Philip J McCall1, Alex Arthur2, Adam Glass2, David S Corcoran3, Alan Kirk4, Alistair Macfie5, John Payne6, Martin Johnson7, John Kinsella8, Benjamin G Shelley2. 1. Academic Unit of Anaesthesia, Pain, and Critical Care, University of Glasgow, Glasgow, United Kingdom; Department of Anaesthesia, Golden Jubilee National Hospital, Clydebank, United Kingdom. Electronic address: philipmccall@nhs.net. 2. Academic Unit of Anaesthesia, Pain, and Critical Care, University of Glasgow, Glasgow, United Kingdom; Department of Anaesthesia, Golden Jubilee National Hospital, Clydebank, United Kingdom. 3. Institute of Cardiovascular and Medical Sciences, University of Glasgow, Glasgow, United Kingdom; Department of Cardiology, Golden Jubilee National Hospital, Clydebank, United Kingdom. 4. Department of Thoracic Surgery, Golden Jubilee National Hospital, Clydebank, United Kingdom. 5. Department of Anaesthesia, Golden Jubilee National Hospital, Clydebank, United Kingdom. 6. National Advanced Heart Failure Service, Golden Jubilee National Hospital, Clydebank, United Kingdom. 7. Scottish Pulmonary Vascular Unit, Golden Jubilee National Hospital, Clydebank, United Kingdom. 8. Academic Unit of Anaesthesia, Pain, and Critical Care, University of Glasgow, Glasgow, United Kingdom.
Abstract
OBJECTIVES: Lung cancer is a leading cause of cancer death and in suitable cases the best chance of cure is offered by surgery. Lung resection is associated with significant postoperative cardiorespiratory morbidity, with dyspnea and reduced functional capacity as dominant features. These changes are poorly associated with deterioration in pulmonary function and a potential role of right ventricular (RV) dysfunction has been hypothesized. Cardiovascular magnetic resonance imaging is a reference method for noninvasive assessment of RV function and has not previously been applied to this population. METHODS: We used cardiovascular magnetic resonance imaging to assess the RV response to lung resection. Cardiovascular magnetic resonance imaging with volume and flow analysis was performed on 27 patients preoperatively, on postoperative day 2 and at 2 months. Left ventricular ejection fraction and RV ejection fraction, the ratio of stroke volume to end systolic volume, pulmonary artery acceleration time, and distensibility of main and branch pulmonary arteries were studied. RESULTS: Mean ± standard deviation RV ejection fraction deteriorated from 50.5% ± 6.9% preoperatively to 45.6% ± 4.5% on postoperative day 2 and remained depressed at 44.9% ± 7.7% by 2 months (P = .003). The ratio of stroke volume to end systolic volume deteriorated from median 1.0 (quartile 1, quartile 3: 0.9, 1.2) preoperatively to median 0.8 (quartile 1, quartile 3: 0.7, 1.0) on postoperative day 2 (P = .011). On postoperative day 2 there was a decrease in pulmonary artery acceleration time and operative pulmonary artery distensibility (P < .030 for both). There were no changes in left ventricular ejection fraction during the study period (P = .621). CONCLUSIONS: These findings suggest RV dysfunction occurs following lung resection and persists 2 months after surgery. The deterioration in the ratio of stroke volume to end systolic volume suggests a mismatch between afterload and contractility. There is an increase in indices of pulsatile afterload resulting from the operative pulmonary artery.
OBJECTIVES:Lung cancer is a leading cause of cancer death and in suitable cases the best chance of cure is offered by surgery. Lung resection is associated with significant postoperative cardiorespiratory morbidity, with dyspnea and reduced functional capacity as dominant features. These changes are poorly associated with deterioration in pulmonary function and a potential role of right ventricular (RV) dysfunction has been hypothesized. Cardiovascular magnetic resonance imaging is a reference method for noninvasive assessment of RV function and has not previously been applied to this population. METHODS: We used cardiovascular magnetic resonance imaging to assess the RV response to lung resection. Cardiovascular magnetic resonance imaging with volume and flow analysis was performed on 27 patients preoperatively, on postoperative day 2 and at 2 months. Left ventricular ejection fraction and RV ejection fraction, the ratio of stroke volume to end systolic volume, pulmonary artery acceleration time, and distensibility of main and branch pulmonary arteries were studied. RESULTS: Mean ± standard deviation RV ejection fraction deteriorated from 50.5% ± 6.9% preoperatively to 45.6% ± 4.5% on postoperative day 2 and remained depressed at 44.9% ± 7.7% by 2 months (P = .003). The ratio of stroke volume to end systolic volume deteriorated from median 1.0 (quartile 1, quartile 3: 0.9, 1.2) preoperatively to median 0.8 (quartile 1, quartile 3: 0.7, 1.0) on postoperative day 2 (P = .011). On postoperative day 2 there was a decrease in pulmonary artery acceleration time and operative pulmonary artery distensibility (P < .030 for both). There were no changes in left ventricular ejection fraction during the study period (P = .621). CONCLUSIONS: These findings suggest RV dysfunction occurs following lung resection and persists 2 months after surgery. The deterioration in the ratio of stroke volume to end systolic volume suggests a mismatch between afterload and contractility. There is an increase in indices of pulsatile afterload resulting from the operative pulmonary artery.