We examined the degree of ventilatory constraint in patients with a history
of chronic heart failure (CHF; n 11; mean a SE age, 62 +/- 4 years; cardia
c index [CI], 2.0 +/- 0.1; and ejection fraction [EF], 24 +/- 2%) and in co
ntrol subjects (CTLS; n = 8; age, 61 +/- 5 years; CI, 2.6 +/- 0.3) by plott
ing the tidal flow-volume responses to graded exercise in relationship to t
he maximal flow-volume envelope (MFVL). Inspiratory capacity (IC) maneuvers
were performed to follow changes in end-expiratory lung volume (EELV) duri
ng exercise, and the degree of expiratory flow limitation was assessed as t
he percent of the tidal volume (V-T) that met or exceeded the expiratory bo
undary of the MFVL. CHF patients had significantly (p < 0.05) reduced basel
ine pulmonary-function (FVC, 76 +/- 4%; FEV1, 78 +/- 4% predicted) relative
to CTLS (FVC, 99 +/- 4%; FEV1, 102 +/- 4% predicted). At peak exercise, ox
ygen consumption ((V) over dot (O2)) and minute ventilation ((V) over dot (
E)) vc ere lon er in CHF patients than in CTLS ((V) over dot (O2), 17 +/- 2
vs 32 +/- 2 mL/kg/min; (V) over dot (E), 56 +/- 4 vs 82 +/- 6 L/min, respe
ctively), whereas (V) over dot (E)/carbon dioxide output was higher (42 +/-
4 vs 29 +/- 5), In CTLS, EELV initially decreased with light exercise, but
increased as (V) over dot (E) and expiratory flow limitation increased. In
contrast, the EELV in patients with CHF remained near residual volume (RV)
throughout exercise, despite increasing flow limitation. At peak exercise,
IC averaged 91 +/- 3% and 79 +/- 4% (p < 0.05) of the FVC in CHF patients
and CTLS, respectively, and flow limitation was present over > 45% of the V
-T in CHF patients vs < 25% in CTLS (despite the higher (V) over dot (E) in
CTLS), The least fit and most symptomatic CHF patients demonstrated the lo
west EELV, the greatest degree of flow limitation, and a limited response t
o increased inspired carbon dioxide during exercise, all consistent with (V
) over dot (E) constraint. We conclude that patients with CHF commonly brea
the near RV during exertion and experience expiratory flow limitation. This
results in (V) over dot (E) constraint and may contribute to exertional in
tolerance.