- 1Scottish Pulmonary Vascular Unit, Level 1, Golden Jubilee National Hospital, Glasgow, UK
- 2Respiratory Laboratory, Gartnavel General Hospital, Glasgow, UK
- Correspondence to Dr Wai-Ting N Lee, Scottish Pulmonary Vascular Unit, Level 1, Golden Jubilee National Hospital, Agamemnon Street, Clydebank, Glasgow G81 4DY, UK;
Contributors All authors were involved in the drafting of the authors' response.
- Accepted 22 August 2011
- Published Online First 22 September 2011
- pulmonary embolism
- asbestos-induced lung disease
- lung physiology
- primary pulmonary hypertension
- COPD exacerbations
- interstitial fibrosis
- respiratory measurement
- sleep apnoea
We would like to thank Trinkmann et al for their comments1 on our paper, ‘Use of non-invasive haemodynamic measurements to detect treatment response in precapillary pulmonary hypertension’,2 and address the point raised regarding shunt correction. We are of the opinion that the in-built shunt correction algorithm in the inert gas rebreathing device may introduce measurement bias, as the assumptions made to correct for shunt flow may not be applicable to patients with pulmonary vascular disease. In the algorithm,3 cardiac output (CO) is derived from pulmonary blood flow (PBF), oxygen content in arterial blood (CaO2), oxygen content in pulmonary end-capillary blood (CcO2) and oxygen uptake (VO2) according to the formula CO=1/(1/PBF+(CaO2−CcO2)/VO2). The oxygen content of arterial blood and pulmonary end-capillary blood is calculated from the formulae CaO2=0.000139×haemoglobin concentration (Hb in g/dl)×SaO2 and CcO2=0.000139×Hb×ScO2 respectively, where SaO2 denotes arterial oxygen saturation measured by pulse oximetry and pulmonary end-capillary oxygen saturation (ScO2) is assumed to be 98%. However, ScO2 may not reach 98% in patients with pulmonary hypertension due to failure of oxygen equilibration in the alveoli combined with a low mixed venous saturation. As a result of the destruction of pulmonary capillary beds and consequently reduced pulmonary capillary blood volume, red cell transit through pulmonary capillaries is more rapid.4 This shortens the time available for oxygen diffusion to complete across the alveolar–capillary membranes, especially as PBF increases in response to exercise. This is compounded by systemic venous blood being more deoxygenated at the start of the equilibration process due to increased peripheral oxygen extraction in a low CO state associated with pulmonary hypertension. These two mechanisms contribute to resting arterial hypoxaemia and exercise desaturation commonly seen in pulmonary hypertension patients. Applying the shunt correction algorithm would overestimate CO, especially for exercise measurements. Therefore, we advocate the use of inert gas rebreathing PBF instead of derived CO in this patient group. As Trinkmann et al pointed out, other non-invasive techniques for measuring CO such as impedance cardiography and continuous-wave Doppler have the advantage of not requiring patient collaboration and may be more suitable for patients with advanced disease. However, they are not readily applicable during exercise and there are little clinical data on their use in patients with pulmonary hypertension.
Linked article 200867.
Competing interests None.
Patient consent Obtained.
Provenance and peer review Not commissioned; internally peer reviewed.