Quantifying the atrial conduction velocity (CV) reveals important information for targeting critical arrhythmia sites that initiate and sustain abnormal electrical pathways, e.g. during atrial flutter. The knowledge about the local CV distribution on the atrial surface thus enhances clinical catheter ablation procedures by localizing pathological propagation paths to be eliminated during the intervention. Several algorithms have been proposed for estimating the CV. All of them are solely based on the local activation times calculated from electroanatomical mapping data. They deliver false values for the CV if applied to regions near scars or wave collisions. We propose an extension to all approaches by including a distinct preprocessing step. Thereby, we first identify scars and wave front collisions and provide this information for the CV estimation algorithm. In addition, we provide reliable CV values even in the presence of noise. We compared the performance of the Triangulation, the Polynomial Fit and the Radial Basis Functions approach with and without the inclusion of the aforementioned preprocessing step. The evaluation was based on different activation patterns simulated on a 2D synthetic triangular mesh with different levels of noise added. The results of this study demonstrate that the accuracy of the estimated CV does improve when knowledge about the depolarization pattern is included. Over all investigated test cases, the reduction of the mean velocity error quantified to at least 25 mm/s for the Radial Basis Functions, 14 mm/s for the Polynomial Fit and 14 mm/s for the Triangulation approach compared to their respective implementations without the preprocessing step. Given the present results, this novel approach can contribute to a more accurate and reliable CV estimation in a clinical setting and thus improve the success of radio-frequency ablation to treat cardiac arrhythmias

Dössel, O.

Nagel, C.

Pilia, N.

Unger, L.

English

KITopen

Current Directions in Biomedical Engineering 2019;5(1):101–104Claudia Nagel*, Nicolas Pilia, Laura Unger, and Olaf DösselPerformance of Different Atrial ConductionVelocity Estimation Algorithms Improves withKnowledge about the Depolarization Patternhttps://doi.org/10.1515/cdbme-2019-0026Abstract: Quantifying the atrial conduction velocity (CV) re-veals important information for targeting critical arrhythmiasites that initiate and sustain abnormal electrical pathways, e.g.during atrial flutter. The knowledge about the local CV distri-bution on the atrial surface thus enhances clinical catheter ab-lation procedures by localizing pathological propagation pathsto be eliminated during the intervention.Several algorithms have been proposed for estimating the CV.All of them are solely based on the local activation times calcu-lated from electroanatomical mapping data. They deliver falsevalues for the CV if applied to regions near scars or wave colli-sions. We propose an extension to all approaches by includinga distinct preprocessing step. Thereby, we first identify scarsand wave front collisions and provide this information for theCV estimation algorithm. In addition, we provide reliable CVvalues even in the presence of noise. We compared the perfor-mance of the Triangulation, the Polynomial Fit and the RadialBasis Functions approach with and without the inclusion of theaforementioned preprocessing step. The evaluation was basedon different activation patterns simulated on a 2D synthetictriangular mesh with different levels of noise added.The results of this study demonstrate that the accuracy of theestimated CV does improve when knowledge about the depo-larization pattern is included. Over all investigated test cases,the reduction of the mean velocity error quantified to at least25 mm/s for the Radial Basis Functions, 14 mm/s for the Poly-nomial Fit and 14 mm/s for the Triangulation approach com-pared to their respective implementations without the prepro-cessing step.Given the present results, this novel approach can contribute toa more accurate and reliable CV estimation in a clinical settingand thus improve the success of radio-frequency ablation totreat cardiac arrhythmias.Keywords: atrial conduction velocity, local activation timeprocessing, atrial flutter*Corresponding author: Claudia Nagel, Karlsruhe Institute ofTechnology, Institute of Biomedical Engineering, Karlsruhe,Germany, e-mail: publications@ibt.kit.eduNicolas Pilia, Laura Unger, Olaf Dössel, Karlsruhe Instituteof Technology, Institute of Biomedical Engineering, Karlsruhe,Germany1 IntroductionAtrial flutter is one of the most common cardiac arrhythmiasin e.g. European countries and the USA. A standard procedureto treat this type of supraventricular tachycardia is radiofre-quency ablation. Thereby, small lesions are induced on the car-diac tissue to eliminate the abnormal excitation pathways.The localization of these pathological paths such as slowconducting tissue areas can be carried out by quantifying thecardiac conduction velocity and its direction. For this purpose,several CV estimation algorithms have already been proposed.However, all of these algorithms reported as suitable for aclinical environment are based on the local activation times(LAT) that are extracted from measured intracardiac electro-grams [1]. They do neither consider that scar tissue stops theexcitation propagation nor do they deliver reliable estimationvalues in vicinity to wave front collisions.We propose an extension applicable to three existing al-gorithms by including a distinct prepocessing step. It con-sists of the identification of scar locations, wave collisions andlow signal to noise ratio (SNR) areas. This a-priori knowledgeabout the depolarization pattern is then included in the CV es-timation routine. The performance evaluation was carried outwith three algorithms reported as suitable for the clinical usecase [3–5] on a 2D triangle mesh.2 Methods2.1 Synthetic Test CasesSynthetic test cases with a known ground truth CV were simu-lated with the Fast Marching method [6]. In this way, the esti-mated CV output from the algorithms could be validated withthe predefined ground truth CV of the simulation setup.Different activation patterns were simulated on a 2D equi-lateral triangle mesh. The mesh contained 15229 faces whichcomposed 30096 triangular faces with a side length of 1.3 mm.These values are chosen according to an exemplary clinicalatrial mesh to create settings comparable to the actual clinicaluse case. Open Access. © 2019 Claudia Nagel et al., published by De Gruyter.  This work is licensed under the Creative Commons Attribution 4.0 License. Bereitgestellt von | Karlsruher Institut für Technologie KIT-BibliothekAngemeldetHeruntergeladen am | 09.10.19 11:41102 C. Nagel et al., CV Estimation Improves with Knowledge about the Depolarization PatternThe simulated LAT maps covered all major activation pat-terns that occur in practice, including the following propaga-tion characteristics:– a radial as well as a planar wave with a homogeneous CVset to 200 mm/s all over the mesh (cf. Fig. 1a, 1d)– a planar wave passing through four horizontal areas withdifferent CVs starting with 200 mm/s at the bottom edgeand increasing in steps of 𝛿𝑣 = 20 mm/s (cf. Fig. 1b) and𝛿𝑣 = 200 mm/s (cf. Fig. 1c)– two focal sources at the lower left and the upper right cor-ner of the mesh causing a wave collision on the main di-agonal (cf. Fig. 1e)– a linear horizontal scar a with a planar wave propagationin orthogonal and parallel direction with respect to thescar (cf. Fig. 1h, 1g) and with a radial wave propagationfrom a focal source in the lower left corner (cf. Fig. 1f)– a box shaped scar with a gap causing delayed depolariza-tion of the enclosed tissue (cf. Fig. 1i)(a) Planar Wave (b) 𝛿𝑣 = 20 mm/s (c) 𝛿𝑣 = 200 mm/s(d) Radial wave (e) Wave front colli-sions(f) Horizontal scarwith spherical wave(g) Horizontal scarwith parallel planarwave(h) Horizontal scarwith vertical planarwave(i) Box shaped scarFig. 1: Synthetic 2D test cases representing the excitation pat-terns to be identified in a clinical environment. The ground truthCV for the Fast Marching simulation is set to 200 mm/s unlessotherwise stated. Scar nodes are marked in yellow. Blue coloredareas represent early excited areas, whereas red colored areasindicate that the excitation arrives later in time.Following the Fast Marching simulation, white Gaussian noisewith an SNR of 15dB and 30dB was added to the spatial coor-dinates and the temporal LAT values. In this way the circum-stances in a clinical environment, consisting of LAT measure-ment noise and electrode localization errors, were simulated.Fig. 2 sketches the workflow of the adapted CV estima-tion routine with the inclusion of the knowledge about the pat-tern of depolarization. The individual processing steps are ex-plained in more detail in the subsequent sections.Simulated Noisy Test CaseLocal SNRCV EstimationLAT MapScar LocationsCV EstimationFinal CV Vector FieldRefinement of the Fitting NeighborhoodIdentification ofWave Collisionsconsists of1st2ndFig. 2: Workflow for estimating the CV with noisy LAT maps byincluding information about scars, wave front collisions and thelocal SNR distribution.2.2 LAT Map PreprocessingTo ensure that excitation propagation was not modeled throughscar nodes, the LAT Maps were first preprocessed before ap-plying the CV estimation algorithm. The knowledge about thescar locations were given by the simulation settings for theFast Marching algorithm. Mesh edges that connected thosescar nodes to any other node in the mesh were deleted. In thisway, the mesh connectivities represented only valid excitationpathways and scar locations were not part of the mesh any-more.2.3 Robust CV Estimation with NoisyLAT Maps in the Presence of ScarsThe CV estimation was carried out with the triangulation ap-proach and by means of surface fitting with a polynomial of or-der two as well as with Gaussian radial basis functions (RBF).These three approaches are well documented in literature andshowed promising results in various simulation and clinicalBereitgestellt von | Karlsruher Institut für Technologie KIT-BibliothekAngemeldetHeruntergeladen am | 09.10.19 11:41C. Nagel et al., CV Estimation Improves with Knowledge about the Depolarization Pattern 103studies [3–5]. Some adjustments were made to ensure properbehavior around scars, wave collisions and noisy LAT areas.This included on the one hand the choice of the localfitting neighborhood for the surface fitting approaches. Thefitting neighborhood was determined according to the graphconnections instead of the Euclidean distance to the surround-ing points. In this way, scar nodes were excluded from the fitwhich would otherwise have distorted the fitted surface andyielded an inaccurate CV estimation. Furthermore, the neigh-borhood size was increased from 20 to 200 points if the SNRin a specific area felt below a threshold of 50dB. In this way,the radius of the fitting neighborhood was approximately in-creased by factor three. Thereby, the algorithms were provideda larger fitting region to average over noisy LAT points.To reduce the influence of noisy LATs at the mesh nodesfor the triangulation approach, the triangles to fit in a planarwave were chosen three times larger than the ones in the orig-inal triangulation mesh. Nevertheless, this procedure does notresult in a decreased mesh density. Instead, the extended trian-gles were shifted and rotated along the original mesh and over-lapping regions were assigned the average of the calculatedCVs. Scar nodes were not included in the calculation processfor this approach either by inhibiting the planar wave fit in anenlarged triangle that overlaps with scar regions.2.4 Identification of Wave FrontCollisionsThe identification of wave front collisions within the activa-tion patterns in connection with the CV estimation is crucialbecause a wave’s velocity is physically not defined at a nodewhere two wave fronts collide with each other. Therefore, itwas necessary to localize these points and deliver a warningthat a CV estimation at these spots is not reliable.The wave front collisions were identified by means of thedivergence operator [2]:∇𝐶𝑉 = 𝜕𝐶𝑉𝑥𝜕𝑥+𝜕𝐶𝑉𝑦𝜕𝑦(1)The divergence operator provided a metric for sinks andsources within a vector field. It characterizes sources with apositive, sinks or collisions with a negative and a parallel prop-agation with a value around zero. The CV values calculatedwith one of the algorithms presented in the previous sectionwere first normalized before put into equation 1. In this way, itwas guaranteed that only the direction of the CV vectors havean impact on the divergence and not their magnitude [1].Hereafter, the choice of the neighborhood for the surfacefitting as well as of the triangles for the triangulation approachwas refined with the knowledge about collision locations. Inthis way, the CV estimation in a second iteration could beperformed in regions where a mostly homogeneous excitationpropagation prevails. In such areas the planar wave assump-tion holding for the triangulation approach can approximatelybe met. Furthermore, the fitting of a planar LAT surface withthe RBF and the Polynomial Fit method can be executed morerobustly compared to one of an undulating surface. Therefore,the CV calculation was carried out a second time taking thedivergence values at each mesh point into consideration.3 ResultsIn this study, the CV calculation for each test case was car-ried out for each of the three presented algorithms once withand once without the knowledge about collision and scar loca-tions as well as with the local SNR. The mean velocity errorof each experiment was calculated by averaging the absolutevalue of the differences between the ground truth CV that wasset for the simulation and the estimated CV values for eachmesh node or triangle 𝑖 :mean(Δ𝑣) =1𝑁𝑁∑︁𝑖=1|𝐶𝑉𝑒𝑠𝑡,𝑖 − 𝐶𝑉𝑔𝑡,𝑖| (2)The change of the mean velocity error when including thepreprocessing step was quantified in the following way:Δ𝑒 = mean(Δ𝑣𝑤)− mean(Δ𝑣𝑤𝑜) (3)The terms mean(Δ𝑣𝑤) and mean(Δ𝑣𝑤𝑜) refer to the mean ve-locity error calculated according to equation 2 with (Δ𝑣𝑤) andwithout (Δ𝑣𝑤𝑜) the preprocessing step, respectively. A nega-tive value of Δ𝑒 thus implied an improvement and a positiveone a deterioration of the CV estimation performance whenincluding the a-priori knowledge about scars, wave collisionsand the local SNR.Tab. 1 shows that the change of the mean velocity errorwas negative for all test cases, both noise levels and all CVestimation algorithms.When including a-priori knowledge, the absolute velocityerrors mean(Δ𝑣𝑤) averaged over all test cases quantified to56mm/s (145mm/s), 24mm/s (102mm/s) and 9mm/s (39mm/s)for the Triangulation, the Polynomial Fit and the RBF ap-proach in the 30dB (15dB) cases.4 DiscussionIn each investigated case, the inclusion of the knowledge aboutthe depolarization pattern reduced the mean velocity error inBereitgestellt von | Karlsruher Institut für Technologie KIT-BibliothekAngemeldetHeruntergeladen am | 09.10.19 11:41C. Nagel et al., CV Estimation Improves with Knowledge about the Depolarization PatternTab. 1: Assessement of the mean velocity error change Δ𝑒 inmm/s for all test cases with an SNR of 15dB and 30dB when in-cluding the preprocessing step. Negative values imply an improve-ment by including a-priori knowledge.Test Case Triangulation Polynomial Fit RBF15dB 30dB 15dB 30dB 15dB 30dB(a) Planar Wave -35 -56 -25 -25 -83 -34(b) 𝛿𝑣 = 20mm/s -31 -62 -56 -28 -103 -38(c) 𝛿𝑣 = 200mm/s -75 -88 -124 -19 -167 -88(d) Spherical Wave -35 -54 -29 -21 -82 -25(e) Wave Collisions -29 -61 -14 -39 -87 -41(f) Scar, Radial W. -14 -55 -14 -46 -86 -63(g) Scar, Parallel W. -24 -57 -16 -41 -91 -54(h) Scar, Vertical W. -26 -56 -27 -34 -85 -46(i) Box Shaped Scar -32 -59 -27 -31 -88 -40the mesh independent on the choice of the CV estimation algo-rithm (cf. Tab. 1). This implies that the inclusion of the prepro-cessing step definitely leads to a more robust and reliable CVestimation for simulated clinically relevant excitation patterns.The inclusion of a-priori knowledge has the highest impact onthe CV estimation with the RBF approach and the lowest onefor the Polynomial Fit method.The knowledge about the scar locations are given by thesimulation setup in this study. Nevertheless, they are also ex-tractable from clinical cata. The same holds for the local signalto noise ratio. Therefore, the proposed preprocessing routine isnot only suited for simulated environments but it can also im-prove the results of the CV estimation in a real clinical setting.The identification of wave front collisions required an ini-tial calculation of the CV vector field before the neighborhoodselection could be refined for the second iteration of the CVestimation. This is a valid approach if the initial calculationof the velocity directions already delivered values of sufficientaccuracy for the application of the divergence operator whenscar locations and the local SNR are available. For all exper-iments with the lowest SNR, the median angle between theground truth CV direction and the calculated CV direction af-ter the first iteration amounts to 55∘, 12∘ and 4∘ for the Tri-angulation, the Polynomial Fit and the RBF approach, respec-tively. This estimation is of adequate precision for the Polyno-mial Fit and the RBF method, which is why the initial vectorfield estimation could be used for the application of the diver-gence operator before the CV speed could be assessed moreprecisely.However, the use of collision detection to position the en-larged triangles for the Triangulation approach might be de-batable due to the relatively high direction error after the firstCV estimation iteration. The latter reflects also in the valuesfor Δ𝑒 shown in Tab.1. The improvement for the Triangula-tion approach with an SNR of 15dB is for all cases inferiorcompared to those of the 30dB cases.5 ConclusionWe showed that an additional processing step yields a more ro-bust CV estimation in combination with the three investigatedCV algorithms compared to their respective implementationsas documented in literature. This fosters confidence that theknowledge about scar locations, the SNR distribution andwave collisions contributes to a sufficiently reliable CV cal-culation. In doing so, a quantitative metric can be deducedduring a clinical electrophysiological study to target ablationlocations for the treatment of cardiac arrhythmias.Author StatementResearch funding: The author state no funding involved. Con-flict of interest: Authors state no conflict of interest.References[1] C. Cantwell, C. Roney, F. Ng, et al., “Techniques for auto-mated local activation time annotation and conduction veloc-ity estimation in cardiac mapping,” Computers in Biology andMedicine, vol. 65, Oct. 2015, pp. 229–242.[2] T. Fitzgerald, D. Brooks, and J. Triedman, “Identification ofCardiac Rhythm Features by Mathematical Analysis of VectorFields,” IEEE Transactions on Biomedical Engineering, vol.52, no. 1, Jan. 2005, pp. 19–29.[3] M. Mase and F. Ravelli, “Automatic reconstruction of activa-tion and velocity maps from electro- anatomic data by radialbasis functions,” in 2010 Annual International Conference ofthe IEEE Engineering in Medicine and Biology. Buenos Aires:IEEE, Aug. 2010, pp. 2608–2611.[4] A. Barnette, P. Bayly, Shu Zhang, et al., “Estimation of 3-Dconduction velocity vector fields from cardiac mapping data,”IEEE Transactions on Biomedical Engineering, vol. 47, no. 8,Aug. 2000, pp. 1027–1035.[5] C.D.Cantwell, C.H.Roney, R.L.Ali, et al., “A software platformfor the comparative analysis of electroanatomic and imagingdata including conduction velocity mapping,” in 2014 36thAnnual International Conference of the IEEE Engineering inMedicine and Biology Society. Chicago, IL: IEEE, Aug. 2014,pp. 1591–1594.[6] J.A.Sethian, “A fast marching level set method for mono-tonically advancing fronts. ”Proceedings of the NationalAcademy of Sciences, vol. 93, no. 4, Feb. 1996, pp.1591–1595.104Bereitgestellt von | Karlsruher Institut für Technologie KIT-BibliothekAngemeldetHeruntergeladen am | 09.10.19 11:41

Performance of Different Atrial Conduction Velocity Estimation Algorithms Improves with Knowledge about the Depolarization Pattern

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Performance of Different Atrial Conduction Velocity Estimation Algorithms Improves with Knowledge about the Depolarization Pattern

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