Niall Holmes
Overview
Explore the profile of Niall Holmes including associated specialties, affiliations and a list of published articles.
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Articles
48
Citations
1122
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Recent Articles
1.
Schofield H, Hill R, Feys O, Holmes N, Osborne J, Doyle C, et al.
Imaging Neurosci (Camb)
. 2024 Nov;
2:1-22.
PMID: 39502465
Magnetoencephalography (MEG) measures brain function via assessment of magnetic fields generated by neural currents. Conventional MEG uses superconducting sensors, which place significant limitations on performance, practicality, and deployment; however, the...
2.
Rier L, Rhodes N, Pakenham D, Boto E, Holmes N, Hill R, et al.
Elife
. 2024 Oct;
13.
PMID: 39360938
No abstract available.
3.
Holmes N, Leggett J, Hill R, Rier L, Boto E, Schofield H, et al.
IEEE Trans Biomed Eng
. 2024 Sep;
72(2):609-618.
PMID: 39302788
Wearable magnetoencephalography based on optically pumped magnetometers (OPM-MEG) offers non-invasive and high-fidelity measurement of human brain electrophysiology. The flexibility of OPM-MEG also means it can be deployed in participants of...
4.
Bardouille T, Smith V, Vajda E, Leslie C, Holmes N
Sensors (Basel)
. 2024 Jun;
24(11).
PMID: 38894294
Magnetoencephalography (MEG) non-invasively provides important information about human brain electrophysiology. The growing use of optically pumped magnetometers (OPM) for MEG, as opposed to fixed arrays of cryogenic sensors, has opened...
5.
Rier L, Rhodes N, Pakenham D, Boto E, Holmes N, Hill R, et al.
Elife
. 2024 Jun;
13.
PMID: 38831699
Neural oscillations mediate the coordination of activity within and between brain networks, supporting cognition and behaviour. How these processes develop throughout childhood is not only an important neuroscientific question but...
6.
Schofield H, Hill R, Feys O, Holmes N, Osborne J, Doyle C, et al.
bioRxiv
. 2024 Apr;
PMID: 38558964
Magnetoencephalography (MEG) measures brain function via assessment of magnetic fields generated by neural currents. Conventional MEG uses superconducting sensors, which place significant limitations on performance, practicality, and deployment; however, the...
7.
Schofield H, Boto E, Shah V, Hill R, Osborne J, Rea M, et al.
Contemp Phys
. 2024 Mar;
63(3):161-179.
PMID: 38463461
Non-invasive imaging has transformed neuroscientific discovery and clinical practice, providing a non-invasive window into the human brain. However, whilst techniques like MRI generate ever more precise images of brain structure,...
8.
Rier L, Rhodes N, Pakenham D, Boto E, Holmes N, Hill R, et al.
bioRxiv
. 2024 Jan;
PMID: 38260246
Neural oscillations mediate the coordination of activity within and between brain networks, supporting cognition and behaviour. How these processes develop throughout childhood is not only an important neuroscientific question but...
9.
Feys O, Corvilain P, Labyt E, Mahmoudzadeh M, Routier L, Sculier C, et al.
Front Neurosci
. 2023 Dec;
17:1284262.
PMID: 38089970
Cryogenic magnetoencephalography (MEG) enhances the presurgical assessment of refractory focal epilepsy (RFE). Optically pumped magnetometers (OPMs) are cryogen-free sensors that enable on-scalp MEG recordings. Here, we investigate the application of...
10.
Feys O, Ferez M, Corvilain P, Schuind S, Rikir E, Legros B, et al.
Ann Neurol
. 2023 Dec;
95(3):620-622.
PMID: 38050959
No abstract available.