P960 Response of alveolo-capillar membrane diffusion to mitral regurgitation in heart failure with reduced ejection fraction

Background

In HFrEF patients, high pulmonary vascular resistances (PVR) imply a combined increase of both pre- and post-capillary pressures, associated with worse outcome. Mitral regurgitation (MR) may play a role in this complex physiopathology. We sought to investigate MR impact on lung DLCO and pulmonary vascular hemodynamic in HFrEF patient.

Methods

27 HFrEF patients (age 69 ± 9; LV EF 34 ± 6) underwent right heart catheterization, rest and exercise echocardiography, right ventricle 3D assessment and lung alveolo-capillary membrane DLCO. We identified 2 subgroups divided by normal (<3 WU, n= 20) or abnormal (>3 WU, n = 7) PVR.

Results

Abnormal PVR patients showed increased pulmonary artery pressures and TPG, reduced CO and pulmonary artery compliance. Total DLCO was not significantly different between groups. The membrane component (Dm) and the alveolar volume (Va) were significantly reduced in abnormal PVR group, while the capillary volume (VC) showed a strong trend toward higher values. Abnormal PVR group had a very high percentage of moderate-to-severe MR. The TASPE/SPAP ratio and the circumferential component of RV systolic function were significantly reduced in abnormal PVR group.

Conclusion

The presence of severe MR is associated with alveolar-capillary membrane remodeling (lower Dm), worse hemodynamic profile (higher PA pressures, lower PA compliance and higher PA resistance) and worse right ventricle to pulmonary circulation coupling (lower TAPSE/SPAP and lower 3D RV circumferential EF) in this cohort of HFrEF patients. These results confirm the adequacy of using therapeutic strategies aimed to solve valvular disease.

P1515 Hemodynamic determinants of tricuspid annular pulmonary systolic excursion (TAPSE)/ systolic pulmonary arterial pressure (SPAP) ratio in Heart Failure with reduced Ejection Fraction

Background

the TAPSE/SPAP ratio has gained a role as an easy-to-use surrogate of right ventricle-to-pulmonary circulation (RV-PC) coupling, showing a strong prognostic significance in heart failure (HF) patients. The hemodynamic determinants of TAPSE/SPAP ratio, as assessed by invasive approach, have not been fully clarified.

Aim

To identify the right heart hemodynamic variables correlated with TAPSE/SPAP in a HF with reduced EF (HFrEF) cohort, both at rest and during exercise.

Methods

30 HFrEF patients (age 68 ± 10 years LV EF 28 ± 7) underwent to rest and exercise echocardiography and performed right heart catheterization within 24 hours. Bivariate correlations between TAPSE/SPAP ratio (at rest and during exercise), right heart hemodynamic variables, RV systolic function and NTproBNP have been explored.

Results

TAPSE/SPAP ratio at rest showed a moderate correlation with pulmonary artery wedge pressure (PAWP: r= 0.441; p= 0.039), pulmonary artery pressures (PAP systolic: r = 0.481; p= 0.026; PAP diastolic: r= 0.434; p= 0.043; mPAP: r= 0.476; p= 0.025), pulmonary vascular resistance and compliance (r= 0.475; p= 0.041). A stronger correlation was identified with right atrial (RAP systolic: r= 0.586; p= 0.017; RAP diastolic: r= 0.681; p= 0.006) and right ventricular pressures- in particular diastolic ones (RVP systolic: r= 0.584; p= 0.004; RAP diastolic: r= 0.652; p= 0.002). No significant correlation with NTproBNP and RV 3D EF emerged. Exercise TAPSE/SPAP ratio significantly correlated with right atrium (RAP systolic: r= 0.564; p= 0.036) and right ventricle systolic pressures only (RVP systolic: r= 0.789; p< 0.001).

Conclusions

TAPSE/SPAP ratio at rest showed a stronger correlation with invasively derived diastolic right heart pressure rather than pulmonary vascular bed pressures. A similar correlation was also observed for exercise TAPSE/SPAP ratio. This tight correlation with RV, rather than with vascular pressures, supports the significance of this ratio as a marker of RV adaptation to vascular overload.

P1410 Right ventricle to pulmonary circulation coupling is primarily defined by the circumferential right ventricle function

Background

Right ventricle to pulmonary circulation (RV-PC) coupling plays a pivotal role during the physical effort. The RV-PC uncoupling can be easily identified by the TAPSE/SPAP ratio, a prognostic marker based on RV longitudinal function and its afterload (SPAP).We sought to explore the relationship between the functional capacity (peak VO2 and VE/VCO2) and the RV-PC coupling, using both a standard and 3D-based echocardiographic assessment of RV.

Methods

eighty-seven patients (age 72 ± 10 years; LV EF 53 ± 15%) underwent rest echocardiography with 3D RV assessment and cardiopulmonary exercise test. RV EF was measured using the 4D RV TomTec software. The 3D mesh of the RV model was post-processed using a custom developed software. This provided longitudinal (EFlong) and circumferential (EFcirc) components of EF. RV-PC coupling was assessed with the TAPSE/SPAP ratio and with similar parameters obtained by using 3D components of RV systolic function over SPAP (EF/SPAP, EFlong/SPAP and EFcirc/SPAP ratio). All variables were correlated with peakVO2 and VE/VCO2.

Results

Correlations between peakVO2 and TAPSE (0.409, p = 0.006), SPAP (-0.597, p < 0.001), RV EF (0.555, p < 0.001), RV EFlong (0.327, p = 0.03), RV EFcirc (0.587, p < 0.001) were modest, while TAPSE/SPAP (0.641, p < 0.001), EF/SPAP (0.751, p < 0.001), EFlong/SPAP (0.610, p < 0.001) and EFcirc/SPAP (0.775, p < 0.001) showed stronger correlations. VE/VCO2 showed a similar relationships although the correlations were weaker [TAPSE (-0.523, p <0.001), SPAP (0.617, p < 0.001), RV EF (-0.412, p = 0.006), RV EFlong (-0.232, p = 0.129), RV EFcirc (-0.454, p = 0.002), TAPSE/SPAP (-0.561, p < 0.001), EF/SPAP (-0.516, p = 0.001), EFlong/SPAP (-0.429, p = 0.008) and EFcirc/SPAP (-0.541, p < 0.001)].

Conclusions

RV-PC coupling is associated with both peak VO2 and VE/VCO2. The use of 3D-derived markers of RV-PC coupling showed a better correlation with the peak VO2, while there were no differences for VE/VCO2. The circumferential component of RV systolic function seems to emerge as a dominant determinant of RV-PC coupling, as well as of functional capacity.

P3549Impact of mitral regurgitation on alveolo-capillar membrane diffusion: an hemodynamic and functional study

Background

In HFrEF patients, high pulmonary vascular resistances (PVR) reflect a combined increase of pre- and post-capillary pressures, associated with worse outcome. Mitral regurgitation (MR) may play a role in this complex physiopathology. We sought to investigate MR impact on lung DLCO and pulmonary vascular hemodynamic in HFrEF patient.

Methods

22 HFrEF patients (age 67±11; LV EF) underwent right heart catheterization, rest and exercise echocardiography, right ventricle 3D assessment and lung alveolo-capillary membrane DLCO. We identified 2 subgroups according to normal (<3 WU, n=17) or abnormal (>3 WU, n=5) PVR.

Results

Abnormal PVR patients showed increased pulmonary artery pressures and TPG, reduced CO and pulmonary artery compliance. Total DLCO was not significantly different between groups. The membrane component (Dm) and the alveolar volume (Va) were significantly reduced in abnormal PVR group, while the capillary volume (VC) showed a strong trend toward higher values. Abnormal PVR group had a very high percentage of moderate-to-severe MR. The TASPE/SPAP ratio and the circumferential component of RV systolic function were significantly reduced in abnormal PVR group.

Normal PVR (n=17) Abnormal PVR (n=5) p NTproBNP, ng/L 3021±2527 7023±8785 0.55 MR moderate-to-severe, n (%) 3 (19%) 4 (80%) 0.025 TAPSE/SPAP, mm/mmHg 0.4761±0.1695 0.2956±0.0739 0.019 3D RV global EF, % 40.616±9.350 29.486±14.062 0.119 3D RV longitudinal EF, % 15.611±7.773 12.086±9.694 0.497 3D RV circumferential EF, % 31.0567±6.5744 21.1746±11.5823 0.019 Lung diffusion of CO (DLCO), ml/min/mmHg 19.021±4.643 15.233±1.761 0.197 Dm ml/min/mmHg 26.8±8.2 17.8±4.1 0.047 VC, ml 110±77 247±152 0.121

Graphics

Conclusion

The presence of severe MR, in this cohort of HFrEF patients, is associated with alveolar-capillary membrane remodeling (lower Dm), worse hemodynamic profile (higher PA pressures, lower PA compliance and higher PA resistance) and worse right ventricle to pulmonary circulation coupling (lower TAPSE/SPAP and lower 3D RV circumferential EF), confirming the use of therapeutic strategies aimed at correction of valvular disease.

4306Hemodynamic correlates of tricuspid annular pulmonary systolic excursion (TAPSE)/systolic pulmonary arterial pressure (SPAP) ratio in heart failure with reduced ejection fraction

Background

The TAPSE/SPAP ratio has gained a role as an easy-to-use surrogate of right ventricle-to-pulmonary circulation (RV-PC) coupling, showing a strong prognostic significance in heart failure (HF) patients. The hemodynamic determinants of TAPSE/SPAP ratio, as assessed by invasive approach, have not been fully elucidated.

Aim

To identify the right heart hemodynamic variables correlated with TAPSE/SPAP in a HF with reduced EF (HFrEF) cohort, at rest and during exercise.

Methods

24 HFrEF patients (age 67±11 years LV EF 27±7) underwent to rest and exercise echocardiography and performed right heart catheterization within 24 hours. Bivariate correlations between TAPSE/SPAP ratio (at rest and exercise), right heart hemodynamic variables, RV systolic function and NTproBNP have been explored.

Results

TAPSE/SPAP ratio at rest showed a moderate correlation with pulmonary artery wedge pressure (PAWP: r=0.432; p=0.039), pulmonary artery pressures (PAP systolic: r=0.474; p=0.026; PAP diastolic: r=0.434; p=0.043; mPAP: r=0.476; p=0.025), pulmonary vascular resistance and compliance (r=0.475; p=0.041), while a stronger correlation was identified with right atrial (RAP systolic: r=0.571; p=0.017; RAP diastolic: r=0.675; p=0.006) and right ventricular pressures- in particular diastolic ones (RVP systolic: r=0.584; p=0.004; RAP diastolic: r=0.646; p=0.002). No significant correlation was found with NTproBNP and RV 3D EF. Exercise TAPSE/SPAP ratio significantly correlated with right atrium (RAP systolic: r=0.564; p=0.036) and right ventricle systolic pressures only (RVP systolic: r=0.765; p<0.001).

TAPSE/PAPS correlation graphics

Conclusions

TAPSE/SPAP ratio at rest showed a stronger correlation with invasively derived diastolic right heart pressure rather than pulmonary vascular bed pressures. A similar correlation was also observed for exercise TAPSE/SPAP ratio. This tight correlation with RV, rather than vascular pressures, supports the significance of the ratio as a marker of RV adaptation to vascular overload.

6068Role of the circumferential right ventricle function in the right ventricle to pulmonary circulation coupling and functional capacity

Background

Right ventricle to pulmonary circulation (RV-PC) coupling plays a central role during the physical effort. The RV-PC uncoupling can be easily identified by the TAPSE/SPAP ratio, a prognostic marker based on RV longitudinal function and its afterload (SPAP).We sought to explore the relationship between the functional capacity (peak VO2 and VE/VCO2) and the RV-PC coupling, using both a standard and 3D-based echocardiographic assessment of RV.

Methods

Forty-four patients (age 71±10 years; LV EF 54±15%) received rest echocardiography with 3D RV assessment and cardiopulmonary exercise test. RV EF was measured using the 4D RV TomTec software. The 3D mesh of the RV model was post-processed using a custom developed software providing longitudinal (EFlong) and circumferential (EFcirc) components of EF. RV-PC coupling was assessed with the TAPSE/SPAP ratio and with similar parameters obtained using 3D components of RV systolic function over SPAP (EF/SPAP, EFlong/SPAP and EFcirc/SPAP ratio). All variables were correlated with peakVO2 and VE/VCO2.

Results

Correlations between peakVO2 and TAPSE (0.409, p=0.006), SPAP (−0.597, p<0.001), RV EF (0.555, p<0.001), RV EFlong (0.327, p=0.03), RV EFcirc (0.587, p<0.001) were modest, while TAPSE/SPAP (0.641, p<0.001), EF/SPAP (0.751, p<0.001), EFlong/SPAP (0.610, p<0.001) and EFcirc/SPAP (0.775, p<0.001) showed stronger correlations. VE/VCO2 showed a similar relationships although the correlations were weaker [TAPSE (−0.531, p<0.001), SPAP (0.614, p<0.001), RV EF (−0.409, p=0.006), RV EFlong (−0.232, p=0.129), RV EFcirc (−0.454, p=0.002), TAPSE/SPAP (−0.561, p<0.001), EF/SPAP (−0.516, p=0.001), EFlong/SPAP (−0.417, p=0.008) and EFcirc/SPAP (−0.534, p<0.001)].

Conclusions

RV-PC coupling is associated with both peak VO2 and VE/VCO2. The use of 3D-derived markers of RV-PC coupling showed a better correlation with the peak VO2 while there were no differences for VE/VCO2. The circumferential component of RV systolic function seems to emerge as a dominant determinant of RV-PC coupling, as well of functional capacity.