergence of distinct cell types during development and uncover pathways that decide a cell's ...Missing: connectivity | Show results with:connectivity
[59]
BigBrain: an ultrahigh-resolution 3D human brain model - PubMed
Jun 21, 2013 · We created an ultrahigh-resolution three-dimensional (3D) model of a human brain at nearly cellular resolution of 20 micrometers.Missing: 1μm voxels primary source
[60]
Human Connectome Project
HCP Lifespan Projects are acquiring and sharing multimodal imaging data acquired across the lifespan, in four age groups (prenatal, 0-5, 6-21, and 36-100+).About the CCF (CCF Overview) · Software · Disease Studies · Using ConnectomeDBMissing: portal diffusion
[61]
FreeSurfer: Tool/Resource Info - NITRC
FreeSurfer is a set of automated tools for reconstruction of the brain's cortical surface from structural MRI data, and overlay of functional MRI data onto the ...
[62]
afni.nimh.nih.gov
AFNI (Analysis of Functional NeuroImages) is a leading software suite of C, Python, R programs and shell scripts primarily developed for the analysis and ...Documentation · Bootcamp · About · Class Handouts
[63]
ITK-SNAP Home
ITK-SNAP is a free, open-source, multi-platform software application used to segment structures in 3D and 4D biomedical images. It was originally developed ...Downloads · Links · Documentation · NewFeaturesVersion40
[64]
Correlated Light-Serial Scanning Electron Microscopy (CoLSSEM ...
Sep 27, 2018 · Current SSEM approaches are mainly applied to small pieces of brain tissue (~hundreds of cubic microns), which is incompatible with the mapping ...
[65]
A petavoxel fragment of human cerebral cortex reconstructed at ...
May 10, 2024 · Connectomic imaging approaches are now available to render neural circuits of sufficiently large volume and high enough resolution to study the ...Missing: ssEM | Show results with:ssEM
[66]
Brain Mapping at High Resolutions: Challenges and Opportunities
Aug 6, 2025 · Methods for imaging the architecture of the brain at high resolutions, and across large volumes, are rapidly improving.Missing: ssEM | Show results with:ssEM
[67]
The Brain Observatory Storage Service and Database (BossDB)
Due to the challenges in collection, storage, and analysis of terascale and petascale data volumes, few public datasets of this size are routinely shared, even ...
[68]
Review on solving the inverse problem in EEG source analysis - PMC
In this primer, we give a review of the inverse problem for EEG source localization. This is intended for the researchers new in the field to get insight.
[69]
Mixed methodology in human brain research: integrating MRI ... - NIH
Jun 26, 2023 · The integration of the methodologies when combining MRI and histology requires the balancing of the opportunities and challenges associated with ...
[70]
Multimodal neuroimaging computing: the workflows, methods, and ...
Sep 4, 2015 · Multimodal neuroimaging computing is a very challenging task due to large inter-modality variations in spatiotemporal resolution, and ...Missing: histology variability
[71]
Current challenges and future directions for brain age prediction in ...
Aug 20, 2025 · Brain-age prediction has been investigated in relation to a number of domains in youth, including mental health, genetics, physical development, ...Missing: inaccuracies | Show results with:inaccuracies
[72]
Beyond neural data: Cognitive biometrics and mental privacy
Sep 25, 2024 · This paper challenges the current approach to protecting individuals through legal protections for “neural data” and advocates for a more expansive legal and ...Missing: neuromarketing | Show results with:neuromarketing
[73]
Regulating the Mind: Neuromarketing, Neural Data and Stakeholder ...
Critics further argue that reliance on neurodata introduces heightened privacy risks, as biometric and neurological information is uniquely sensitive ...Missing: identifiers surveillance
[74]
Global South research is critical for understanding brain health ...
Nov 21, 2023 · The impact of high levels of disparities on brain health and ageing in underserved populations is evident across various aspects, including ...
[75]
Neuroimaging data repositories and AI-driven healthcare—Global ...
In this paper, we examined the ethical concerns of ML-driven modeling of global community neuroscience needs arising from the use of data amassed within ...<|separator|>
[76]
Structural inequality linked to brain volume and network dynamics in ...
Dec 27, 2024 · Higher country-level inequality was consistently associated with lower brain volume, particularly in temporoparietal and cerebellar areas across all groups.
[77]
Ethical considerations for the use of brain–computer interfaces ... - NIH
Oct 28, 2024 · This essay explores the ethical, scientific and practical challenges posed by the use of this technology for cognitive enhancement.
[78]
Ethical imperatives in the commercialization of brain-computer ...
The rapid commercialization of brain-computer interfaces (BCIs) raises urgent ethical and scientific challenges for human research oversight.
[79]
EU Policy & Regulatory | Neurotech - Considerati
Apr 30, 2025 · As the EU prepares its first neurotech-specific legislative package for late 2025, companies must engage in consultative drafting processes ...Missing: extensions OHBM sharing
[80]
Implications of the novel EU AI Act for neurotechnologies
Sep 25, 2024 · The EU AI Act, the first comprehensive regulation of AI, came into effect in August. Here, we provide an overview of the provisions that apply to the field of ...Missing: extensions | Show results with:extensions
[81]
[PDF] European Charter for the Responsible Development of ...
The Charter aims to provide ethical guidance for the successful development of neurotechnologies in Europe by: Promoting equality of access and encouraging ...
[82]
[PDF] Best Practices in Data Analysis and Sharing in Neuroimaging using ...
This report elaborates principles of open and reproducible research for neuroimaging using MRI, and distills these principles to specific research practices.