Your search keyword '"Snare, SR"' showing total 11 results

1. Poster session Wednesday 11 December all day display: 11/12/2013, 09: 30–16: 00Location: Poster area

Author

Storve, S, Dalen, H, Snare, SR, Haugen, BO, and Torp, H

Published

2013

2. P791Non-expert assessment of left ventricular systolic function using pocket-sized ultrasound

Author

Mjolstad, OC, Snare, SR, Folkvord, L, Helland, F, Torp, H, Haraldseth, O, Grimsmo, A, and Haugen, BO

Published

2011

3. Assessment of left ventricular function by GPs using pocket-sized ultrasound.

Author

Mjølstad OC, Snare SR, Folkvord L, Helland F, Grimsmo A, Torp H, Haraldseth O, Haugen BO, Mjølstad, Ole Christian, Snare, Sten Roar, Folkvord, Lasse, Helland, Frode, Grimsmo, Anders, Torp, Hans, Haraldseth, Olav, and Haugen, Bjørn Olav

Abstract

Background: Assessment of left ventricular (LV) function with echocardiography is mandatory in patients with suspected heart failure (HF).Objectives: To investigate if GPs were able to evaluate the LV function in patients at risk of developing or with established HF by using pocket-sized ultrasound (pUS).Methods: Feasibility study in general practice, seven GPs in three different Norwegian primary care centres participated. Ninety-two patients with reduced or at risk of developing reduced LV function were examined by their own GP using pUS. The scan (<5 minute) was done as part of a routine appointment. A cardiologist examined the patients <30 minutes afterwards with both a laptop scanner and pUS. Measurements of the septal mitral annular excursion (sMAE) were compared.Results: In 87% of the patients, the GPs were able to obtain a standard view and measure the sMAE. There was a non-significant mean difference in sMAE between GP pUS and cardiologist laptop scanner of -0.15 mm 95% confidence interval (-0.60 to 0.30) mm. A comparison of the pUS recordings and measurements of sMAE made by GP versus cardiologist revealed a non-significant mean difference with acceptable 95% limits of agreement (-0.26 ± 3.02 mm).Conclusions: With tailored training, GPs were able to assess LV function with sMAE and pUS. pUS, as a supplement to the physical examination, may become an important tool in general practice. [ABSTRACT FROM AUTHOR]

Published

2012

4. Poster session Wednesday 11 December all day display: 11/12/2013, 09:30-16:00 * Location: Poster area

Author

Bertrand, PB, Grieten, L, Smeets, C, Verbrugge, FH, Mullens, W, Vrolix, M, Rivero-Ayerza, M, Verhaert, D, Vandervoort, P, Tong, L, Ramalli, A, Tortoli, P, Dhoge, J, Bajraktari, G, Lindqvist, P, Henein, MY, Obremska, M, Boratynska, MB, Kurcz, JK, Zysko, DZ, Baran, TB, Klinger, MK, Darahim, K, Mueller, H, Carballo, D, Popova, N, Vallee, J-P, Floria, M, Chistol, R, Tinica, G, Grecu, M, Rodriguez Serrano, M, Osa-Saez, A, Rueda-Soriano, J, Buendia-Fuentes, F, Domingo-Valero, D, Igual-Munoz, B, Alonso-Fernandez, P, Quesada-Carmona, A, Miro-Palau, V, Palencia-Perez, M, Bech-Hanssen, O, Polte, CL, Lagerstrand, K, Janulewicz, M, Gao, S, Erdogan, E, Akkaya, M, Bacaksiz, A, Tasal, A, Sonmez, O, Turfan, M, Kul, S, Vatankulu, MA, Uyarel, H, Goktekin, O, Mincu, RI, Magda, LS, Mihaila, S, Florescu, M, Mihalcea, D, Enescu, OE, Chiru, A, Popescu, B, Tiu, C, Vinereanu, D, 112/2011, Research grant, Broch, K, Kunszt, G, Massey, R, De Marchi, SF, Aakhus, S, Gullestad, L, Urheim, S, Yuan, L, Feng, JL, Jin, XY, Bombardini, T, Casartelli, M, Simon, D, Gaspari, MG, Procaccio, F, Hasselberg, NE, Haugaa, KH, Brunet, A, Kongsgaard, E, Donal, E, Edvardsen, T, Sahin, TAYLAN, Yurdakul, S, Cengiz, BETUL, Bozkurt, AYSEN, Aytekin, SAIDE, Cesana, F, Spano, F, Santambrogio, G, Alloni, M, Vallerio, P, Salvetti, M, Carerj, S, Gaibazzi, N, Rigo, F, Moreo, A, Group, APRES Collaborative, Wdowiak-Okrojek, K, Michalski, B, Kasprzak, JD, Shim, A, Lipiec, P, Generati, G, Pellegrino, M, Bandera, F, Donghi, V, Alfonzetti, E, Guazzi, M, Marcun, R, Stankovic, I, Farkas, J, Vlahovic-Stipac, A, Putnikovic, B, Kadivec, S, Kosnik, M, Neskovic, AN, Lainscak, M, Iliuta, L, Szymanski, P, Lipczynska, M, Klisiewicz, A, Sobieszczanska-Malek, M, Zielinski, T, Hoffman, P, Gjerdalen, G F, Hisdal, J, Solberg, EE, Andersen, TE, Radunovic, Z, Steine, K, Svanadze, A, Poteshkina, N, Krylova, N, Mogutova, P, Shim, A, Kasprzak, JD, Szymczyk, E, Wdowiak-Okrojek, K, Michalski, B, Stefanczyk, L, Lipiec, P, Benedek, T, Matei, C, Jako, B, Suciu, ZS, Benedek, I, Yaroshchuk, N A, Kochmasheva, V V, Dityatev, V P, Kerbikov, O B, Przewlocka-Kosmala, M, Orda, A, Karolko, B, Mysiak, A, Kosmala, W, Rechcinski, T, Wierzbowska-Drabik, K, Lipiec, P, Chmiela, M, Kasprzak, JD, Aziz, A, Hooper, J, Rayasamudra, S, Uppal, H, Asghar, O, Potluri, R, Zaroui, A, Mourali, MS, Rezine, Z, Mbarki, S, Jemaa, M, Aloui, H, Mechmeche, R, Farhati, A, Gripari, P, Maffessanti, F, Tamborini, G, Muratori, M, Fusini, L, Vignati, C, Bartorelli, AL, Alamanni, F, Agostoni, PG, Pepi, M, Ruiz Ortiz, M, Mesa, D, Delgado, M, Seoane, T, Carrasco, F, Martin, M, Mazuelos, F, Suarez De Lezo Herreros De Tejada, J, Romero, M, Suarez De Lezo, J, Brili, S, Stamatopoulos, I, Misailidou, M, Chrisochoou, C, Christoforatou, E, Stefanadis, C, Ruiz Ortiz, M, Mesa, D, Delgado, M, Martin, M, Seoane, T, Carrasco, F, Ojeda, S, Segura, J, Pan, M, Suarez De Lezo, J, Cammalleri, V, Ussia, GP, Muscoli, S, Marchei, M, Sergi, D, Mazzotta, E, Romeo, F, Igual Munoz, B, Bel Minguez, ABM, Perez Guillen, MPG, Maceira Gonzalez, AMG, Monmeneu Menadas, JVMM, Hernandez Acuna, CHA, Estornell Erill, JEE, Lopez Lereu, PLL, Francisco Jose Valera Martinez, FJVM, Montero Argudo, AMA, Sunbul, M, Akhundova, A, Sari, I, Erdogan, O, Mutlu, B, Cacicedo, A, Velasco Del Castillo, S, Anton Ladislao, A, Aguirre Larracoechea, U, Rodriguez Sanchez, I, Subinas Elorriaga, A, Oria Gonzalez, G, Onaindia Gandarias, J, Laraudogoitia Zaldumbide, E, Lekuona Goya, I, Ding, W, Zhao, Y, Lindqvist, P, Nilson, J, Winter, R, Holmgren, A, Ruck, A, Henein, MY, Attenhofer Jost, C H, Soyka, R, Oxenius, A, Kretschmar, O, Valsangiacomo Buechel, ER, Greutmann, M, Weber, R, Keramida, K, Kouris, N, Kostopoulos, V, Karidas, V, Damaskos, D, Makavos, G, Paraskevopoulos, K, Olympios, CD, Eskesen, K, Olsen, NT, Fritz-Hansen, T, Sogaard, P, Cameli, M, Lisi, M, Righini, FM, Curci, V, Massoni, A, Natali, B, Maccherini, M, Chiavarelli, M, Massetti, M, Mondillo, S, Mabrouk Salem Omar, A, Ahmed Abdel-Rahman, M, Khorshid, H, Rifaie, O, Santoro, C, Santoro, A, Ippolito, R, De Palma, D, De Stefano, F, Muscariiello, R, Galderisi, M, Squeri, A, Censi, S, Baldelli, M, Grattoni, C, Cremonesi, A, Bosi, S, Saura Espin, D, Gonzalez Canovas, C, Gonzalez Carrillo, J, Oliva Sandoval, MJ, Caballero Jimenez, L, Espinosa Garcia, MD, Garcia Navarro, M, Valdes Chavarri, M, De La Morena Valenzuela, G, Ryu, SK, Shin, DG, Son, JW, Choi, JH, Goh, CW, Choi, JW, Park, JY, Hong, GR, Sklyanna, O, Yuan, L, Yuan, L, Planinc, I, Bagadur, G, Ljubas, J, Baricevic, Z, Skoric, B, Velagic, V, Bijnens, B, Milicic, D, Cikes, M, Gospodinova, M, Chamova, T, Guergueltcheva, V, Ivanova, R, Tournev, I, Denchev, S, Ancona, R, Comenale Pinto, S, Caso, P, Arenga, F, Coppola, MG, Calabro, R, Neametalla, H, Boitard, S, Hamdi, H, Planat-Benard, V, Casteilla, L, Li, Z, Hagege, AA, Mericskay, M, Menasche, P, Agbulut, O, Merlo, M, Stolfo, D, Anzini, M, Negri, F, Pinamonti, B, Barbati, G, Di Lenarda, A, Sinagra, G, Stolfo, D, Merlo, M, Pinamonti, B, Gigli, M, Poli, S, Porto, A, Di Nora, C, Barbati, G, Di Lenarda, A, Sinagra, G, Coppola, C, Piscopo, G, Cipresso, C, Rea, D, Maurea, C, Esposito, E, Arra, C, Maurea, N, Nemes, A, Kalapos, A, Domsik, P, Forster, T, Voilliot, D, Huttin, O, Vaugrenard, T, Schwartz, J, Sellal, J-M, Aliot, E, Juilliere, Y, Selton-Suty, C, Sanchez Millan, P J, Cabeza Lainez, P, Castillo Ortiz, J, Chueca Gonzalez, EM, Gheorghe, L, Fernandez Garcia, P, Herruzo Rojas, MS, Del Pozo Contreras, R, Fernandez Garcia, M, Vazquez Garcia, R, Rosca, M, Popescu, BA, Botezatu, D, Calin, A, Beladan, CC, Gurzun, M, Enache, R, Ginghina, C, Farouk, H, Al-Maimoony, T, Alhadad, A, El Serafi, M, Abdel Ghany, M, Poorzand, H, Mirfeizi, SZ, Javanbakht, A, center, Preventive Cardiovascular care research, center, Lupus Research, sciences, Mashhad university of medical, Tellatin, S, Famoso, G, Dassie, F, Martini, C, Osto, E, Maffei, P, Iliceto, S, Tona, F, Radunovic, Z, Steine, KS, Jedrzejewska, I, Braksator, W, Krol, W, Swiatowiec, A, Sawicki, J, Kostarska-Srokosz, E, Dluzniewski, M, Maceira Gonzalez, A M, Cosin-Sales, J, Diago, JL, Aguilar, J, Ruvira, J, Monmeneu, J, Igual, B, Lopez-Lereu, MP, Estornell, J, Olszanecka, A, Dragan, A, Kawecka-Jaszcz, K, Czarnecka, D, Scholz, F, Gaudron, PD, Hu, K, Liu, D, Florescu, C, Herrmann, S, Bijnens, B, Ertl, G, Stoerk, S, Weidemann, F, Krestjyaninov, M, Razin, VA, Gimaev, RH, Bogdanovic, Z, Burazor, I, Deljanin Ilic, M, Peluso, D, Muraru, D, Cucchini, U, Mihaila, S, Casablanca, S, Pigatto, E, Cozzi, F, Punzi, L, Badano, LP, Iliceto, S, Zhdanova, E, Rameev, VV, Safarova, AF, Moisseyev, SV, Kobalava, ZD, Magnino, C, Omede, P, Avenatti, E, Presutti, D, Losano, I, Moretti, C, Bucca, C, Gaita, F, Veglio, F, Milan, A, Bellsham-Revell, H, Bell, AJ, Miller, OI, Simpson, JM, Hwang, YM, Kim, GH, Jung, MH, Woo, GH, Medicine, Department of Internal, Hospital, St.Vincents, Korea, The Catholic University of, Suwon, Division of Cardiology, Repu, Driessen, MMP, Leiner, T, Schoof, PH, Breur, JMPJ, Sieswerda, GT, Meijboom, FJ, Bellsham-Revell, H, Hayes, N, Anderson, D, Austin, BC, Razavi, R, Greil, GF, Simpson, JM, Bell, AJ, Zhao, XX, Xu, XD, Qin, YW, Szmigielski, C A, Styczynski, G, Sobczynska, M, Placha, G, Kuch-Wocial, A, Ikonomidis, I, Voumbourakis, A, Triantafyllidi, H, Pavlidis, G, Varoudi, M, Papadakis, I, Trivilou, P, Paraskevaidis, I, Anastasiou-Nana, M, Lekakis, I, Kong, WILL, Yip, JAMES, Ling, LH, Milan, A, Tosello, F, Leone, D, Bruno, G, Losano, I, Avenatti, E, Sabia, L, Veglio, F, Zaborska, B, Baran, J, Pilichowska-Paszkiet, E, Sikora-Frac, M, Michalowska, I, Kulakowski, P, Budaj, A, Mega, S, Bono, MC, De Francesco, V, Castiglione, I, Ranocchi, F, Casacalenda, A, Goffredo, C, Patti, G, Di Sciascio, G, Musumeci, F, Kennedy, M, Waterhouse, DF, Sheahan, R, Foley, DF, Mcadam, BF, Ancona, R, Comenale Pinto, S, Caso, P, Arenga, F, Coppola, MG, Calabro, R, Remme, E W, Smedsrud, M K, Hasselberg, N E, Smiseth, O A, Edvardsen, T, Halmai, L, Nemes, A, Kardos, A, Neubauer, S, Degiovanni, A, Baduena, L, Dellera, G, Occhetta, E, Marino, P, Hotchi, J, Yamada, H, Nishio, S, Bando, M, Hayashi, S, Hirata, Y, Amano, R, Soeki, T, Wakatsuki, T, Sata, M, Lamia, B, Molano, LC, Viacroze, C, Cuvelier, A, Muir, JF, Lipczynska, M, Piotr Szymanski, PS, Anna Klisiewicz, AK, Lukasz Mazurkiewicz, LM, Piotr Hoffman, PH, Van T Sant, J, Wijers, SC, Ter Horst, IAH, Leenders, GE, Cramer, MJ, Doevendans, PA, Meine, M, Hatam, N, Goetzenich, A, Aljalloud, A, Mischke, K, Hoffmann, R, Autschbach, R, Sikora-Frac, M, Zaborska, B, Maciejewski, P, Bednarz, B, Budaj, A, Evangelista, A, Torromeo, C, Pandian, NG, Nardinocchi, P, Varano, V, Schiariti, M, Teresi, L, Puddu, PE, Storve, S, Dalen, H, Snare, SR, Haugen, BO, Torp, H, Fehri, W, Mahfoudhi, H, Mezni, F, Annabi, MS, Taamallah, K, Dahmani, R, Haggui, A, Hajlaoui, N, Lahidheb, D, Haouala, H, Colombo, A, Carminati, MC, Maffessanti, F, Gripari, P, Pepi, M, Lang, RM, Caiani, EG, Walker, JR, Abadi, S, Agmon, Y, Carasso, S, Aronson, D, Mutlak, D, Lessick, J, Saxena, A, Ramakrishnan, S, Juneja, R, Ljubas, J, Reskovic Luksic, V, Matasic, R, Pezo Nikolic, B, Lovric, D, Separovic Hanzevacki, J, Quattrone, A, Zito, C, Alongi, G, Vizzari, G, Bitto, A, De Caridi, G, Greco, M, Tripodi, R, Pizzino, G, Carerj, S, Ibrahimi, P, Jashari, F, Johansson, E, Gronlund, C, Bajraktari, G, Wester, P, Henein, MY, Kosmala, W, Marwick, TH, Souza, J R M, Zacharias, L G T, Geloneze, B, Pareja, J C, Chaim, A, Nadruz, W JR, Coelho, O R, Apostolovic, S, Stanojevic, D, Jankovic-Tomasevic, R, Salinger-Martinovic, S, Djordjevic-Radojkovic, D, Pavlovic, M, Tahirovic, E, Musial-Bright, L, Lainscak, M, Duengen, HD, group, CIBIS ELD study, Filipiak, D, Kasprzak, JD, and Lipiec, P

Abstract

Purpose: With the advent of percutaneous transcatheter device closures in congenital heart defects and the emergence of percutaneous left atrial appendage closure, there is an increasingly important role for echocardiographic guidance and control of device position and function. Disc occluder devices frequently present as an unexplained ‘figure-of-8’ on echocardiography. The aim of this study was to clarify this ‘figure-of-8’ display and to relate its morphology to transducer position and device type. Methods: A mathematical model was developed to resemble disc occluder geometry and to allow a numerical simulation of the echocardiographic appearance. In addition, we developed an in vitro set-up for echocardiographic analysis of various disc occluders and various transducer positions. Results: In the mathematical model of an epitrochoid curve (closely resembling disc occluder geometry) a ‘figure-of-8’ display is obtained when emphasizing points with tangent vector perpendicular to the direction of ultrasound waves. Decreasing imaging depth results in a more asymmetric ‘figure-of-8’, with small upper part and wide lower part. Clinical and in vitro data are in close agreement with these results (Figure 1). Furthermore a ‘figure-of-8’ display is only obtained in a coronal imaging position, and is similar for different commercially available disc occluder types. Conclusions: The ‘figure-of-8’ display in the ultrasound image of a disc occluder is an imaging artifact due to the specific ‘epitrochoidal’ geometry of a deployed device and its interaction with ultrasound waves. The morphology of the ‘figure-of-8’ depends on transducer position, i.e. imaging depth, and is similar for different device types. Figure 1 Impact of imaging depth

Published

2013

5. Cardiac Valve Event Timing in Echocardiography Using Deep Learning and Triplane Recordings.

Author

Fermann BS, Nyberg J, Remme EW, Grue JF, Grue H, Haland R, Lovstakken L, Dalen H, Grenne B, Aase SA, Snare SR, and Ostvik A

Subjects

Humans, Heart Valves diagnostic imaging, Heart Valves physiology, Male, Image Interpretation, Computer-Assisted methods, Deep Learning, Echocardiography methods

Abstract

Cardiac valve event timing plays a crucial role when conducting clinical measurements using echocardiography. However, established automated approaches are limited by the need of external electrocardiogram sensors, and manual measurements often rely on timing from different cardiac cycles. Recent methods have applied deep learning to cardiac timing, but they have mainly been restricted to only detecting two key time points, namely end-diastole (ED) and end-systole (ES). In this work, we propose a deep learning approach that leverages triplane recordings to enhance detection of valve events in echocardiography. Our method demonstrates improved performance detecting six different events, including valve events conventionally associated with ED and ES. Of all events, we achieve an average absolute frame difference (aFD) of maximum 1.4 frames (29 ms) for start of diastasis, down to 0.6 frames (12 ms) for mitral valve opening when performing a ten-fold cross-validation with test splits on triplane data from 240 patients. On an external independent test consisting of apical long-axis data from 180 other patients, the worst performing event detection had an aFD of 1.8 (30 ms). The proposed approach has the potential to significantly impact clinical practice by enabling more accurate, rapid and comprehensive event detection, leading to improved clinical measurements.

Published

2024

6. Two methods for modifed Doo-Sabin modeling of nonsmooth surfaces-applied to right ventricle modeling.

Author

Bølviken HS, Bersvendsen J, Orderud F, Snare SR, Brekke P, and Samset E

Abstract

Purpose: In recent years, there has been increased clinical interest in the right ventricle (RV) of the heart. RV dysfunction is an important prognostic marker for several cardiac diseases. Accurate modeling of the RV shape is important for estimating the performance. We have created computationally effective models that allow for accurate estimation of the RV shape. Approach: Previous approaches to cardiac shape modeling, including modeling the RV geometry, has used Doo-Sabin surfaces. Doo-Sabin surfaces allow effective computation and adapt to smooth, organic surfaces. However, they struggle with modeling sharp corners or ridges without many control nodes. We modified the Doo-Sabin surface to allow for sharpness using weighting of vertices and edges instead. This was done in two different ways. For validation, we compared the standard Doo-Sabin versus the sharp Doo-Sabin models in modeling the RV shape of 16 cardiac ultrasound images, against a ground truth manually drawn by a cardiologist. A Kalman filter fitted the models to the ultrasound images, and the difference between the volume of the model and the ground truth was measured. Results: The two modified Doo-Sabin models both outperformed the standard Doo-Sabin model in modeling the RV. On average, the regular Doo-Sabin had an 8-ml error in volume, whereas the sharp models had 7- and 6-ml error, respectively. Conclusions: Compared with the standard Doo-Sabin, the modified Doo-Sabin models can adapt to a larger variety of surfaces while still being compact models. They were more accurate on modeling the RV shape and could have uses elsewhere., (© 2020 Society of Photo-Optical Instrumentation Engineers (SPIE).)

Published

2020

7. Real-Time Nonlocal Means-Based Despeckling.

Author

Breivik LH, Snare SR, Steen EN, and Solberg AHS

Subjects

Algorithms, Anisotropy, Heart diagnostic imaging, Humans, Models, Cardiovascular, Phantoms, Imaging, Time Factors, Image Processing, Computer-Assisted methods, Ultrasonography methods

Abstract

In this paper, we propose a multiscale nonlocal means-based despeckling method for medical ultrasound. The multiscale approach leads to large computational savings and improves despeckling results over single-scale iterative approaches. We present two variants of the method. The first, denoted multiscale nonlocal means (MNLM), yields uniform robust filtering of speckle both in structured and homogeneous regions. The second, denoted unnormalized MNLM (UMNLM), is more conservative in regions of structure assuring minimal disruption of salient image details. Due to the popularity of anisotropic diffusion-based methods in the despeckling literature, we review the connection between anisotropic diffusion and iterative variants of NLM. These iterative variants in turn relate to our multiscale variant. As part of our evaluation, we conduct a simulation study making use of ground truth phantoms generated from clinical B-mode ultrasound images. We evaluate our method against a set of popular methods from the despeckling literature on both fine and coarse speckle noise. In terms of computational efficiency, our method outperforms the other considered methods. Quantitatively on simulations and on a tissue-mimicking phantom, our method is found to be competitive with the state-of-the-art. On clinical B-mode images, our method is found to effectively smooth speckle while preserving low-contrast and highly localized salient image detail.

Published

2017

8. Automated septum thickness measurement--a Kalman filter approach.

Author

Snare SR, Mjølstad OC, Orderud F, Dalen H, and Torp H

Subjects

Algorithms, Cardiomegaly pathology, Case-Control Studies, Diastole, Feasibility Studies, Heart Septum anatomy & histology, Heart Septum pathology, Humans, Ultrasonography methods, Automation, Cardiomegaly diagnostic imaging, Heart Septum diagnostic imaging, Models, Biological

Abstract

Interventricular septum thickness in end-diastole (IVSd) is one of the key parameters in cardiology. This paper presents a fast algorithm, suitable for pocket-sized ultrasound devices, for measurement of IVSd using 2D B-mode parasternal long axis images. The algorithm is based on a deformable model of the septum and the mitral valve. The model shape is estimated using an extended Kalman filter. A feasibility study using 32 unselected recordings is presented. The recordings originate from a database consisting of subjects from a normal healthy population. Five patients with suspected hypertrophy were included in the study. Reference B-mode measurements were made by two cardiologists. A paired t-test revealed a non-significant mean difference, compared to the B-mode reference, of (mean±SD) 0.14±1.36 mm (p=0.532). Pearson's correlation coefficient was 0.79 (p<0.001). The results are comparable to the variability between the two cardiologists, which was found to be 1.29±1.23 mm (p<0.001). The results indicate that the method has potential as a tool for rapid assessment of IVSd., (Copyright © 2011 Elsevier Ireland Ltd. All rights reserved.)

Published

2012

9. Real-time scan assistant for echocardiography.

Author

Snare SR, Torp H, Orderud F, and Haugen BO

Subjects

Algorithms, Computer Simulation, Computer Systems, Humans, User-Computer Interface, Echocardiography methods, Expert Systems, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Models, Cardiovascular, Pattern Recognition, Automated methods, Subtraction Technique

Abstract

A real-time scan assistant (SA) for use with echocardiography is presented. The motivation is to aid nonexpert users in capturing apical 4-chamber views (A4CH) during echocardiography. The algorithm is based on a parametric multi-chamber model of the A4CH view, updated in an extended Kalman filter framework. The regional model goodness-of-fit is used to calculate a score, which is provided to the user during acquisition, together with an icon (emoticon) indicating whether the current view is acceptable or not. The SA was implemented on a commercially available scanner. A feasibility test was performed using two healthy volunteers as models and 10 medical students acting as nonexpert users. The students examined the models on two occasions, separated more than four days in time. Half of the students used the SA during the first exam and no SA at the second exam. The other half used the opposite order. The recordings were later rated by a cardiologist. A Wilcoxon signed pair rank test revealed a statistically significant improvement when using SA. Nine cases were rated as poor without using the SA. In eight (89%) of these cases, view quality improved to acceptable when the SA was used.

Published

2012

10. Fast automatic measurement of mitral annulus excursion using a pocket-sized ultrasound system.

Author

Snare SR, Mjølstad OC, Orderud F, Haugen BO, and Torp H

Subjects

Equipment Design, Equipment Failure Analysis, Humans, Image Enhancement methods, Miniaturization, Reproducibility of Results, Sensitivity and Specificity, Algorithms, Echocardiography instrumentation, Elasticity Imaging Techniques instrumentation, Image Interpretation, Computer-Assisted methods, Mitral Valve diagnostic imaging, Pattern Recognition, Automated methods

Abstract

We present a fast, automatic method for mitral annulus excursion measurement using pocket-sized ultrasound (PSU). The motivation is to provide PSU users with a rapid measurement of cardiac systolic function. The algorithm combines low-frame-rate tolerance, computational efficiency and automation in a novel way. The method uses a speckle-tracking scheme, initialized and constrained by a deformable model. A feasibility study using 30 apical four-chamber PSU recordings from an unselected patient population revealed an error of (mean ± SD) -1.80 ± 1.96 mm, p < 0.001, when compared with manual anatomic m-mode analysis using laptop scanner data. When only septal side excursion was measured, the mean error was -0.27 ± 1.89 mm, p < 0.001. The accuracy is comparable with previously reported results using semiautomatic methods and full-size scanners. The computation time of 3.7 ms/frame on a laptop computer suggests that a real-time implementation on a PSU device is feasible., (Copyright © 2011 World Federation for Ultrasound in Medicine & Biology. Published by Elsevier Inc. All rights reserved.)

Published

2011

11. Echocardiography without electrocardiogram.

Author

Aase SA, Snare SR, Dalen H, Støylen A, Orderud F, and Torp H

Subjects

Adult, Aged, Aged, 80 and over, Electrocardiography, Female, Heart Diseases physiopathology, Humans, Image Processing, Computer-Assisted, Male, Middle Aged, Signal Processing, Computer-Assisted, Algorithms, Echocardiography methods, Heart Diseases diagnostic imaging

Abstract

Aims: automatic detection of the QRS complex on electrocardiogram (ECG) is used on cardiac ultrasound scanners to separate ultrasound image series into cardiac cycles for playback and storage. On small hand-held scanners it is unpractical to connect ECG cables. We therefore aim to do automatic cardiac cycle separation using apical B-mode ultrasound images., Methods and Results: cardiac cycle length is estimated by cyclicity analysis of B-mode intensities. To determine a cycle start estimate near QRS, a deformable model is fitted to the left ventricle in real-time. The model is used to initialize and constrain a speckle tracker positioned near the mitral annulus. In the displacement curve generated by the speckle tracker, a time point near maximum distance from the probe is detected as a cardiac cycle start estimate. Validation against ECG was done on 233 recordings from normal subjects and 46 recordings from subjects with coronary pathology. Several test cases were run for each recording to emulate B-mode series starting at all time points in the cardiac cycle. Totally, 11 886 test cases were run. Cycle length estimation was feasible in 98% of normal subject cases and 91% of pathology cases. Median difference in cycle length by ECG was 0 and -3 ms, respectively. Cycle start estimation was feasible in 90% of normal subject cases and 77% of pathology cases. Median difference to cycle start by ECG was 62 and 76 ms, respectively., Conclusion: apical B-mode series can automatically be separated into cardiac cycles without using ECG.

Published

2011