Influence of respiratory loading on left-ventricular function in cervical spinal cord injury.

Cervical spinal cord injury (C-SCI) negatively impacts cardiac and respiratory function. As the heart and lungs are linked via the pulmonary circuit these systems are interdependent. Here, we utilized inspiratory and expiratory loading to assess whether augmenting the respiratory pump improves left-ventricular (LV) filling and output in individuals with motor-complete C-SCI. We hypothesized LV end-diastolic volume (LVEDV) would increase and decrease with inspiratory and expiratory loading, respectively. Participants (C-SCI: 7M/1F, 35 ± 7 years; able-bodied: 7M/1F, 32 ± 6 years) were assessed under five conditions during 45° head-up tilt; unloaded, inspiratory loading with -10 and -20 cmH O oesophageal pressure (P ) on inspiration, and expiratory loading with +10 and +20 cmH O P on expiration. An oesophageal balloon catheter monitored P , and LV structure and function were assessed by echocardiography. In C-SCI only, (1) +20 cmH O reduced LVEDV vs. unloaded (81 ± 15 vs. 88 ± 11 ml, P = 0.006); (2) heart rate was higher during +20 cmH O compared to unloaded (P = 0.001) and +10 cmH O (P = 0.002); (3) cardiac output was higher during +20 cmH O than unloaded (P = 0.002); and (4) end-expiratory lung volume was higher during +20 cmH O vs. unloaded (63 ± 10 vs. 55 ± 13% total lung capacity, P = 0.003) but was unaffected by inspiratory loading. In both groups, -10 and -20 cmH O had no significant effect on LVEDV. These findings suggest greater expiratory positive pressure acutely impairs LV filling in C-SCI, potentially via impaired venous return, mediastinal constraint and/or direct ventricular interaction subsequent to dynamic hyperinflation. Inspiratory loading did not significantly improve LV function in C-SCI and neither inspiratory nor expiratory loading affected cardiac function or lung volumes in able-bodied participants. KEY POINTS: Cervical spinal cord injury (C-SCI) alters both the cardiac and the respiratory system, but little is known about how these systems interact following injury. Here, we manipulated inspiratory or expiratory intrathoracic pressure (ITP) to mechanistically test the role of the respiratory pump in circulatory function in highly trained individuals with C-SCI and an able-bodied reference group. In individuals with C-SCI, greater ITP during expiratory loading caused dynamic hyperinflation that was associated with impaired left-ventricular filling. More negative ITP during inspiratory loading did not significantly alter left-ventricular volumes in either group. Interventions that prevent dynamic hyperinflation and/or enhance the ability to generate expiratory pressures may help preserve left-ventricular filling in individuals with C-SCI.