Your search keyword '"Niederer S"' showing total 5 results

1. A rule-based method for predicting the electrical activation of the heart with cardiac resynchronization therapy from non-invasive clinical data

Author

Lee, A.W.C., Nguyen, U.C., Razeghi, O., Gould, J., Sidhu, B.S., Sieniewicz, B., Behar, J., Mafi-Rad, M., Plank, G., Prinzen, F.W., Rinaldi, C.A., Vernooy, K., and Niederer, S.

Published

2019

2. Quantifying atrial anatomy uncertainty from clinical data and its impact on electro-physiology simulation predictions.

Author

Corrado C, Razeghi O, Roney C, Coveney S, Williams S, Sim I, O'Neill M, Wilkinson R, Oakley J, Clayton RH, and Niederer S

Subjects

Artifacts, Bayes Theorem, Electrophysiologic Techniques, Cardiac, Heart Atria diagnostic imaging, Humans, Principal Component Analysis, Uncertainty, Heart Atria anatomy & histology, Magnetic Resonance Imaging, Models, Cardiovascular

Abstract

Patient-specific computational models of structure and function are increasingly being used to diagnose disease and predict how a patient will respond to therapy. Models of anatomy are often derived after segmentation of clinical images or from mapping systems which are affected by image artefacts, resolution and contrast. Quantifying the impact of uncertain anatomy on model predictions is important, as models are increasingly used in clinical practice where decisions need to be made regardless of image quality. We use a Bayesian probabilistic approach to estimate the anatomy and to quantify the uncertainty about the shape of the left atrium derived from Cardiac Magnetic Resonance images. We show that we can quantify uncertain shape, encode uncertainty about the left atrial shape due to imaging artefacts, and quantify the effect of uncertain shape on simulations of left atrial activation times., Competing Interests: Declaration of Competing Interest We wish to confirm that there are no known conflicts of interest associated with this publication and there has been no significant financial support for this work that could have influenced its outcome., (Copyright © 2019. Published by Elsevier B.V.)

Published

2020

3. A work flow to build and validate patient specific left atrium electrophysiology models from catheter measurements.

Author

Corrado C, Williams S, Karim R, Plank G, O'Neill M, and Niederer S

Subjects

Algorithms, Cardiac Pacing, Artificial, Electrocardiography, Heart Conduction System physiopathology, Humans, Models, Cardiovascular, Atrial Fibrillation physiopathology, Cardiac Catheterization, Epicardial Mapping methods, Heart Atria physiopathology, Heart Conduction System physiology, Workflow

Abstract

Biophysical models of the atrium provide a physically constrained framework for describing the current state of an atrium and allow predictions of how that atrium will respond to therapy. We propose a work flow to simulate patient specific electrophysiological heterogeneity from clinical data and validate the resulting biophysical models. In 7 patients, we recorded the atrial anatomy with an electroanatomical mapping system (St Jude Velocity); we then applied an S1-S2 electrical stimulation protocol from the coronary sinus (CS) and the high right atrium (HRA) whilst recording the activation patterns using a PentaRay catheter with 10 bipolar electrodes at 12 ± 2 sites across the atrium. Using only the activation times measured with a PentaRay catheter and caused by a stimulus applied in the CS with a remote catheter we fitted the four parameters for a modified Mitchell-Schaeffer model and the tissue conductivity to the recorded local conduction velocity restitution curve and estimated local effective refractory period. Model parameters were then interpolated across each atrium. The fitted model recapitulated the S1-S2 activation times for CS pacing giving a correlation ranging between 0.81 and 0.98. The model was validated by comparing simulated activations times with the independently recorded HRA pacing S1-S2 activation times, giving a correlation ranging between 0.65 and 0.96. The resulting work flow provides the first validated cohort of models that capture clinically measured patient specific electrophysiological heterogeneity., (Copyright © 2018 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2018

4. The estimation of patient-specific cardiac diastolic functions from clinical measurements.

Author

Xi J, Lamata P, Niederer S, Land S, Shi W, Zhuang X, Ourselin S, Duckett SG, Shetty AK, Rinaldi CA, Rueckert D, Razavi R, and Smith NP

Subjects

Adult, Aged, Algorithms, Elastic Modulus, Humans, Male, Reproducibility of Results, Sensitivity and Specificity, Stroke Volume, Heart Ventricles pathology, Heart Ventricles physiopathology, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Magnetic Resonance Imaging, Cine methods, Ventricular Dysfunction, Left diagnosis, Ventricular Dysfunction, Left physiopathology

Abstract

An unresolved issue in patients with diastolic dysfunction is that the estimation of myocardial stiffness cannot be decoupled from diastolic residual active tension (AT) because of the impaired ventricular relaxation during diastole. To address this problem, this paper presents a method for estimating diastolic mechanical parameters of the left ventricle (LV) from cine and tagged MRI measurements and LV cavity pressure recordings, separating the passive myocardial constitutive properties and diastolic residual AT. Dynamic C1-continuous meshes are automatically built from the anatomy and deformation captured from dynamic MRI sequences. Diastolic deformation is simulated using a mechanical model that combines passive and active material properties. The problem of non-uniqueness of constitutive parameter estimation using the well known Guccione law is characterized by reformulation of this law. Using this reformulated form, and by constraining the constitutive parameters to be constant across time points during diastole, we separate the effects of passive constitutive properties and the residual AT during diastolic relaxation. Finally, the method is applied to two clinical cases and one control, demonstrating that increased residual AT during diastole provides a potential novel index for delineating healthy and pathological cases., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2013

5. An accurate, fast and robust method to generate patient-specific cubic Hermite meshes.

Author

Lamata P, Niederer S, Nordsletten D, Barber DC, Roy I, Hose DR, and Smith N

Subjects

Biomechanical Phenomena, Finite Element Analysis, Humans, Imaging, Three-Dimensional, Computational Biology methods, Computer Simulation, Heart physiology, Image Processing, Computer-Assisted

Abstract

In-silico continuum simulations of organ and tissue scale physiology often require a discretisation or mesh of the solution domain. Cubic Hermite meshes provide a smooth representation of anatomy that is well-suited for simulating large deformation mechanics. Models of organ mechanics and deformation have demonstrated significant potential for clinical application. However, the production of a personalised mesh from patient's anatomy using medical images remains a major bottleneck in simulation workflows. To address this issue, we have developed an accurate, fast and automatic method for deriving patient-specific cubic Hermite meshes. The proposed solution customises a predefined template with a fast binary image registration step and a novel cubic Hermite mesh warping constructed using a variational technique. Image registration is used to retrieve the mapping field between the template mesh and the patient images. The variational warping technique then finds a smooth and accurate projection of this field into the basis functions of the mesh. Applying this methodology, cubic Hermite meshes are fitted to the binary description of shape with sub-voxel accuracy and within a few minutes, which is a significant advance over the existing state of the art methods. To demonstrate its clinical utility, a generic cubic Hermite heart biventricular model is personalised to the anatomy of four patients, and the resulting mechanical stability of these customised meshes is successfully demonstrated., (Copyright © 2011 Elsevier B.V. All rights reserved.)

Published

2011