Since 2006, our preclinical and clinical trials have consistently demonstrated that XV Technology provides an unprecedented level of information on respiratory function.
Our ground-breaking work has been published in more than 80 scientific publications.
Studies include information about X-ray velocimetry and lung heterogeneity. Lung heterogeneity may be a key indicator of lung health.
Quantifying ventilation by X-ray velocimetry in healthy adults
Association of X-ray velocimetry (XV) ventilation analysis compared to spirometry
Functional imaging for assessing regional lung ventilation in preclinical and clinical research
Performance of CT:V Quantitative Ventilation Imaging Against PET Ventilation Imaging
Reyne, N. et al. Effect of elexacaftor-tezacaftor-ivacaftor on nasal potential difference and lung function in Phe508del rats.
Fouras, A. et al. Engineering Imaging: Using particle image velocimetry to see physiology in a new light.
Fouras, A. et al. The past, present, and future of x-ray technology for in vivo imaging of function and form.
Jamison, R. A. et al. Functional Imaging to Understand Biomechanics: A Critical Tool for the Study of Biology, Pathology and the Development of Pharmacological Solutions.
Dubsky, S. & Fouras, A. Imaging regional lung function: A critical tool for developing inhaled antimicrobial therapies.
Fouras, A. & Dubsky, S. The Role of Functional Lung Imaging in the Improvement of Pulmonary Drug Delivery.
Fouras, A. & Soria, J. Accuracy of out-of-plane vorticity measurements derived from in-plane velocity field data.
Fouras, A., Hourigan, K., Kawahashi, M. & Hirahara, H. An improved, free surface, topographic technique.
Fouras, A., Dusting, J. & Hourigan, K. A simple calibration technique for stereoscopic particle image velocimetry.
Fouras, A., Jacono, D. L. & Hourigan, K. Target-free Stereo PIV: a novel technique with inherent error estimation and improved accuracy.
Nguyen, C., Fouras, A. & Carberry, J. Control of the depth of correlation in micro-PIV using a novel post-processing method.
Irvine, S. C, et al. Phase retrieval for improved three-dimensional velocimetry of dynamic x-ray blood speckle.
Parsons, D. W. et al. High-resolution visualization of airspace structures in intact mice via synchrotron phase-contrast X-ray imaging (PCXI).
Nesbitt, W. S. et al. A shear gradientdependent platelet aggregation mechanism drives thrombus formation.
Fouras, A., et al. Volumetric correlation PIV: a new technique for 3D velocity vector field measurement.
Irvine, S. C., Paganin, D. et al. Phase retrieval for improved multi-dimensional velocimetric analysis of X-ray blood flow speckle patterns.
Fouras, A. et al. In-vivo Synchrotron PIV for the measurement of airway motion.
Nguyen, C. V., Fouras, A. & Carberry, J. Image Overlapping to Improve Micro PIV Accuracy.
Nguyen, C. V., Fouras, A. & Carberry, J. Improvement of measurement accuracy in micro PIV by image overlapping.
Kitchen, M. J. et al. A new design for high stability pressure-controlled ventilation for small animal lung imaging.
Irvine, S. C., Paganin, D. M., et al. Vector tomographic X-ray phase contrast velocimetry utilizing dynamic blood speckle.
Higgins, S. P., et al. Holographic correlation velocimetry.
Nguyen, C. V., Carberry, J. & Fouras, A. Volumetric-correlation PIV to measure particle concentration and velocity of microflows.
Samarage, C. R., Carberry, J., Hourigan, K. & Fouras, A. Optimisation of temporal averaging processes in PIV.
Thurgood, J. et al. Mapping cardiogenic oscillations using synchrotron-based phase contrast CT imaging.
