Phrenic nerve stimulation increases human diaphragm fiber force after cardiothoracic surgery.

To the Editor: Mechanical ventilation (MV) causes diaphragm inactivity and unloading, and this quiescence results in ventilator-induced diaphragm dysfunction (VIDD). VIDD is characterized by oxidative stress, muscle atrophy, and decreases in diaphragm fiber force, as documented in both animal models and humans (1). VIDD is a major clinical problem because the ensuing decreased ability to develop inspiratory pressure will contribute to the difficulties in weaning patients from MV. During open-chest cardiothoracic surgery in humans, a rapid form of VIDD has been observed, with 20–30% depression of diaphragm force occurring within 2 hours of commencing MV (2). Extensive experiments establishing a cause-and-effect relationship for the mechanisms leading to VIDD in animals are available (reviewed in Reference 3), but interventions in humans are scant. Recently, intermittent phrenic nerve stimulation during MV has emerged as a potential VIDD countermeasure (4, 5). Specifically, hemidiaphragm stimulation during MV resulted in greater type 2 muscle fiber area in sheep (4), improved contractile properties in rats (6), and higher mitochondrial respiration rates in humans undergoing cardiothoracic surgery (5). In this preliminary study, we examined whether intermittent phrenic nerve stimulation during cardiothoracic surgery prevents diaphragm fiber contractile function impairment. We obtained diaphragm biopsies from four patients undergoing sternotomy for elective cardiothoracic surgical procedures (Table 1). The University of Florida Institutional Review Board approved the protocol, and participants gave written consent. Patients received nondepolarizing neuromuscular blockers during intubation, but none during surgery. The experimental intervention consisted of unilateral of phrenic nerve stimulation using an external cardiac pacemaker (Medtronic 5388; Medtronic, Minneapolis, MN) with temporary wire electrodes (AE Medical Corp., Farmingdale, NJ). The stimulation parameters and protocol were reported previously (5) and are given in Table 1. Briefly, stimulations were conducted every 30 minutes as soon as the phrenic nerve and diaphragm were exposed. The contralateral hemidiaphragm served as intrasubject control. There were no complications from the stimulations or biopsies. All participants were successfully extubated on the first attempt. Table 1. Patient Characteristics and Stimulation Parameters Muscle biopsies from each hemidiaphragm were either frozen immediately and later prepared for protein immunoblotting (see online supplement) or placed in an ice-cold solution containing low calcium and high ATP concentration (“relaxing” solution) (7), processed for chemical permeabilization (7), and stored at −20°C in relaxing solution (50% glycerol) until measurements of contractile properties (≤3 wk of surgery). We carefully isolated single fibers from diaphragm bundles in ice-cold relaxing solution and clamped the fibers to a force transducer and length controller for mechanical testing at 15°C, using calcium activation (7). We discarded fibers with sarcomere length greater than 2.65 μm under slack conditions on final mounting on the mechanics apparatus. This was the only exclusion criterion we adopted to avoid selectively studying “healthy” fibers. In our hands, slack sarcomere length greater than 2.65 μm is a sign of damage imposed during isolation of the fiber. We studied fibers from each hemidiaphragm (stimulated or control) in all subjects and determined fiber types using myosin heavy chain gel electrophoresis (8). Incidentally, the vast majority of fibers were type 2 (38 fibers); only four fibers were type 1 (three control, one stimulated). Hence, we report here only findings for type 2 fibers. These fibers account for approximately half of the diaphragm fiber composition (2). We analyzed the data from four patients with a varying number of fibers in each of the stimulated and control muscles, using a mixed effects model with random intercept for each individual and a fixed effect for group (stimulated or control), using the parametric bootstrap to assess statistical significance, as described by Faraway (9). This statistical approach takes into consideration the within-subject design in which different numbers of fibers are analyzed per subject in each condition. Specific force averaged 77 kN/m2 in control/inactive fibers compared with 100–150 kN/m2 reported in healthy active type 2 fibers [rodents (7), humans (2)]. Stimulated fibers elicited an approximately 30% greater specific force compared with the inactive fibers (P = 0.028; Figure 1). We found no differences between stimulated and control hemidiaphragms in other measures of isometric contractile properties (Figure 1). We also measured the abundance of protein carbonyls and ubiquitin conjugates (n = 3 patients), which, respectively, are general markers of oxidative damage and targeting for degradation by the ubiquitin-proteasome system. There was no difference between stimulated and control hemidiaphragms for protein carbonyls (control, 8.5 ± 2.8; stimulated, 9.2 ± 3.1) or ubiquitin conjugates (control, 2.3 ± 1.1; stimulated, 2.5 ± 1.0; Figures E1–E2 in the online supplement). Figure 1. Phrenic nerve stimulation increases diaphragm fiber force after cardiothoracic surgery. (A) Specific force versus pCa relationship for all fibers from control and stimulated hemidiaphragms. Specific force is absolute force (in kilonewtons) normalized ... Several mechanisms are involved in VIDD, including activation of proteolytic pathways, oxidative stress, impaired excitation–contraction coupling, and posttranslational modification of sarcomeric proteins. Our preliminary findings suggest that intermittent phrenic nerve stimulation preserves human diaphragm fiber contractile function, possibly by inhibiting proteolysis and/or posttranslational modification of sarcomeric proteins seen after MV (3, 10). However, the protection does not appear to be mediated by changes in protein carbonyls or ubiquitination. The resolution of specific cellular and molecular mechanisms will require a larger number of subjects and different analysis techniques. It is possible that indirect stretch imposed onto the control hemidiaphragm by stimulation of the treated side conferred some protection against VIDD (11). Therefore, our data may underestimate the benefits of intermittent phrenic nerve stimulation to diaphragm fiber function. However, our intrasubject design was sufficiently sensitive to detect significant differences in function that may be obscured by the large variability in an intersubject design resulting from factors such as age, sex, genetics, duration of surgery, and so on. We cannot determine whether a 30% increase in diaphragm fiber force is clinically relevant. Of note, an increase in inspiratory/diaphragm muscle strength elicited by inspiratory strength training is associated with greater weaning rate than standard care in chronic failure-to-wean patients (12). Phrenic nerve stimulation has been shown to increase the type 2 fiber cross-sectional area in sheep (4), mitochondrial respiration rates (5), and specific force in rats (6) and humans, as shown for the first time to our knowledge in the present study. These observations suggest that intermittent diaphragm activity during MV offers some protection against VIDD. Thus, intermittent diaphragm activity may ultimately prove to be a useful clinical strategy to prevent or attenuate VIDD in a subset of patients that has yet to be identified in larger trials.