asnweb

https://www.asnweb.org/i4a/pages/index.cfm?pageID=3334

[1] History of Neuroimaging | The American Society of Neuroimaging — History of Neuroimaging. Presented to the ASN from the Archives by William McKinney. Edited and adapted for the ASN website by Rohit Bakshi. ... because the advent of new techniques for imaging the brain and spinal cord, for measuring its blood flow and neural function, are of greatest importance for care of patients with neurologic disorders

wikipedia

https://en.wikipedia.org/wiki/Neuroimaging

[4] Neuroimaging - Wikipedia — Functional brain imaging techniques, such as functional magnetic resonance imaging (fMRI), are common in neuroimaging but rarely used in neuroradiology. The biggest drawback of PET scanning is that because the radioactivity decays rapidly, it is limited to monitoring short tasks.: 60  Before fMRI technology came online, PET scanning was the preferred method of functional (as opposed to structural) brain imaging, and it continues to make large contributions to neuroscience. PET radioisotopes have limited exposure time in the body as they commonly have very short half-lives (~2 hours) and decay rapidly. Currently, fMRI is a preferred method of imaging brain activity compared to PET, since it does not involve radiation, has a higher temporal resolution than PET, and is more readily available in most medical settings.

sciencedirect

https://www.sciencedirect.com/topics/psychology/neuroimaging

[5] Neuroimaging - an overview | ScienceDirect Topics — A brief overview of select neuroimaging techniques is provided in Box 1. In addition to the variety of techniques that can be used to examine structural and functional properties of the living brain, neuroimaging is feasible in patient populations so long as they are able to lay still for a short amount of time (10-60 min). In fact

researchgate

https://www.researchgate.net/publication/288218387_Cognition_An_Overview_of_Neuroimaging_Techniques

[6] Cognition: An Overview of Neuroimaging Techniques - ResearchGate — The advent of neuroimaging techniques for use in humans has led to an explosion of research on the neural basis of cognitive processes in humans during the past decade.

nih

https://pubmed.ncbi.nlm.nih.gov/23143086/

[7] PET/MRI for neurologic applications - PubMed — PET and MRI provide complementary information in the study of the human brain. Simultaneous PET/MRI data acquisition allows the spatial and temporal correlation of the measured signals, creating opportunities impossible to realize using stand-alone instruments. This paper reviews the methodologic im …

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC3806202/

[8] PET/MRI for Neurological Applications - PMC - PubMed Central (PMC) — The features of this new technology may be particularly appealing to applications in neuroscience and translational neurologic/psychiatric research, considering that MR represents the first-line diagnostic imaging modality for numerous indications and that a great number of specific PET tracers are available today to assess functional and molecular processes in the brain. The concept of baseline state is an essential, though often overlooked, aspect of brain activation studies because the change in signal reported in response to a stimulus (measured either with PET or MR imaging techniques) is typically assessed with respect to an (unquantified) baseline condition. Simultaneous MR/PET imaging of the human brain: feasibility study.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC5485669/

[9] Neurological Applications of PET/MR - PMC - PubMed Central (PMC) — PET/MR benefits neurological clinical care and research by providing spatially and temporally matched anatomic MR imaging, advanced MR physiologic imaging, and metabolic PET imaging. ... Work published in this article was supported NIH grants P50 AG05681, ... Journal of magnetic resonance imaging: JMRI. 2012 Jan;35(1):56-63. doi: 10.1002/jmri

eejournals

https://www.eejournals.org/public/uploads/1727620020_457d8658cf6baed03c46.pdf

[18] PDF — https://www.eejournals.org Open Access Page | 5 Advancements in Neuroimaging for Early Detection of Neurological Disorders Kato Jumba K. This paper examines the most recent breakthroughs in neuroimaging, with a focus on resting-state functional MRI, presymptomatic detection in Alzheimer's research, diffusion tensor imaging for white matter analysis, and magnetoencephalography. Keywords: Neuroimaging, Early Detection, Alzheimer's Disease, Functional MRI, Diffusion Tensor Imaging INTRODUCTION Advancements in neuroimaging for early detection of neurological disorders. APPLICATIONS OF NEUROIMAGING IN EARLY DETECTION Neuroimaging is becoming increasingly useful in the early diagnosis and monitoring of neurological disorders. Technologies such as resting-state functional MRI, diffusion tensor imaging, and magnetoencephalography have provided unprecedented insights into the brain's structure and function, allowing for earlier and more accurate detection of diseases like Alzheimer’s and other neurodegenerative conditions. Advancements in Neuroimaging for Early Detection of Neurological Disorders.

inmed

https://inmed.ai/2024/03/01/exploring-the-future-of-neuro-diagnostics-advanced-imaging-and-ai/

[26] Exploring the Future of Neuro-Diagnostics: - InMed — Exploring the Future of Neuro-Diagnostics: ... Neuroimaging modalities/techniques have progressed in the past two decades. The techniques are quicker, less invasive and more comfortable. ... The role of neuroimaging in diagnosis and personalized medicine-current position and likely future directions. Dialogues Clin Neurosci [Internet]. 2009

wikipedia

https://en.wikipedia.org/wiki/History_of_neuroimaging

[35] History of neuroimaging - Wikipedia — Neuroimaging first came about as a medical technique in the 1880s with the invention of the human circulation balance and has since lead to other inventions such as the x-ray, air ventriculography, cerebral angiography, PET/SPECT scans, magnetoencephalography, and xenon CT scanning. "Brain Imaging Explained." Online at http://www.nature.com/nsu/010712/010712-13.html "Connecting Cortex to Machines: Recent Advance in Brain Interfaces." Online at http://www.nature.com/cgi-taf/DynaPage.taf?file=/neuro/journal/v5/n11s/full/nn947.html "UCLA Researchers Map Brain Growth in Four Dimensions, Revealing Stage-Specific Growth Patterns in Children." Online at https://web.archive.org/web/20041204085436/http://www.loni.ucla.edu/~thompson/MEDIA/press_release.html and https://web.archive.org/web/20041204083259/http://www.loni.ucla.edu/~thompson/JAY/Growth_REVISED.html "Bioinformatics and Brain Imaging: Recent Advances and Neuroscience Applications." Online at https://web.archive.org/web/20050118095748/http://www.loni.ucla.edu/~thompson/SFN2002/SFN2002coursePT_v4.pdf "Brain Scan Technology Poised to Play Policy Roll." Online at https://web.archive.org/web/20041204084542/http://www.loni.ucla.edu/~thompson/MEDIA/RH/rh.html

neurography

https://www.neurography.com/wp-content/uploads/2016/12/neurography-imaginghistory.pdf

[36] PDF — On October 1, 1971 Godfrey Hounsfield and Jamie Am-brose positioned a patient inside a new machine in the basement of the hospital turned a switch and launched the era of modern neurosurgery and neuroimaging.

asnweb

https://www.asnweb.org/i4a/pages/index.cfm?pageID=3334

[37] History of Neuroimaging | The American Society of Neuroimaging — In recounting a history of his life in neuroimaging to the American Society of Neuroimaging (ASN) in 1992, Oldendorf discussed Godfrey Hounsfield and his successful introduction of the CT scanner. In 1975 James Toole, MD chairman of the Ad hoc committee on Neuroimaging of the American Academy of Neurology (AAN) wrote to Oldendorf regarding his opinion of the effect of CT scanning on the practice of neurology. In 1972 Dr. William Stuart of Atlanta, Georgia visited the Massachusetts General Hospital to see a new piece of equipment that “was going to revolutionize the practice of neurology.” He returned to Atlanta with Polaroid images from the “primitive CT scan of that period.” The Atlanta neurologists bought the 16th scanner off the EMI assembly line.

worldbrainmapping

https://www.worldbrainmapping.org/courses/lessons/historical-advancements-in-neuroimaging-techniques/

[38] Historical Advancements in Neuroimaging Techniques — Historical Advancements in Neuroimaging Techniques - Society for Brain Mapping and Therapeutics SOCIETY FOR BRAIN MAPPING AND THERAPEUTICS What is Brain Mapping Annual Brain Mapping Day at the US Congress SBMT Initiatives ME + Brain ME + Brain Impact: This discovery revolutionized understanding of how the brain operates in a baseline state and its alterations in disorders like Alzheimer’s, schizophrenia, and depression. MRI provides high-resolution images of brain structures, enabling early detection of tumors, multiple sclerosis, and stroke. Pre-surgical Planning: MRI and DTI help map brain structures and connectivity, minimizing risks during neurosurgery. The Society for Brain Mapping and Therapeutics (SBMT) was founded in 2004 to break boundaries in healthcare. What Is Brain Mapping Copyright © 2024 Society for Brain Mapping and Therapeutics (SBMT).

nih

https://pubmed.ncbi.nlm.nih.gov/20382954/

[39] History of neuroimaging: the legacy of William Oldendorf — The field of neuroimaging witnessed remarkable progress in the post-World War II era, resulting in tremendous benefits for healthcare today. One such important milestone was the development of the computerized axial tomography (CAT) scan. This state of the art technique has paved the way for modern …

alliedacademies

https://www.alliedacademies.org/articles/the-evolution-of-brain-imaging-from-ct-scans-to-fmri-and-beyond.pdf

[40] PDF — strategies, and a deeper understanding of brain function . Conclusion The evolution of brain imaging, from the early days of CT scans to the sophisticated techniques of today, has profoundly expanded our knowledge of the brain. Each advancement has provided new insights into neurological function and disease, improving diagnosis and treatment.

ajnr

https://www.ajnr.org/content/24/9/1739

[65] Neuroethics in a New Era of Neuroimaging | American Journal of ... — The ethical challenges introduced by advanced capabilities in neuroimaging were recognized as a priority for the new discipline, taking into consideration significant concerns and potentially thorny issues that have surfaced both in research and in the clinical environment.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0278262602005183

[66] Legal and ethical issues in neuroimaging research: human subjects ... — Current efforts to delineate the field of "neuroethics" reflect an emerging view that ethical problems in the neurosciences merit a distinct domain within the broader arena of bioethics (Stanford Center for Bioethics, 2002).As evidenced by this special issue of the journal Brain and Cognition, neuroimaging techniques are a logical focus for this new "neuroethical" inquiry, given the

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0160791X1600004X

[67] Exploring responsible innovation: Dutch public perceptions of the ... — Insight into public perceptions provides opportunities to take public desires and concerns into account in an early phase of innovation development in order to maximise the potential benefits for users of the future. Public perceptions of neuroimaging in health care are presented in this article, based on research undertaken in the Netherlands.

nih

https://pubmed.ncbi.nlm.nih.gov/37511847/

[69] Exploring the Frontiers of Neuroimaging: A Review of Recent Advances in ... — Exploring the Frontiers of Neuroimaging: A Review of Recent Advances in Understanding Brain Functioning and Disorders - PubMed Exploring the Frontiers of Neuroimaging: A Review of Recent Advances in Understanding Brain Functioning and Disorders Exploring the Frontiers of Neuroimaging: A Review of Recent Advances in Understanding Brain Functioning and Disorders Functional magnetic resonance imaging (fMRI) and electroencephalography (EEG) are two widely used neuroimaging techniques to review changes in brain activity. Recent advances in fMRI technology, its application to studying brain function, and the impact of neuroimaging techniques on neuroscience research are discussed. Neuroimaging techniques such as fMRI (A) and EEG (B) have revolutionized our understanding of brain function and have become essential tools in studying neurological disorders.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC6221760/

[71] The vast potential and bright future of neuroimaging - PMC — Quantitative neuroimaging is well-suited for statistical modeling and systematic image analysis approaches that utilize canonical templates or brain atlases to measure changes in specific regions of interest.7 Quantitative methods are beginning to evaluate the brain as an integrated structural and functional network.8 These new approaches might be critical not only for deciphering brain circuitry but also for understanding the dysfunction of brain network connectivity that occurs during the progression of many neurological and psychiatric disorders.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC7479713/

[72] Advances in functional magnetic resonance imaging: Technology and ... — Investigators have used fMRI to identify abnormal functional brain activity during task performance in a variety of patient populations, including those with neurodegenerative, demyelinating, cerebrovascular, and other neurological disorders that highlight the potential utility of fMRI in both basic and clinical spheres of research.

globalsante

https://globalsante.org/en/the-latest-advances-in-functional-mri/

[73] Functional MRI: The Revolutionary Innovations of 2023 — Functional magnetic resonance imaging (fMRI) is a revolutionary technique in medicine that allows real-time visualization of brain activity. The integration of artificial intelligence into fMRI image analysis also opens new perspectives for the rapid detection of pathologies. Advances in imaging, new analysis methods, and better awareness among practitioners will enable optimal use of this technology, thus transforming the diagnosis and treatment of neurological diseases. A new imaging technology against cancer powered by artificial intelligence in Hong Kong Recevez directement dans votre boîte mail les dernières actualités, articles, et ressources pour rester informé et inspiré, où que vous soyez. GlobalSante.org est une plateforme dédiée aux professionnels de la santé, offrant des articles spécialisés, des ressources pratiques, et les dernières actualités médicales.

worldbrainmapping

https://www.worldbrainmapping.org/courses/lessons/case-studies-fmri-in-neurological-disorders/

[74] Case Studies: fMRI in Neurological Disorders - Society for Brain ... — Case Study 1: Memory and Aging Objective: Analyze how resting-state fMRI uncovers changes in functional connectivity linked to aging. Example: A longitudinal study involving older adults used resting-state fMRI to detect early signs of Alzheimer's disease by observing disruptions in the Default Mode Network (DMN). Researchers identified that decreased connectivity in specific DMN regions

nature

https://www.nature.com/articles/s41586-023-06670-9

[75] Functional neuroimaging as a catalyst for integrated neuroscience — Functional magnetic resonance imaging (fMRI) enables non-invasive access to the awake, behaving human brain. By tracking whole-brain signals across a diverse range of cognitive and behavioural states or mapping differences associated with specific traits or clinical conditions, fMRI has advanced our understanding of brain function and its links to both normal and atypical behaviour. Q. Typical and atypical development of functional human brain networks: insights from resting-state fMRI. This article presents a method for concurrent widefield optical imaging and fMRI, enabling cell-type-specific investigations of how different neural populations contribute to the fMRI signal as well as more precise translation between mouse models and human studies. M. Functional brain connectivity Using fMRI in aging and Alzheimer’s disease. L. Identifying natural images from human brain activity. & Shine, J.M. Functional neuroimaging as a catalyst for integrated neuroscience.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC4520679/

[81] Integration of multimodal neuroimaging methods: a rationale for ... — The EEG-fMRI approach has several promising clinical applications. The first is the detection of cortical areas involved in interictal and ictal epileptic activity. Second, combining evoked potentials with fMRI could be an accurate way to study eloquent cortical areas for the planning of neurosurgery or rehabilitation, circumventing the above-mentioned limitation of fMRI. Finally, the use of

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0278262602005183

[98] Legal and ethical issues in neuroimaging research: human subjects ... — Legal and ethical issues in neuroimaging research: human subjects protection, medical privacy, and the public communication of research results - ScienceDirect Legal and ethical issues in neuroimaging research: human subjects protection, medical privacy, and the public communication of research results The focus will be on three issues of contemporary significance in clinical research: compliance with regulatory requirements for the protection of human subjects, safeguarding privacy and confidentiality, and ethical behavior in the public communication of research results. This paper has explored ethical issues of significance to neuroimaging researchers, including protections for human subjects, issues of privacy and confidentiality, and a researcher’s obligation to communicate science responsibly.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC5033543/

[99] Ethical considerations of neuroscience research and the application of ... — The International Neuroethics Society (INS) recently commented on the ethical considerations of neuroscience research and the application of neuroscience research findings for the Presidential Commission for the Study of Bioethical Issues, published in the Federal Register Jan. 31, 2014. COMMENTS BY THE INTERNATIONAL NEUROETHICS SOCIETY (INS) ON THE ETHICAL CONSIDERATIONS OF NEUROSCIENCE RESEARCH AND THE APPLICATION OF NEUROSCIENCE RESEARCH FINDINGS FOR THE PRESIDENTIAL COMMISSION FOR THE STUDY OF BIOETHICAL ISSUES These include: issues of transparency; issues of consent; safety of neuroimaging techniques; use of large databases; security of personal databases (containing e.g. disease or genetic information); obsolescence of data in a rapidly developing field where technology and methodology are updated frequently; secondary findings of potential clinical significance and return of results.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC8242825/

[100] A Just Standard: The Ethical Management of Incidental Findings in Brain ... — Moreover, disclosing incidental findings of unknown or uncertain significance may impede the satisfaction of researchers’ institutional obligations, by precipitating the expenditure of significant health care resources for participant follow-up, with only a small chance of benefit. We have argued that researchers have an obligation to look for and disclose incidental findings arising from neuroimaging research only insofar as this is a requirement of the basic care to which participants are entitled as a matter of distributive justice. While attempts to justify disclosure on the basis of respect for participant autonomy or beneficence (arising either from the researcher as a moral agent, or in their role as a researcher) provide a reasonable justification for disclosing incidental findings in cases where there is clear clinical benefit, they inadequately address researcher’s responsibilities regarding findings of uncertain or unknown significance.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC6499712/

[102] Machine learning in neuroimaging: Progress and challenges — The application of machine learning methods to neuroimaging has risen more rapidly than could have been predicted 15 years ago. It has been a very exciting new direction in neuroimaging, as it has expanded the field from population-based analyses into individualized biomarkers of diseases or functional brain states. From a clinical perspective

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC9732070/

[103] Machine learning in neuroimaging: from research to clinical practice — Compared to structural imaging, functional neuroimaging can detect underlying neurophysiological and molecular properties, and combining both enables a multi-modal description of the brain and the modeling of its structure–function relationship as a marker for disease [17–19]. Machine learning models link the observed neuroimaging information such as the sequential BOLD signal observed for each image voxel of fMRI data to experiment conditions, aiming to identify brain regions whose functional signal is associated with the condition (Fig. 2). Supervised machine learning using functional connectivity data revealed disease correlates not visible in structural imaging, for instance, deep learning models for the identification of characteristics of autism spectrum disorders or a generative autoencoder model to classify autism . Machine learning offers a means to align individual brains based on their functional imaging data.

nih

https://pubmed.ncbi.nlm.nih.gov/35347570/

[104] How Machine Learning is Powering Neuroimaging to Improve Brain Health — This report presents an overview of how machine learning is rapidly advancing clinical translational imaging in ways that will aid in the early detection, prediction, and treatment of diseases that threaten brain health. ... How Machine Learning is Powering Neuroimaging to Improve Brain Health Neuroinformatics. 2022 Oct;20(4) :943

nih

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10255716/

[105] Deep Learning Aided Neuroimaging and Brain Regulation — As AI techniques continue to be refined and improved, deep learning has been proposed to dramatically change the health care monitoring and regulation of the brain , which can not only improve the reconstruction accuracy of neuroimaging and achieve fast imaging, but also mine a large amount of pathological and genetic data by processing and cross-referencing health and medical big data such as images, pathology, and genes, and help pathologists to evaluate pathological sections faster to improve the efficiency and prognosis of disease diagnosis . In recent years, several deep learning-based medical image analysis methods have been introduced to facilitate health monitoring and diagnosis using brain MRI scans .

conpas

http://conpas.org/neuroimaging-techniques-and-their-applications/

[112] Neuroimaging techniques and their applications - conpas — Neuroimaging techniques have revolutionized our understanding of the brain’s structure and function. Multi-modal imaging combines information from different neuroimaging techniques to provide a comprehensive understanding of the brain. While neuroimaging techniques have significantly improved in terms of resolution, there are still limitations in capturing fine details of brain structures and functions. Initiatives like the Human Connectome Project and the Alzheimer’s Disease Neuroimaging Initiative have already demonstrated the power of collaborative research in advancing our understanding of brain networks and disease processes. Neuroimaging techniques have transformed the field of neuroscience, providing unprecedented insights into the structure and function of the human brain. Despite challenges such as cost, resolution limitations, and ethical considerations, continuous advancements in technology and interdisciplinary collaborations are paving the way for a future where neuroimaging plays an even more significant role in understanding and improving brain health.

thekingsleyclinic

https://thekingsleyclinic.com/resources/top-neuroimaging-techniques-for-diagnosing-brain-disorders/

[113] Top Neuroimaging Techniques for Diagnosing Brain Disorders — Whether you’re curious about how neuroimaging identifies brain disorders or seeking information on the best imaging tests for memory loss, this guide provides clear, patient-centered insights. Using advanced technologies like Magnetic Resonance Imaging (MRI) and Computed Tomography (CT), neuroimaging offers vital information about the brain’s anatomy and function. By employing advanced techniques such as MRI, CT scans, and functional imaging, healthcare providers can visualize the brain’s structure and function. Neuroimaging, often referred to as brain imaging, is a non-invasive diagnostic procedure that provides detailed images of the brain’s structure and function. The specific steps involved depend on the type of imaging test, such as an MRI brain scan, CT scan, or functional neuroimaging.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC3869600/

[114] Selecting Neuroimaging Techniques: A Review for the Clinician — Positron emission tomography (PET) is a nuclear medicine diagnostic technique used to obtain functional brain scans, similar to fMRI and different from standard CT and MRI scans that provide structural information. PET has an important role in the localization of the focus for cases in which surgical treatment is considered.22,23 Other less common applications of nuclear medicine techniques in neuropsychiatry are the evaluation of brain tumors (which tend to be hypermetabolic) and head trauma (particularly in the chronic phase if affective, behavioral, and cognitive symptoms are present and structural imaging is unrevealing).24,25

cmrad

https://about.cmrad.com/articles/neurology-images-complete-guide-to-brain-imaging-techniques-analysis

[115] Neurology Images: Complete Guide to Brain Imaging Techniques & Analysis — Neurological imaging is a crucial component of modern medicine that allows healthcare professionals to visualize and understand the complex structures and functions of the brain and nervous system. Neurological images are medical visualizations of the brain and nervous system used for diagnosis, treatment planning, and research. Beyond basic structural imaging, advanced MRI techniques can now map blood flow, track neural activity, and even measure the direction of water movement within brain tissue, providing insights into neural connectivity. Also Read: Dr. Imran Lasker's Monthly Case Webinar #6: Neurological MRI to Trauma Bone Imaging CT Neurological imaging represents a cornerstone of modern neurology, providing crucial insights into brain structure and function.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S193986542400198X

[118] The connectomics revolution: Utilizing Resting State fMRI and DTI to ... — The connectomics revolution: Utilizing Resting State fMRI and DTI to personalize the treatment of neurological and psychocognitive disorders - ScienceDirect The connectomics revolution: Utilizing Resting State fMRI and DTI to personalize the treatment of neurological and psychocognitive disorders Resting state functional magnetic resonance imaging (rs-fMRI) and diffusion tensor imaging (DTI) are critical imaging modalities that provide insights into the brain's functional and structural connectivity without the need for active patient participation. This presentation is designed to showcase the pivotal role of rs-fMRI and DTI in the burgeoning field of personalized functional imaging. Employing rs-fMRI and DTI for connectomic analysis has yielded promising results in pinpointing neurological disease biomarkers, deciphering psychiatric disorder pathways, and crafting tailored therapeutic interventions. Journal of Cardiovascular Magnetic Resonance, Volume 19, Issue 1, 2016, Article 21

worldbrainmapping

https://www.worldbrainmapping.org/courses/lessons/historical-advancements-in-neuroimaging-techniques/

[119] Historical Advancements in Neuroimaging Techniques — Historical Advancements in Neuroimaging Techniques - Society for Brain Mapping and Therapeutics SOCIETY FOR BRAIN MAPPING AND THERAPEUTICS What is Brain Mapping Annual Brain Mapping Day at the US Congress SBMT Initiatives ME + Brain ME + Brain Impact: This discovery revolutionized understanding of how the brain operates in a baseline state and its alterations in disorders like Alzheimer’s, schizophrenia, and depression. MRI provides high-resolution images of brain structures, enabling early detection of tumors, multiple sclerosis, and stroke. Pre-surgical Planning: MRI and DTI help map brain structures and connectivity, minimizing risks during neurosurgery. The Society for Brain Mapping and Therapeutics (SBMT) was founded in 2004 to break boundaries in healthcare. What Is Brain Mapping Copyright © 2024 Society for Brain Mapping and Therapeutics (SBMT).

researchgate

https://www.researchgate.net/publication/370756904_MRI_vs_CT_Scan_A_Comparative_Study_in_Radiology_Diagnosis

[121] MRI vs. CT Scan: A Comparative Study in Radiology Diagnosis — When comparing MRI and CT scan, several factors should be considere d, including image quality, radiation exposure, diagnostic capabilities, patient characteristics, and cost. MR I generally

nih

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2807751/

[148] Neuroimaging in Psychiatry: From Bench to Bedside — We will focus on studies that tried to utilise neuroimaging to understand the pathophysiology of mental disorders by identifying cognitive tasks acting as a surrogate marker (e.g., working memory in schizophrenia, theory of mind in autism), those that compared different diagnostic or at-risk groups in order to obtain diagnostic or prognostic markers, and those that integrated neuroimaging in treatment protocols. The identification of these symptom-related regions and networks may inform treatment, for example targeted interference with transcranial magnetic stimulation (TMS), as shown for example with a NIRS-guided repetitive TMS treatment protocol in a patient with panic disorder targeted on a frontal brain region implicated in emotion processing (Dresler et al., 2009).

psychiatryonline

https://psychiatryonline.org/doi/10.1176/appi.ajp.2021.21060616

[149] Understanding the Value and Limitations of MRI Neuroimaging in Psychiatry — In psychiatry, MRI neuroimaging methods have become a critical tool for performing research with the intent of developing a better understanding of brain circuit alterations that are associated with etiology, pathophysiology, and treatment response. In this issue of the Journal, we present a series of papers that highlight the use of various neuroimaging techniques that are aimed at linking brain structure and function to 1) understanding pathophysiological processes associated with illnesses, 2) factors related to normative development and early-life risk, and 3) treatment response. By comparing fMRI data from 626 patients with a range of psychiatric diagnoses to 610 control subjects, the authors found altered interoception-related left dorsal mid-insula activation to be common across the patient groups (diagnoses included schizophrenia, bipolar disorder, depression, anxiety disorders, posttraumatic stress disorder, eating disorders, and substance use disorders).

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC6221760/

[152] The vast potential and bright future of neuroimaging - PMC — Quantitative neuroimaging is well-suited for statistical modeling and systematic image analysis approaches that utilize canonical templates or brain atlases to measure changes in specific regions of interest.7 Quantitative methods are beginning to evaluate the brain as an integrated structural and functional network.8 These new approaches might be critical not only for deciphering brain circuitry but also for understanding the dysfunction of brain network connectivity that occurs during the progression of many neurological and psychiatric disorders.

sagepub

https://journals.sagepub.com/doi/full/10.1177/0033294120926669

[154] Future Applications of Real-World Neuroimaging to Clinical Psychology ... — Therefore, the present article describes the concept of ecological validity, fNIRS as an emerging neuroimaging method, current challenges in clinical psychology and cognitive neuroscience to studying mechanisms of change, and future applications of real-world designs and methods that can address these issues in theory and practice.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC6221760/

[155] The vast potential and bright future of neuroimaging - PMC — Quantitative neuroimaging is well-suited for statistical modeling and systematic image analysis approaches that utilize canonical templates or brain atlases to measure changes in specific regions of interest.7 Quantitative methods are beginning to evaluate the brain as an integrated structural and functional network.8 These new approaches might be critical not only for deciphering brain circuitry but also for understanding the dysfunction of brain network connectivity that occurs during the progression of many neurological and psychiatric disorders.

nih

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2728702/

[156] Current and future uses of neuroimaging for cognitively impaired ... — Developments in diagnosis and treatment of age-related cognitive decline have led to better detection of and symptomatic treatment for Alzheimer’s disease (AD), and neuroimaging is often used to assist physicians in making an accurate diagnosis. The prospect of more effective treatments for AD and other dementias, and the potential for improving memory and other cognitive functions in people with mild, age-related decline, as well as delaying their progression, has led to new brain imaging technologies that might not only further improve diagnostic accuracy but also accelerate treatment discovery. In-vivo imaging of Alzheimer disease β-amyloid with [11C]SB-13 PET. PET imaging of cortical 11C-nicotine binding correlates with the cognitive function of attention in Alzheimer’s disease. Changes in brain 11C-nicotine binding sites in patients with mild Alzheimer’s disease following rivastigmine treatment as assessed by PET.

nih

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5703144/

[160] Professor Wieslaw Nowinski: 25 years of contribution to the development ... — The role of digital brain atlases is therefore absolutely crucial in modern neuroimaging research, and will continue to grow due to the huge increase in data. It can be safely assumed that without brain atlases, many major discoveries in clinical neuroscience over the last 20 years would not have been possible.

frontiersin

https://www.frontiersin.org/journals/neuroscience/articles/10.3389/fnins.2025.1497881/full

[161] A short investigation of the effect of the selection of human brain ... — These brain atlases are used to standardize and simplify the process of analyzing complex brain data using neuroimaging techniques, such as fMRI. Brain atlases can be categorized into two classes, "Anatomical" and "Functional" where the anatomical atlas is related to the physical structures of the brain and the functional atlas is

medium

https://medium.com/@neurotist/brain-wars-eeg-vs-fmri-the-battle-for-neuroimaging-supremacy-6de8bc4fec0e

[165] Brain Wars: EEG vs. fMRI — The Battle for Neuroimaging Supremacy — Another area where EEG and fMRI complement each other is in the investigation of brain disorders. Conditions like schizophrenia, autism, and depression involve disruptions in both the timing and

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC8174780/

[166] Multimodal EEG-fMRI: advancing insight into large-scale human brain ... — Keywords: functional neuroimaging, brain networks, state changes, hemodynamics, EEG-fMRI Scalp EEG provides a non-invasive view into brain electrical activity, and is complementary to fMRI: EEG captures fast electrical activity, with the ability to resolve temporal markers of natural or pathological state changes (e.g., sleep and seizure activity), but with coarser spatial resolution and different physiological origins compared to fMRI. Therefore, one major framework in fusing EEG-fMRI has involved the use of EEG – with its high temporal resolution - to track the occurrence or continuous modulation of electrical activity over time, and fMRI - with its superior spatial resolution - to investigate the corresponding whole-brain correlates, particularly in deep subcortical structures that regulate brain states but which are less accessible to scalp EEG.

springer

https://link.springer.com/referenceworkentry/10.1007/978-981-15-2848-4_81-1

[167] Multimodal Neuroimaging with Simultaneous fMRI and EEG — Functional magnetic resonance imaging (fMRI) and electroencephalography (EEG) are noninvasive techniques used to measure neural activity in the human brain. fMRI measures the magnetic resonance signal associated with hemodynamic changes driven by neural activity and has a good spatial resolution (2-3 mm isotropic) and low temporal resolution (1-3 s).

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC3811108/

[168] Simultaneous EEG and fMRI: towards the characterization of structure ... — Both electroencephalography (EEG) and functional magnetic resonance imaging (fMRI) are extremely efficient methods for the assessment of human brain function. The specific appeal of the combination is related to the fact that both methods are complementary in terms of basic aspects: EEG is a direct measurement of neural mass activity and

nih

https://pubmed.ncbi.nlm.nih.gov/34862536/

[179] Introduction to Machine Learning in Neuroimaging - PubMed — Advancements in neuroimaging and the availability of large-scale datasets enable the use of more sophisticated machine learning algorithms. In this chapter, we non-exhaustively discuss relevant analytical steps for the analysis of neuroimaging data using machine learning (ML), while the field of radiomics will be addressed separately (c.f., Chap. 18 -Radiomics).

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC9732070/

[180] Machine learning in neuroimaging: from research to clinical practice — Compared to structural imaging, functional neuroimaging can detect underlying neurophysiological and molecular properties, and combining both enables a multi-modal description of the brain and the modeling of its structure–function relationship as a marker for disease [17–19]. Machine learning models link the observed neuroimaging information such as the sequential BOLD signal observed for each image voxel of fMRI data to experiment conditions, aiming to identify brain regions whose functional signal is associated with the condition (Fig. 2). Supervised machine learning using functional connectivity data revealed disease correlates not visible in structural imaging, for instance, deep learning models for the identification of characteristics of autism spectrum disorders or a generative autoencoder model to classify autism . Machine learning offers a means to align individual brains based on their functional imaging data.

springer

https://link.springer.com/chapter/10.1007/978-3-031-77620-5_11

[181] Deep-Learning Based Multi-Modalities Fusion for the ... - Springer — The machine learning applications in brain haemorrhage research are particularly difficult since it requires the acquisition of patient data from computed tomography (CT) scan pictures . Every year, roughly seven million people worldwide encounter brain injuries as a result of car accidents, falls, attacks, brain disorders, or blood vessel

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC6499712/

[182] Machine learning in neuroimaging: Progress and challenges — For example, in clinical neuroimaging, machine learning studies revealed imaging signatures for a number of diseases and disorders, such as Alzheimer's Disease ((Kloppel et al., 2008; Zhang et al., 2011); see (Rathore et al., 2017) for a recent review), brain development and aging (Franke et al., 2010; Habes et al., 2016; Xia et al., 2018), preclinical states (Davatzikos et al., 2009), schizophrenia (Davatzikos et al., 2005a) and its prodromal stages (Koutsouleris et al., 2009), mood disorders (Koutsouleris et al., 2015), and autism (Ecker et al., 2010), amongst others. The literature certainly uses such models (Brodersen et al., 2011), and adaptations of GAN deep networks might hold promise, however the development of machine learning methods that seek primarily to provide insights into the biology of disease processes or brain function, in addition to making the right decision, is still in its infancy.

cambridge

https://www.cambridge.org/core/journals/bjpsych-advances/article/everything-you-wanted-to-know-about-neuroimaging-and-psychiatry-but-were-afraid-to-ask/F4E6EF4CBDB015999576E401CC5DF7F7

[190] Everything you wanted to know about neuroimaging and psychiatry, but ... — Some techniques, such as computed tomography (CT), electroencephalography (EEG) and structural magnetic resonance imaging (sMRI), are well established in clinical practice, whereas more contemporary techniques, such as functional MRI (fMRI) and diffusion tensor imaging (DTI), have yet to show their full translational potential. For example, research has enabled us to link the increased risk of developing Alzheimer’s disease associated with e4 allele of the apolipoprotein E (APOE) gene to reductions in grey matter volume (Reference Shaw, Lerch and PruessnerShaw 2007) and functional connectivity (Reference Filippini, MacIntosh and HoughFilippini 2009) in young people, suggesting that brain imaging on people with this mutation might help early detection of brain abnormalities.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC3052989/

[194] Neuroimaging in Psychiatric Disorders - PMC — An example of the use of neuroimaging in preclinical models is the demonstration that a new PET compound, [11C]GSK931145, binds the glycine transporter 1, an important modulator of NMDA receptors, which are considered to be hypoactive in schizophrenia . For instance, by imaging striatal dopamine (DA) D2 receptors using [11C]raclopride PET, a link was found between D2 receptor occupancy by medication and a reduction in positive symptoms in schizophrenia: ascending doses of up to 80% receptor occupancy were progressively more effective in relieving delusions and hallucinations . As mentioned, the original PET studies with neuroleptics showed that DA D2 antagonists have antipsychotic efficacy with minimal extrapyramidal syndrome side effects within a 'therapeutic window' of 65–80% striatal D2 receptor occupancy. Dose-occupancy study of striatal and extrastriatal dopamine D(2) receptors by aripiprazole in schizophrenia with PET and [(18)F]Fallypride.

nih

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2807751/

[195] Neuroimaging in Psychiatry: From Bench to Bedside — We will focus on studies that tried to utilise neuroimaging to understand the pathophysiology of mental disorders by identifying cognitive tasks acting as a surrogate marker (e.g., working memory in schizophrenia, theory of mind in autism), those that compared different diagnostic or at-risk groups in order to obtain diagnostic or prognostic markers, and those that integrated neuroimaging in treatment protocols. The identification of these symptom-related regions and networks may inform treatment, for example targeted interference with transcranial magnetic stimulation (TMS), as shown for example with a NIRS-guided repetitive TMS treatment protocol in a patient with panic disorder targeted on a frontal brain region implicated in emotion processing (Dresler et al., 2009).

psychiatryonline

https://psychiatryonline.org/doi/10.1176/appi.ajp.2021.21060616

[197] Understanding the Value and Limitations of MRI Neuroimaging in ... — In psychiatry, MRI neuroimaging methods have become a critical tool for performing research with the intent of developing a better understanding of brain circuit alterations that are associated with etiology, pathophysiology, and treatment response. In this issue of the Journal, we present a series of papers that highlight the use of various neuroimaging techniques that are aimed at linking brain structure and function to 1) understanding pathophysiological processes associated with illnesses, 2) factors related to normative development and early-life risk, and 3) treatment response. By comparing fMRI data from 626 patients with a range of psychiatric diagnoses to 610 control subjects, the authors found altered interoception-related left dorsal mid-insula activation to be common across the patient groups (diagnoses included schizophrenia, bipolar disorder, depression, anxiety disorders, posttraumatic stress disorder, eating disorders, and substance use disorders).

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC6499712/

[228] Machine learning in neuroimaging: Progress and challenges — For example, in clinical neuroimaging, machine learning studies revealed imaging signatures for a number of diseases and disorders, such as Alzheimer's Disease ((Kloppel et al., 2008; Zhang et al., 2011); see (Rathore et al., 2017) for a recent review), brain development and aging (Franke et al., 2010; Habes et al., 2016; Xia et al., 2018), preclinical states (Davatzikos et al., 2009), schizophrenia (Davatzikos et al., 2005a) and its prodromal stages (Koutsouleris et al., 2009), mood disorders (Koutsouleris et al., 2015), and autism (Ecker et al., 2010), amongst others. The literature certainly uses such models (Brodersen et al., 2011), and adaptations of GAN deep networks might hold promise, however the development of machine learning methods that seek primarily to provide insights into the biology of disease processes or brain function, in addition to making the right decision, is still in its infancy.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC9732070/

[230] Machine learning in neuroimaging: from research to clinical practice — Compared to structural imaging, functional neuroimaging can detect underlying neurophysiological and molecular properties, and combining both enables a multi-modal description of the brain and the modeling of its structure–function relationship as a marker for disease [17–19]. Machine learning models link the observed neuroimaging information such as the sequential BOLD signal observed for each image voxel of fMRI data to experiment conditions, aiming to identify brain regions whose functional signal is associated with the condition (Fig. 2). Supervised machine learning using functional connectivity data revealed disease correlates not visible in structural imaging, for instance, deep learning models for the identification of characteristics of autism spectrum disorders or a generative autoencoder model to classify autism . Machine learning offers a means to align individual brains based on their functional imaging data.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC9732070/

[232] Machine learning in neuroimaging: from research to clinical practice — Compared to structural imaging, functional neuroimaging can detect underlying neurophysiological and molecular properties, and combining both enables a multi-modal description of the brain and the modeling of its structure–function relationship as a marker for disease [17–19]. Machine learning models link the observed neuroimaging information such as the sequential BOLD signal observed for each image voxel of fMRI data to experiment conditions, aiming to identify brain regions whose functional signal is associated with the condition (Fig. 2). Supervised machine learning using functional connectivity data revealed disease correlates not visible in structural imaging, for instance, deep learning models for the identification of characteristics of autism spectrum disorders or a generative autoencoder model to classify autism . Machine learning offers a means to align individual brains based on their functional imaging data.

medicai

https://blog.medicai.io/en/a-window-into-the-brain-how-neuroimaging-is-changing-the-diagnosis-and-treatment-of-neurological-disorders/

[233] How Neuroimaging changes diagnosis of neurological disorders - Medicai — The future of neuroimaging is bright, with new technologies and techniques emerging that promise to provide even more detailed and accurate images of the brain and nervous system. These advances are likely to have a significant impact on the diagnosis and treatment of a wide range of neurological conditions. Artificial Intelligence (AI)

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC6499712/

[236] Machine learning in neuroimaging: Progress and challenges — For example, in clinical neuroimaging, machine learning studies revealed imaging signatures for a number of diseases and disorders, such as Alzheimer's Disease ((Kloppel et al., 2008; Zhang et al., 2011); see (Rathore et al., 2017) for a recent review), brain development and aging (Franke et al., 2010; Habes et al., 2016; Xia et al., 2018), preclinical states (Davatzikos et al., 2009), schizophrenia (Davatzikos et al., 2005a) and its prodromal stages (Koutsouleris et al., 2009), mood disorders (Koutsouleris et al., 2015), and autism (Ecker et al., 2010), amongst others. The literature certainly uses such models (Brodersen et al., 2011), and adaptations of GAN deep networks might hold promise, however the development of machine learning methods that seek primarily to provide insights into the biology of disease processes or brain function, in addition to making the right decision, is still in its infancy.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC9732070/

[237] Machine learning in neuroimaging: from research to clinical practice — Compared to structural imaging, functional neuroimaging can detect underlying neurophysiological and molecular properties, and combining both enables a multi-modal description of the brain and the modeling of its structure–function relationship as a marker for disease [17–19]. Machine learning models link the observed neuroimaging information such as the sequential BOLD signal observed for each image voxel of fMRI data to experiment conditions, aiming to identify brain regions whose functional signal is associated with the condition (Fig. 2). Supervised machine learning using functional connectivity data revealed disease correlates not visible in structural imaging, for instance, deep learning models for the identification of characteristics of autism spectrum disorders or a generative autoencoder model to classify autism . Machine learning offers a means to align individual brains based on their functional imaging data.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2772529424001759

[238] Artificial intelligence in neuroimaging: Opportunities and ethical ... — Artificial intelligence in neuroimaging: Opportunities and ethical challenges - ScienceDirect Artificial intelligence in neuroimaging: Opportunities and ethical challenges open access The integration of artificial intelligence (AI) into neuroimaging represents a transformative shift in the diagnosis and treatment of neurodegenerative diseases. This letter discusses the opportunities AI presents in neuroimaging, including improved disease detection, predictive modeling, and treatment planning. Issues such as algorithmic bias, data privacy, and the interpretability of AI-driven insights must be addressed to ensure that these technologies are used responsibly and equitably. As neuroimaging continues to evolve, a collaborative approach involving researchers, clinicians, and ethicists is essential to navigate these challenges and maximize the benefits of AI in improving patient outcomes in neurodegenerative diseases. Next article in issue No articles found. For all open access content, the relevant licensing terms apply.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC8423931/

[239] Neuroimaging Advances in Neurologic and Neurodegenerative Diseases — Neuroimaging Advances in Neurologic and Neurodegenerative Diseases - PMC Neuroimaging tools, including magnetic resonance imaging (MRI), positron emission tomography (PET), and others (computerized tomography (CT), single-photon emission computerized tomography (SPECT), etc.) can be important biomarkers for identification, tracking, diagnosis, and treatment monitoring of neurologic diseases. Widely used in neurodegenerative disorders like Alzheimer’s disease (AD), frontotemporal lobar degeneration (FTLD), and Parkinson’s disease (PD) and associated disorders, neuroimaging methods are also applied to many other neurologic diseases to uncover important information about underlying biology, diagnostic classification, and treatment response. Finally, Brooks (2020) provides a comprehensive review of neuroimaging in PD and related disorders (such as LBD), focusing on MRI, SPECT (i.e., DATScan), and PET findings (primarily dopamine-focused and other neurotransmitter-focused tracers) .

advancesinclinicalradiology

https://www.advancesinclinicalradiology.com/article/S2589-8701(24

[241] Hybrid PET/MRI in Neurodegenerative Disorders - Advances in Clinical ... — Imaging will play a major role in this transition, particularly specific radiotracers designed to target underlying proteinopathies, such as tau and amyloid. In parallel, PET/MRI is emerging as a hybrid modality with the advantage of combining specific molecular targeting with high spatial resolution in the evaluation of neurodegenerative