Continuous haemodynamic monitoring during exercise in patients with pulmonary hypertension

Hemodynamic monitoring in heart failure and pulmonary hypertension: From analog tracings to the digital age

Hemodynamic monitoring has long formed the cornerstone of heart failure (HF) and pulmonary hypertension diagnosis and management. We review the long history of invasive hemodynamic monitors initially using pulmonary artery (PA) pressure catheters in the hospital setting, to evaluating the utility of a number of implantable devices that can allow for ambulatory determination of intracardiac pressures. Although the use of indwelling PA catheters has fallen out of favor in a number of settings, implantable devices have afforded clinicians an opportunity for objective determination of a patient’s volume status and pulmonary pressures. Some devices, such as the CardioMEMS and thoracic impedance monitors present as part of implantable cardiac defibrillators, are supported by a body of evidence which show the potential to reduce HF related morbidity and have received regulatory approval, whereas other devices have failed to show benefit and, in some cases, harm. Clearly these devices can convey a considerable amount of information and clinicians should start to familiarize themselves with their use and expect further development and refinement in the future.

Validation of Cardiac Output as Reported by a Permanently Implanted Wireless Sensor

The CardioMEMS heart failure (HF) system was tested for cardiac output (CO) measurement accuracy using an in vitro mock circulatory system. A software algorithm calculates CO based on analysis of the pressure waveform as measured from the pulmonary artery, where the CardioMEMS system resides. Calculated CO was compared to that from reference flow probe in the circulatory system model. CO measurements were compared over a clinically relevant range of stroke volumes and heart rates with normal, pulmonary hypertension (PH), decompensated left heart failure (DLHF), and combined DHLF + PH hemodynamic conditions. The CardioMEMS CO exhibited minimal fixed and proportional bias.

Hemodynamic ranges during daily activities and exercise testing in patients with pulmonary arterial hypertension

BACKGROUND

In patients with pulmonary arterial hypertension (PAH) the relationship between hemodynamic impairment experienced during daily activity and that during exercise testing is not known.

METHODS AND RESULTS

Ten PAH patients received an implantable hemodynamic monitor that continuously recorded and stored right ventricular systolic (RVSP) and mean pulmonary arterial (MPAP) pressures. Before starting a new PAH treatment (baseline) and after 12 weeks on treatment, a 6-minute walk test (6MWT) and a maximal walk test (MAXWT) were performed. Exercise pressure range was measured as the difference between rest before exercise and maximal pressure during 6MWT or MAXWT. Ambulatory range (AMB) was measured as the difference between the lowest (4th percentile) and highest (96th percentile) values recorded over 24 hours. One week of AMBs were averaged for each patient before each exercise test. Mean age was 54 ±18 years, 9 were female, and all were in World Health Organization functional class III. At baseline, RVSP and MPAP increased, respectively, 136 ± 49% and 164 ± 49% during AMB, 63 ± 26% and 79 ± 30% during MAXWT, and 59 ± 32% and 69 ± 33% during 6MWT. There was no difference in pressure change at 12 weeks.

CONCLUSIONS

Changes in RV and PA pressures during exercise tests were relatively small compared with the range seen during ambulatory conditions.

Exercise physiology and pulmonary arterial hypertension

The lungs are the only organ that receives the entire cardiac output with every stroke. The pulmonary circulation is normally a high-flow, low-resistance, low-pressure system that carries blood into the pulmonary microcirculation. In pulmonary artery hypertension (PAH)vascular remodeling contributes to a sustained elevation of pulmonary vascular resistance (PVR) and pulmonary artery pressure (PAP) as a result of vascular remodeling characterized largely by vascular smooth muscle cell proliferation and medial hypertrophy, and endothelial cell proliferation resulting in lumen obliteration. The loss of pulmonary arterial compliance and development of elevated PVR puts an excessive burden on the right ventricle due to the increased workload necessary to overcome the downstream pressure, ultimately leading to right-sided heart failure. The functional status of the pulmonary circulation and the levels of PVR and PAP ultimately determine the outcome of patients with PAH. Study of the pressure-flow relationships in the pulmonary vascular bed will provide an improved appreciation of the pathophysiology of pulmonary hypertension.

Exercise in Pulmonary Hypertension

In healthy subjects, exercise causes a complex cardiovascular and ventilatory response that allows for a 20-fold increase of oxygen consumption as compared to rest. In pulmonary hypertension (PH) this response is very much limited by a restriction of the maximum cardiac output (CO). This restriction is caused by a massively increased afterload of the right ventricle (RV) despite an adaptation that doubles right ventricular contractility as compared to normal controls.1

Pulmonary Vascular Response Patterns to Exercise: Is there a Role for Pulmonary Arterial Pressure Assessment during Exercise in the Post-Dana Point Era?

Pulmonary hypertension (PH) is often diagnosed late in its course when it purports a particularly poor prognosis. Exercise effectively unmasks early forms of several cardiopulmonary diseases but the role of performing pulmonary arterial pressure measurements during exercise in the evaluation of PH remains unclear. Whether pulmonary arterial pressure-flow relationships during exercise may provide a window into earlier diagnosis of functionally significant pulmonary arterial hypertension and left ventricular dysfunction,¹ or add incrementally to our armentarium of diagnostic tests and prognostic indicators in PH, is the topic of active ongoing investigation. Evidence is emerging that abnormal pulmonary arterial pressure response patterns to exercise, when properly indexed to increased blood flow, may help to identify early forms of heart failure and pulmonary arterial hypertension. This article will discuss approaches to performing hemodynamic measurements during exercise as well as the potential clinical utility of identifying normal and abnormal pulmonary vascular response patterns to exercise.

Exercise-induced pulmonary arterial hypertension

BACKGROUND

The clinical relevance of exercise-induced pulmonary arterial hypertension (PAH) is uncertain, and its existence has never been well studied by direct measurements of central hemodynamics. Using invasive cardiopulmonary exercise testing, we hypothesized that exercise-induced PAH represents a symptomatic stage of PAH, physiologically intermediate between resting pulmonary arterial hypertension and normal.

METHODS AND RESULTS

A total of 406 consecutive clinically indicated cardiopulmonary exercise tests with radial and pulmonary arterial catheters and radionuclide ventriculographic scanning were analyzed. The invasive hemodynamic phenotype of exercise-induced PAH (n=78) was compared with resting PAH (n=15) and normals (n=16). Log-log plots of mean pulmonary artery pressure versus oxygen uptake (V(.)o(2)) were obtained, and a "join-point" for a least residual sum of squares for 2 straight-line segments (slopes m1, m2) was determined; m2<m1="plateau," and m2>m1="takeoff" pattern. At maximum exercise, V(.)o(2) (55.8+/-20.3% versus 66.5+/-16.3% versus 91.7+/-13.7% predicted) was lowest in resting PAH, intermediate in exercise-induced PAH, and highest in normals, whereas mean pulmonary artery pressure (48.4+/-11.1 versus 36.6+/-5.7 versus 27.4+3.7 mm Hg) and pulmonary vascular resistance (294+/-158 versus 161+/-60 versus 62+/-20 dyne x s x cm(-5), respectively; P<0.05) followed an opposite pattern. An exercise-induced PAH plateau (n=32) was associated with lower o(2)max (60.6+/-15.1% versus 72.0+/-16.1% predicted) and maximum cardiac output (78.2+/-17.1% versus 87.8+/-18.3% predicted) and a higher resting pulmonary vascular resistance (247+/-101 versus 199+/-56 dyne x s x cm(-5); P<0.05) than takeoff (n=40). The plateau pattern was most common in resting PAH, and the takeoff pattern was present in nearly all normals.

CONCLUSIONS

Exercise-induced PAH is an early, mild, and clinically relevant phase of the PAH spectrum.

Right Ventricular Pressure Waveform and Wave Reflection Analysis in Patients With Pulmonary Arterial Hypertension

BACKGROUND

Cardiac index is an important determinant of outcome in patients with idiopathic pulmonary artery hypertension (IPAH). An implantable hemodynamic monitor (IHM) [Chronicle; Medtronic; Minneapolis, MN; a system limited to investigational use only] that records right ventricular (RV) pressure waveforms continuously may increase our understanding of IPAH and improve therapeutic selections and outcomes. The aim of this study was to investigate whether the RV pressure waveform utilizing an IHM can be used to estimate the magnitude of pressure wave reflection and cardiac index in patients with IPAH in acute settings.

METHODS

In eight patients with pulmonary arterial hypertension, RV pressure waveforms were recorded utilizing the IHM, and breath-by-breath cardiac index was recorded during acute IV epoprostenol infusion at 3, 6 and 9 ng/kg/min. Late systolic pressure augmentation and cardiac index were estimated using the RV pressure waveforms and correlated with direct measurement of cardiac index.

RESULTS

At baseline, the cardiac index was 2.1 +/- 0.2 L/min/m(2), total pulmonary resistance index was 38 +/- 2 Wood U/m(2), and RV systolic pressure was 92 +/- 4 mm Hg. Wave reflection accounted for 29 +/- 1 mm Hg of the RV systolic pressure. During epoprostenol infusion, total pulmonary resistance index and wave reflection decreased (- 15 +/- 4 Wood U/m(2), p < 0.001, and - 5 +/- 2 mm Hg, p < 0.05, respectively). The breath-by-breath cardiac index correlated with the RV pressure waveform cardiac index estimates (r(2) = 0.95).

CONCLUSIONS

RV pressure waveform analysis provides continuous hemodynamic assessments including cardiac index in acute settings. Once confirmed in long-term settings, this information may prove useful in optimizing a treatment regimen in patients with IPAH.