Your search keyword '"Ilya A. Verzhbinsky"' showing total 6 results

1. Thalamic spindles and Up states coordinate cortical and hippocampal co-ripples in humans

Author

Charles W. Dickey, Ilya A. Verzhbinsky, Sophie Kajfez, Burke Q. Rosen, Christopher E. Gonzalez, Patrick Y. Chauvel, Sydney S. Cash, Sandipan Pati, and Eric Halgren

Subjects

Biology (General), QH301-705.5

Published

2024

2. Human co-ripples facilitate neuronal interactions between cortical locations

Author

Ilya A. Verzhbinsky, Daniel B. Rubin, Sophie Kajfez, Yiting Bu, Leigh R. Hochberg, Sydney S. Cash, and Eric Halgren

Subjects

Article

Abstract

Synchronous bursts of high frequency oscillations (‘ripples’) are hypothesized to contribute to binding by facilitating integration of neuronal firing across cortical locations. We tested this hypothesis using local field-potentials and single-unit firing from four 96-channel microelectrode arrays in supragranular cortex of 3 patients. Neurons in co-rippling locations showed increased short-latency co-firing, prediction of each-other’s firing, and co-participation in neural assemblies. Effects were similar for putative pyramidal and interneurons, during NREM sleep and waking, in temporal and Rolandic cortices, and at distances up to 16mm. Increased co-prediction during co-ripples was maintained when firing-rate changes were equated, and were strongly modulated by ripple phase. Co-ripple enhanced prediction is reciprocal, synergistic with local upstates, and enhanced when multiple sites co-ripple. Together, these results support the hypothesis that transcortical co-ripples increase the integration of neuronal firing of neurons in different cortical locations, and do so in part through phase-modulation.

Published

2023

3. Myofiber strain in healthy humans using DENSE and cDTI

Author

Luigi E. Perotti, Ilya A. Verzhbinsky, Daniel B. Ennis, Kevin Moulin, Magalie Viallon, Pierre Croisille, Stanford University, Centre de Recherche en Acquisition et Traitement de l'Image pour la Santé (CREATIS), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Hospices Civils de Lyon (HCL)-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Centre Hospitalier Universitaire de Saint-Etienne (CHU de Saint-Etienne), University of California [San Diego] (UC San Diego), University of California (UC), University of Central Florida [Orlando] (UCF), and GAUTHERON, Arthur

Subjects

[SDV.IB.IMA]Life Sciences [q-bio]/Bioengineering/Imaging, Population, Magnetic Resonance Imaging, Cine, Article, 030218 nuclear medicine & medical imaging, Contractility, 03 medical and health sciences, 0302 clinical medicine, In vivo, myofiber strain, Circumferential strain, Myocyte, Humans, Radiology, Nuclear Medicine and imaging, Myocytes, Cardiac, DENSE, education, Physics, education.field_of_study, Strain (chemistry), Phantoms, Imaging, Healthy Volunteers, [SDV.IB.IMA] Life Sciences [q-bio]/Bioengineering/Imaging, Potential biomarkers, Acquisition time, 030217 neurology & neurosurgery, Biomedical engineering, cDTI

Abstract

Purpose: Myofiber strain, Eff , is a mechanistically relevant metric of cardiac cell shortening and is expected to be spatially uniform in healthy populations, making it a prime candidate for the evaluation of local cardiomyocyte contractility. In this study, a new, efficient pipeline was proposed to combine microstructural cDTI and functional DENSE data in order to estimate Eff in vivo.Methods: Thirty healthy volunteers were scanned with three long-axis (LA) and three short-axis (SA) DENSE slices using 2D displacement encoding and one SA slice of cDTI. The total acquisition time was 11 minutes ± 3 minutes across volunteers. The pipeline first generates 3D SA displacements from all DENSE slices which are then combined with cDTI data to generate a cine of myofiber orientations and compute Eff . The precision of the post-processing pipeline was assessed using a computational phantom study. Transmural myofiber strain was compared to circumferential strain, Ecc , in healthy volunteers using a Wilcoxon sign rank test.Results: In vivo, computed Eff was found uniform transmurally compared to Ecc (-0.14[-0.15, -0.12] vs -0.18 [-0.20, -0.16], P < .001, -0.14 [-0.16, -0.12] vs -0.16 [-0.17, -0.13], P < .001 and -0.14 [-0.16, -0.12] vs Ecc_C = -0.14 [-0.15, -0.11], P = .002, Eff_C vs Ecc_C in the endo, mid, and epi layers, respectively).Conclusion: We demonstrate that it is possible to measure in vivo myofiber strain in a healthy human population in 10 minutes per subject. Myofiber strain was observed to be spatially uniform in healthy volunteers making it a potential biomarker for the evaluation of local cardiomyocyte contractility in assessing cardiovascular dysfunction.

Published

2021

4. Probing cardiomyocyte mobility with multi-phase cardiac diffusion tensor MRI

Author

Nyasha G Maforo, Daniel B. Ennis, Kevin Moulin, Luigi E. Perotti, and Ilya A. Verzhbinsky

Subjects

Male, Ventricular Function, Left, Diagnostic Radiology, Nuclear magnetic resonance, Animal Cells, Diastole, Materials Physics, Cell Movement, Medicine and Health Sciences, Myocytes, Cardiac, Microstructure, Cardiomyocytes, Physics, Brain Mapping, Multidisciplinary, Cardiac cycle, medicine.diagnostic_test, Radiology and Imaging, Heart, Magnetic Resonance Imaging, Healthy Volunteers, Diffusion Tensor Imaging, medicine.anatomical_structure, Physical Sciences, Diastasis, Medicine, Female, Cellular Types, Anatomy, Research Article, Adult, Cardiac function curve, Systole, Imaging Techniques, Brain Morphometry, Science, Materials Science, Cardiology, Muscle Tissue, Magnetic Resonance Imaging, Cine, Neuroimaging, Research and Analysis Methods, Diagnostic Medicine, Fractional anisotropy, medicine, Humans, Muscle Cells, Biology and Life Sciences, Magnetic resonance imaging, Cell Biology, medicine.disease, Biological Tissue, Algebra, Diffusion Magnetic Resonance Imaging, Linear Algebra, Ventricle, Cardiovascular Anatomy, Eigenvectors, Mathematics, Neuroscience, Diffusion MRI

Abstract

Purpose Cardiomyocyte organization and performance underlie cardiac function, but the in vivo mobility of these cells during contraction and filling remains difficult to probe. Herein, a novel trigger delay (TD) scout sequence was used to acquire high in-plane resolution (1.6 mm) Spin-Echo (SE) cardiac diffusion tensor imaging (cDTI) at three distinct cardiac phases. The objective was to characterize cardiomyocyte organization and mobility throughout the cardiac cycle in healthy volunteers. Materials and methods Nine healthy volunteers were imaged with cDTI at three distinct cardiac phases (early systole, late systole, and diastasis). The sequence used a free-breathing Spin-Echo (SE) cDTI protocol (b-values = 350s/mm2, twelve diffusion encoding directions, eight repetitions) to acquire high-resolution images (1.6x1.6x8mm3) at 3T in ~7 minutes/cardiac phase. Helix Angle (HA), Helix Angle Range (HAR), E2 angle (E2A), Transverse Angle (TA), Mean Diffusivity (MD), diffusion tensor eigenvalues (λ1-2-3), and Fractional Anisotropy (FA) in the left ventricle (LV) were characterized. Results Images from the patient-specific TD scout sequence demonstrated that SE cDTI acquisition was possible at early systole, late systole, and diastasis in 78%, 100% and 67% of the cases, respectively. At the mid-ventricular level, mobility (reported as median [IQR]) was observed in HAR between early systole and late systole (76.9 [72.6, 80.5]° vs 96.6 [85.9, 100.3]°, p Conclusion We demonstrate that it is possible to probe cardiomyocyte mobility using multi-phase and high resolution cDTI. In healthy volunteers, aggregate cardiomyocytes re-orient themselves more longitudinally during contraction, while cardiomyocyte sheetlets tilt radially during wall thickening. These observations provide new insights into the three-dimensional mobility of myocardial microstructure during systolic contraction.

Published

2020

5. Estimating Aggregate Cardiomyocyte Strain Using In Vivo Diffusion and Displacement Encoded MRI

Author

Kevin Moulin, Luigi E. Perotti, Michael Loecher, Ilya A. Verzhbinsky, Daniel B. Ennis, and Tyler E. Cork

Subjects

Physics, Radiological and Ultrasound Technology, Strain (chemistry), Phantoms, Imaging, Swine, Image (category theory), Heart Ventricles, Magnetic Resonance Imaging, Cine, Heart, Imaging phantom, Displacement (vector), Article, Computer Science Applications, Orientation (vector space), Nuclear magnetic resonance, Cardiovascular Diseases, Image Interpretation, Computer-Assisted, Image Processing, Computer-Assisted, Animals, Myocytes, Cardiac, Electrical and Electronic Engineering, Diffusion (business), Radial stress, Software, Diffusion MRI

Abstract

Changes in left ventricular (LV) aggregate cardiomyocyte orientation and deformation underlie cardiac function and dysfunction. As such, in vivo aggregate cardiomyocyte “myofiber” strain ( ${E}_{\text {ff}}$ ) has mechanistic significance, but currently there exists no established technique to measure in vivo ${E}_{\text {ff}}$ . The objective of this work is to describe and validate a pipeline to compute in vivo ${E}_{\text {ff}}$ from magnetic resonance imaging (MRI) data. Our pipeline integrates LV motion from multi-slice Displacement ENcoding with Stimulated Echoes (DENSE) MRI with in vivo LV microstructure from cardiac Diffusion Tensor Imaging (cDTI) data. The proposed pipeline is validated using an analytical deforming heart-like phantom. The phantom is used to evaluate 3D cardiac strains computed from a widely available, open-source DENSE Image Analysis Tool. Phantom evaluation showed that a DENSE MRI signal-to-noise ratio (SNR) ≥20 is required to compute ${E}_{\text {ff}}$ with near-zero median strain bias and within a strain tolerance of 0.06. Circumferential and longitudinal strains are also accurately measured under the same SNR requirements, however, radial strain exhibits a median epicardial bias of −0.10 even in noise-free DENSE data. The validated framework is applied to experimental DENSE MRI and cDTI data acquired in eight ( ${N}={8}$ ) healthy swine. The experimental study demonstrated that ${E}_{\text {ff}}$ has decreased transmural variability compared to radial and circumferential strains. The spatial uniformity and mechanistic significance of in vivo ${E}_{\text {ff}}$ make it a compelling candidate for characterization and early detection of cardiac dysfunction.

Published

2019

6. Probing cardiomyocyte mobility with multi-phase cardiac diffusion tensor MRI.

Author

Kévin Moulin, Ilya A Verzhbinsky, Nyasha G Maforo, Luigi E Perotti, and Daniel B Ennis

Subjects

Medicine, Science

Abstract

PurposeCardiomyocyte organization and performance underlie cardiac function, but the in vivo mobility of these cells during contraction and filling remains difficult to probe. Herein, a novel trigger delay (TD) scout sequence was used to acquire high in-plane resolution (1.6 mm) Spin-Echo (SE) cardiac diffusion tensor imaging (cDTI) at three distinct cardiac phases. The objective was to characterize cardiomyocyte organization and mobility throughout the cardiac cycle in healthy volunteers.Materials and methodsNine healthy volunteers were imaged with cDTI at three distinct cardiac phases (early systole, late systole, and diastasis). The sequence used a free-breathing Spin-Echo (SE) cDTI protocol (b-values = 350s/mm2, twelve diffusion encoding directions, eight repetitions) to acquire high-resolution images (1.6x1.6x8mm3) at 3T in ~7 minutes/cardiac phase. Helix Angle (HA), Helix Angle Range (HAR), E2 angle (E2A), Transverse Angle (TA), Mean Diffusivity (MD), diffusion tensor eigenvalues (λ1-2-3), and Fractional Anisotropy (FA) in the left ventricle (LV) were characterized.ResultsImages from the patient-specific TD scout sequence demonstrated that SE cDTI acquisition was possible at early systole, late systole, and diastasis in 78%, 100% and 67% of the cases, respectively. At the mid-ventricular level, mobility (reported as median [IQR]) was observed in HAR between early systole and late systole (76.9 [72.6, 80.5]° vs 96.6 [85.9, 100.3]°, pConclusionWe demonstrate that it is possible to probe cardiomyocyte mobility using multi-phase and high resolution cDTI. In healthy volunteers, aggregate cardiomyocytes re-orient themselves more longitudinally during contraction, while cardiomyocyte sheetlets tilt radially during wall thickening. These observations provide new insights into the three-dimensional mobility of myocardial microstructure during systolic contraction.

Published

2020