APA

Kousera C. A., Nijjer S., Torii R., Petraco R., Sen S., Foin N., Hughes A. D., Francis D. P. P., Xu X. Y. & Davies J. E. (20150402). Patient-specific coronary stenoses can be modeled using a combination of OCT and flow velocities to accurately predict hyperemic pressure gradients. : IEEE transactions on bio-medical engineering.

Chicago

Kousera C A, Nijjer S, Torii R, Petraco R, Sen S, Foin N, Hughes A D, Francis D P P, Xu X Y and Davies J E. 20150402. Patient-specific coronary stenoses can be modeled using a combination of OCT and flow velocities to accurately predict hyperemic pressure gradients. : IEEE transactions on bio-medical engineering.

Harvard

Kousera C. A., Nijjer S., Torii R., Petraco R., Sen S., Foin N., Hughes A. D., Francis D. P. P., Xu X. Y. and Davies J. E. (20150402). Patient-specific coronary stenoses can be modeled using a combination of OCT and flow velocities to accurately predict hyperemic pressure gradients. : IEEE transactions on bio-medical engineering.

MLA

Kousera C A, Nijjer S, Torii R, Petraco R, Sen S, Foin N, Hughes A D, Francis D P P, Xu X Y and Davies J E. Patient-specific coronary stenoses can be modeled using a combination of OCT and flow velocities to accurately predict hyperemic pressure gradients. : IEEE transactions on bio-medical engineering. 20150402.