Ingår i Hjärtgruppen vid Albano
Publikationer
- Comparison between real‐time 3‐dimensional and 2‐dimensional biplane echocardiographic assessment of left atrial volumes in dogs with myxomatous mitral valve disease. Authors: Tidholm A, Bodegård-Westling A, Höglund K,, Häggström J . Ljungvall I. Vet Intern Med. 1-7. 2019.
- Prevalence of mitral valve regurgitation in 79 asymptomatic Norfolk terriers. Authors: Bodegård-Westling A, Tidholm A, Häggström J. J Vet Cardiol 2017.
- Left Atrial Ejection Fraction Assessed by Real-Time 3-Dimensional Echocardiography in Normal Dogs and Dogs with Myxomatous Mitral Valve Disease. Authors: Tidholm A, Höglund K, Häggström, Bodegard-Westling A, Ljungvall I. J Vet Intern Med 2013.
- Comparisons of 2- and 3-Dimensional Echocardiographic Methods for Estimation of Left Atrial Size in Dogs with and without Myxomatous Mitral Valve Disease. Authors: Tidholm A, Bodegård-Westling A, Höglund K, Ljungvall I, Häggström J. J Vet Intern Med, 25:1320–1327, 2011.
- Comparisons of 3-, 2-Dimensional, and M-Mode Echocardiographical Methods for Estimation of Left Chamber Volumes in Dogs With and Without Acquired Heart Disease. Authors: Tidholm A, Bodegård-Westling A, Höglund K, Ljungvall I, Häggström J. J Vet Intern Med, 1–7, 2010.
- Tissue Doppler and Strain Imaging in Dogs with Myxomatous Mitral Valve Disease in Different Stages of Congestive Heart Failure. Authors: Tidholm A, Höglund K, Ljungvall I, Bodegård-Westling A, Häggström J. J Vet Intern Med 23:1197–1207, 2009.
- Förmakstakykardi hos en engelsk bulldog. Författare: Bodegård-Westling A. Svensk Veterinärtidning, vol 1 29-31, 2007.
- Somatosensory areas engaged during discrimination of steady pressure, spring strength and kinaesthesia. Authors: Bodegård A, Geyer S, Grefkes C, Zilles K, Roland P. E. Human Brain Mapping, Vol. 20:2 p 103-115, 2003.
- Hierarchical processing of tactile shape in the human brain. Authors: Bodegård A, Geyer S, Grefkes C, Zilles K, Roland PE. Neuron. 2;31(2):317-28. 2001.
- Integration of microstructural and functional aspects of human somatosensory areas 3a, 3b, and 1 on the basis of a computerized brain atlas. Authors: Geyer S, Schleicher A, Schormann T, Mohlberg H, Bodegard A, Roland PE, Zilles K. Anat Embryol (Berl). 204(4):351-66, 2001.
- Object shape differences reflected by somatosensory cortical activation. Authors: Bodegård A, Ledberg A, Geyer S, Naito E, Zilles K and Roland PE. The Journal of Neuroscience, 20:RC51 (1-5), 2000.
- Somatosensory areas in man activated by moving stimuli. Cytoarchitectonic mapping and PET. Authors: Bodegård A, Geyer S, Naito E, Zilles K and Roland PE. NeuroReport, 11:187-191, 2000.
- Somatosensory stimulation produces no ipsilateral activations in primary somatosensory cortex. Authors: Bodegård A, Bengtsson S, Geyer S, Zilles K, Roland PE. Neuroimage, 11:S841 2000.
- Somatosensory stimulation of the glabrous skin decreases the rCBF in V1 and V2. Authors: Bodegård A, Amunts K, Zilles K, Roland PE. Soc. Neurosci. Abs. 25:270:2, 1999.
- PET and cytoarchitectonic mapping. Somatosensory areas activated due to moving stimuli. Authors: Bodegård A, Geyer S, Naito E, Roland PE. Neuroimage, 7:415, 1998.
- Differential activation of somatosensory areas depending on object shape. PET and cytoarchitectonic mapping. Authors: Bodegård A, Geyer S, Naito E, Roland PE. Neuroimage, 7:417, 1998.