Wilson W Good1, Burak Erem2, Brian Zenger3, Jaume Coll-Font4, Dana H Brooks5, Rob S MacLeod3. 1. Scientific Computing and Imaging Institute, Biomedical Engineering, University of Utah, Salt Lake City, UT, USA. Electronic address: wgood@sci.utah.edu. 2. TrueMotion, Boston, MA, USA; Computational Radiology Lab., Boston Children's Hospital, Boston, MA, USA. 3. Scientific Computing and Imaging Institute, Biomedical Engineering, University of Utah, Salt Lake City, UT, USA. 4. Computational Radiology Lab., Boston Children's Hospital, Boston, MA, USA. 5. SPIRAL Group, ECE Dept., Northeastern University, Boston, MA, USA.
Abstract
BACKGROUND: Myocardial ischemia has a complex and time-varying electrocardiographic signature that is used to diagnose and stratify severity. Despite the ubiquitous clinical use of the ECG to detect ischemia, the sensitivity and specificity of ECG based detection of myocardial ischemia are still inadequate. PURPOSE: The purpose of this study was to compare, using animal models, the performance of several traditional ECG-based metrics for detecting acute ischemia against two novel metrics, the Laplacian Eigenmap (LE) parameters and a three-dimensional estimate of Conduction Velocity (CV). METHODS: LE is a machine learning technique that reduces the dimensions of simultaneously recorded time signals using a non-linear embedding followed by an singular value decomposition to represent each multichannel recording as a single trajectory on a manifold. Perturbations in the trajectories suggest the presence of myocardial ischemia. CV was computed using a tetrahedral mesh created from the electrode locations of transmural plunge needles. To validate the results, we used electrograms collected over 95 episodes of acutely induced myocardial ischemia in 15 canine and 2 porcine subjects. The LE and CV metrics were compared against traditional metrics derived from the ST segment, the T wave, the QRS of the same electrograms. The response time and robustness of each metric was quantified using parameters we defined as time to threshold (TTT) and contrast ratio (CR). RESULTS: The temporal performance of the metrics evaluated throughout the ischemic episodes showed a consistent relationship; the LE metrics changed earlier than those from the T wave, which were followed by those from the ST segment, and finally from the QRS. The CV results showed median drops in conduction velocity throughout the perfusion bed of more than 23% in canines and over 12% during half of the induced ischemia episodes in swine. The other half of the episodes in swine produced a 76% drop. CONCLUSIONS: Our results suggest that the LE metric is more sensitive to acute ischemia than traditional single parameters used in previous studies, likely because it incorporates the entire QRST across multiple electrodes in a way that captures their most salient features in a low-dimensional space. The estimates of conduction velocity suggest substantial, in some cases dramatic slowing of the spread of activation, a finding that is not surprising but has not been documented in such three-dimensional detail before. The experiments and these new metrics provide a means to both explore details of the acute ischemic response not available from humans and suggest a path to translate this knowledge into improvements in clinical scoring of ischemia. Published by Elsevier Inc.
BACKGROUND:Myocardial ischemia has a complex and time-varying electrocardiographic signature that is used to diagnose and stratify severity. Despite the ubiquitous clinical use of the ECG to detect ischemia, the sensitivity and specificity of ECG based detection of myocardial ischemia are still inadequate. PURPOSE: The purpose of this study was to compare, using animal models, the performance of several traditional ECG-based metrics for detecting acute ischemia against two novel metrics, the Laplacian Eigenmap (LE) parameters and a three-dimensional estimate of Conduction Velocity (CV). METHODS: LE is a machine learning technique that reduces the dimensions of simultaneously recorded time signals using a non-linear embedding followed by an singular value decomposition to represent each multichannel recording as a single trajectory on a manifold. Perturbations in the trajectories suggest the presence of myocardial ischemia. CV was computed using a tetrahedral mesh created from the electrode locations of transmural plunge needles. To validate the results, we used electrograms collected over 95 episodes of acutely induced myocardial ischemia in 15 canine and 2 porcine subjects. The LE and CV metrics were compared against traditional metrics derived from the ST segment, the T wave, the QRS of the same electrograms. The response time and robustness of each metric was quantified using parameters we defined as time to threshold (TTT) and contrast ratio (CR). RESULTS: The temporal performance of the metrics evaluated throughout the ischemic episodes showed a consistent relationship; the LE metrics changed earlier than those from the T wave, which were followed by those from the ST segment, and finally from the QRS. The CV results showed median drops in conduction velocity throughout the perfusion bed of more than 23% in canines and over 12% during half of the induced ischemia episodes in swine. The other half of the episodes in swine produced a 76% drop. CONCLUSIONS: Our results suggest that the LE metric is more sensitive to acute ischemia than traditional single parameters used in previous studies, likely because it incorporates the entire QRST across multiple electrodes in a way that captures their most salient features in a low-dimensional space. The estimates of conduction velocity suggest substantial, in some cases dramatic slowing of the spread of activation, a finding that is not surprising but has not been documented in such three-dimensional detail before. The experiments and these new metrics provide a means to both explore details of the acute ischemic response not available from humans and suggest a path to translate this knowledge into improvements in clinical scoring of ischemia. Published by Elsevier Inc.
Authors: F Kornreich; T J Montague; M Kavadias; J Segers; P M Rautaharju; M B Horacek; B Taccardi Journal: Am J Cardiol Date: 1987-12-01 Impact factor: 2.778
Authors: M J Janse; F J van Capelle; H Morsink; A G Kléber; F Wilms-Schopman; R Cardinal; C N d'Alnoncourt; D Durrer Journal: Circ Res Date: 1980-08 Impact factor: 17.367
Authors: Jaume Coll-Font; Shi Chen; Robert Eder; Yiling Fang; Qiao Joyce Han; Maaike van den Boomen; David E Sosnovik; Choukri Mekkaoui; Christopher T Nguyen Journal: Magn Reson Med Date: 2021-08-13 Impact factor: 4.668
Authors: W W Good; B Erem; B Zenger; J Coll-Font; J A Bergquist; D H Brooks; R S MacLeod Journal: Comput Biol Med Date: 2020-10-28 Impact factor: 4.589
Authors: Wilson W Good; Karli K Gillette; Brian Zenger; Jake A Bergquist; Lindsay C Rupp; Jess Tate; Devan Anderson; Matthias A F Gsell; Gernot Plank; Rob S MacLeod Journal: IEEE Trans Biomed Eng Date: 2021-10-19 Impact factor: 4.756
Authors: Wilson W Good; Karli K Gillette; Jake A Bergquist; Brian Zenger; Jess Tate; Lindsay C Rupp; Devan Anderson; Gernot Plank; Rob S MacLeod Journal: Comput Cardiol (2010) Date: 2020-02-24