VENTILATORY LOAD CHARACTERISTICS DURING VENTILATORY MUSCLE TRAINING

The response of skeletal muscle to training is influenced by both the intensity and nature of the training stimulus. In this study we invest igated the characteristics of the ventilatory load applied to the vent ilatory muscles during several different modes of ventilatory muscle t raining. Patients with chronic obstructive pulmonary disease (COPD) pe rformed the following breathing maneuvers: (1) Unloaded hyperpnea (UH) , (2) resistive breathing through a fixed orifice (0.5 cm diameter) at frequencies of 15 and 30 breaths/min (RT15, RT30), (3) loaded breathi ng through a threshold valve set at 30% of the Pl(max) at frequencies of 15 and 30 breaths/min (TT15, TT30), and (4) repetitive maximal insp iratory maneuvers against a closed shutter (Pl(max)). During these man euvers we recorded airflow and pressures at the mouth and esophagus, a nd from these measurements we derived VE and the work of breathing (WO B), tension time index (TTI), and pressure time product (PTP). The VE during UH was significantly higher than all other modes (p < 0.01), wh ereas the Pes(max) was significantly lower during UH than during the r esistive and loaded maneuvers (p < 0.01). The WOB did not differ durin g UH, TT30, and RT30, but was significantly higher in all three modes than at TT15 and RT15 (p < 0.05). During RT30 the TTI was higher than during TT30, TT15, and RT15 (p < 0.05), whereas the TTI during UH was significantly lower than during other maneuvers (p < 0.01). As expecte d, the highest Pes(max) and PTP were found during the Pl(max) maneuver . These data show that important qualitative differences in ventilator y muscle loading can be achieved by means of different devices and bre athing strategies. It is possible to create tailored training regimens that range from pure pressure loads (Pl(max)) through combination flo w and pressure loads (TT30, RT30) to predominantly flow loads (UH). Be cause of the important principle of training specificity, consideratio n of these characteristics may be important in the design of ventilato ry muscle training protocols.