Enhance extemal counterpulsation (ECP) procedure has exhbited itself to be an effective therapy for the m anagem entof ischem ic card iovascu lar diseases, However, considering that EECP significantly increases the...Enhance extemal counterpulsation (ECP) procedure has exhbited itself to be an effective therapy for the m anagem entof ischem ic card iovascu lar diseases, However, considering that EECP significantly increases the acute diastolic pressure, whether it will intervene in the chronic progression of advanced plaque causing great concern in clilical applkation, but yet rein ains elusive presently. In the current paper, a flu id-structure interface (FSI) num erical model of artery with p iaque corn ponent w as developed based on in vivo hem odynam ic m easurem entperfotm ed h a porcine model, to caku late the m echanical stresses of the plaque before and during EECP, and h lum to assess the potential effects of long-term EECP treatm ent on plaque progression. The resu Its show that E E C P augm ented the wall shear stress (WSS) and plaque w all stress (PWS) over the card lac cycles, aswell as the spacial oscillatory of W SS (WSSG ). Durhg EECP treatm ent, the PW S level respectively raised 6.82% and 6.07% in two simulation cases. The currentpilot study suggests that E E C P treatm entre ay p lay a positive effect on inh biting the conthued plaque progression by hcreashg the PW S level over the card iac cycles. Meanwhile, the plaque morphology should be taken into consideration while m aking patient- specific plan for Ion g- term E E C P treatment in clinic.展开更多
基金Key Clinical Project from the Ministry of Heatthgrant number:25400+1 种基金National Natural Science Foundation of Chinagrant number:81170272
文摘Enhance extemal counterpulsation (ECP) procedure has exhbited itself to be an effective therapy for the m anagem entof ischem ic card iovascu lar diseases, However, considering that EECP significantly increases the acute diastolic pressure, whether it will intervene in the chronic progression of advanced plaque causing great concern in clilical applkation, but yet rein ains elusive presently. In the current paper, a flu id-structure interface (FSI) num erical model of artery with p iaque corn ponent w as developed based on in vivo hem odynam ic m easurem entperfotm ed h a porcine model, to caku late the m echanical stresses of the plaque before and during EECP, and h lum to assess the potential effects of long-term EECP treatm ent on plaque progression. The resu Its show that E E C P augm ented the wall shear stress (WSS) and plaque w all stress (PWS) over the card lac cycles, aswell as the spacial oscillatory of W SS (WSSG ). Durhg EECP treatm ent, the PW S level respectively raised 6.82% and 6.07% in two simulation cases. The currentpilot study suggests that E E C P treatm entre ay p lay a positive effect on inh biting the conthued plaque progression by hcreashg the PW S level over the card iac cycles. Meanwhile, the plaque morphology should be taken into consideration while m aking patient- specific plan for Ion g- term E E C P treatment in clinic.
