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Volume-related and volume-independent effects of posture on esophageal and transpulmonary pressures in healthy subjects

¹Department of Anesthesia and Critical Care and ²Division of Pulmonary and Critical Care Medicine, Beth Israel Deaconess Medical Center, Boston, Massachusetts

Submitted 13 June 2005 ; accepted in final form 16 November 2005

	ABSTRACT

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Ventilator management decisions in acute lung injury could be better informed with knowledge of the patient's transpulmonary pressure, which can be estimated using measurements of esophageal pressure. Esophageal manometry is seldom used for this, however, in part because of a presumed postural artifact in the supine position. Here, we characterize the magnitude and variability of postural effects on esophageal pressure in healthy subjects to better assess its significance in patients with acute lung injury. We measured the posture-related changes in relaxation volume and total lung capacity in 10 healthy subjects in four postures: upright, supine, prone, and left lateral decubitus. Then, in the same subjects, we measured static pressure-volume characteristics of the lung over a wide range of lung volumes in each posture by using an esophageal balloon catheter. Transpulmonary pressure during relaxation (PL_rel) averaged 3.7 (SD 2.0) cmH₂O upright and –3.3 (SD 3.2) cmH₂O supine. Approximately 58% of the decrease in PL_rel between the upright and supine postures was due to a corresponding decrease in relaxation volume. The remaining 2.9-cmH₂O difference is consistent with reported values of a presumed postural artifact. Relaxation volumes and pressures in prone and lateral postures were intermediate. To correct estimated transpulmonary pressure for the effect of lying supine, we suggest adding 3 cmH₂O (95% confidence interval: –1 to +7 cmH₂O). We conclude that postural differences in estimated transpulmonary pressure at a given lung volume are small compared with the substantial range of PL_rel in patients with acute lung injury.

respiratory mechanics; chest wall; esophageal balloon; supine posture

Before interpreting Pes in patients with acute lung injury, we sought to fully characterize the magnitude and variability of postural effects on Pes in normal subjects and to determine the contribution of postural change in lung volume to the postural change in Pes at resting end exhalation. Changing from upright to supine caused only minor changes in the relationship between Pes and lung volume, and over one-half of the effect was due to a change in resting lung volume. It remains to be determined whether measurements of Pes can be helpful for managing mechanical ventilation in patients with acute lung injury.

	METHODS

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Subjects were healthy adults, nine men and one woman, recruited from the hospital community (Table 1). Each provided written, informed consent using a protocol approved by the Committee on Clinical Investigations at Beth Israel Deaconess Medical Center.

The first of two protocols was designed to measure postural differences in total lung capacity (TLC). To do this, we used continuous spirometry during postural change instead of repeated helium dilution measurements, because continuous spirometry avoids the noise associated with repeated measurement of functional residual capacity (FRC). The spirometer was flushed with air before each breathing episode, typically lasting 60 s, and was used without CO₂ absorbent to reduce volume change due to metabolic gas exchange. Subjects were coached to relax completely during exhalation to FRC. Then, breathing on the spirometer, they performed two or three tidal breaths followed by relaxed exhalation to FRC to approximate the relaxation volume (V_rel). After this sequence of tidal breaths, subjects inhaled maximally to TLC and, while continuing to breathe from the spirometer, changed posture and repeated the entire sequence. This measured the volume difference between TLC in the two postures. After a recovery period off the spirometer, the sequence was repeated with postural change in the opposite direction. For each pair of postures (upright and supine, upright and prone, and supine and left lateral), the complete sequence with postural change was performed 10 times, 5 times in each direction, and the average postural difference in TLC was calculated. Postural difference between TLC values in the upright and left lateral postures was computed as the sum of TLC changes on going between upright to supine and supine to lateral.

The second protocol was designed to assess PL-volume (PV) characteristics in the same four postures. With the esophageal balloon in place, subjects breathed from the spirometer. After two or three tidal breaths ending at V_rel, subjects exhaled to residual volume (RV) and then inhaled to TLC, measuring the volume differences between TLC, V_rel, and RV. At TLC, the breathing circuit was occluded for approximately 3–5 s for measurement of static PL. The subject then made a slow exhalation interrupted by intermittent occlusions of 3–5 s to generate individual points of the static deflation PV curve of the lung (Fig. 1). This maneuver was repeated five times in each posture. Pressures used for analyses were taken midway between the extremes of the cardiogenic oscillation to minimize this source of variability.

View larger version (14K): [in this window] [in a new window]   Fig. 1. Transpulmonary pressure (PL) and lung volume in one subject. Up arrows indicate static deflation points during airway occlusions used for analysis. Down arrows indicate relaxation volume (Vrel) and residual volume (RV). TLC, total lung capacity.

View larger version (19K): [in this window] [in a new window]   Fig. 2. PL-lung volume relationship in one subject in 5 runs in each position. All lung volumes are referenced to the upright TLC. Note that the PL at upright Vrel is less supine than in other postures.

View larger version (19K): [in this window] [in a new window]   Fig. 3. PL-lung volume relationship in each body position for the same subject shown in Fig. 2, with least squares regression lines. All lung volumes are referenced to upright TLC. Note that slopes of the lines are lowest in supine and left lateral postures.

	RESULTS

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Postural effects on TLC, V_rel, RV, and VC are shown in Table 2. SDs for 10 measurements of TLC difference between postural pairs in individual subjects were small; the average SDs for upright-to-supine, upright-to-prone, and prone-to-lateral differences were 97, 133, and 111 ml, respectively. TLC was slightly greater in the upright posture than in other postures, and V_rel decreased from 35% of VC upright to 13% of VC supine. VCs were closely similar in all postures.

	DISCUSSION

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PL at V_rel in the supine position was negative in 7 of 10 subjects, on average –3.3 cmH₂O, and still negative after correcting for the shift in the PV curve. Pressure in the pleural space varies regionally due to gravitational gradients (15) and changes in the shape of the lung caused by displacements of surrounding chest wall structures, such as the heart and diaphragm-abdomen (12). Thus the Pes can, at best, reflect the pressure only at one locus in the pleural space, overestimating it in the nondependent pleural space and underestimating it in dependent regions (12). At low lung volumes, especially near the bottom of the pleural space, Ppl may indeed be locally positive, and thus a negative value of PL is not unreasonable. Negative PL are consistent with the low V_rel in our supine subjects, which averaged only 13% of VC.

Reluctance to use esophageal manometry in supine patients stems, in part, from studies in normal subjects, demonstrating that Pes at a given lung volume is increased, and CL is apparently reduced, in the supine position (6, 13, 16, 18). These upright-to-supine differences in pressure and compliance have been attributed to an artifact caused by direct compression of the esophagus by mediastinal contents, such as the heart (6, 13, 16, 18). Lesser changes in Pes have been observed with change from supine to prone or lateral positions (6, 18). Previous studies (6, 13, 16, 18), each performed in four to seven subjects, did not characterize the contribution of changes in lung volume to the increases in Pes at end exhalation.

We found the average slope of the PV curve to be 15% less in the supine position than upright. This difference in the static deflation CL as measured with an esophageal balloon was attributed by Knowles et al. (13) to compression of the esophagus by overlying mediastinal content. According to this explanation, as the lung deflates toward RV, the heart and other structures settle onto the esophagus, compressing it and raising Pes. The increasing esophageal compression at progressively lower lung volumes results in both a lower slope of the transpulmonary PV relationship and higher Pes observed supine at the reference volume (upright V_rel). Our data for the upright, supine, and prone positions are consistent with this mechanism. In the supine position, both PL_rel and compliance are lower than upright, whereas, in the prone position, in which the mediastinal content is below the esophagus, PL_rel and compliance are similar to those upright. However, in the left lateral position, compliance was decreased relative to upright (Table 6) without a concomitant decrease in PL_rel (Table 4). As shown in Figs. 2 and 3, the horizontal position of the left lateral PV curve is similar to those of the prone and upright curves, but its slope is similar to that of the supine curve. How do we explain PL_rel and compliance in left lateral recumbency, if not by mediastinal compression of the esophagus?

Alternatively, we speculate that changes in posture could cause true changes in the PV characteristic of the lung, changes that are not simply an artifact of Pes measurement. CL could be decreased by inhomogeneous inflation caused by increased interregional differences in Ppl, such as would be caused by changes in the shape of the chest wall. For example, cephalad displacement of the dorsal diaphragmatic surface by the abdominal contents supine could compress the dependent lung, increasing the gravitational Ppl gradient. Animal studies have shown greater gravitational gradients in Ppl supine than prone, an effect attributed to a change in shape of the lung and chest wall (12, 15, 23, 24). D'Angelo et al. (4) proposed that increasing the Ppl gradient in rabbits causes an increase in lung elastance. We suggest that, in the upright and prone positions, the lung's inherent shape is close to that of its container, the gravitational Ppl gradient is low, and CL high. Neither prone nor upright positions cause the compression of the dependent lung by the heart that occurs in the supine position (3). By contrast, in the left lateral position, the mediastinum settles in the chest, compressing the dependent lung and increasing interregional differences in Ppl, thereby decreasing CL. In the left lateral posture, in which the heart and mediastinal content is largely below the esophagus, Pes is not elevated at V_rel, and changes in compliance cannot be explained by direct compression of the esophagus by the mediastinum.

In critically ill, mechanically ventilated patients, clinical decisions are informed by assessments of transrespiratory pressures and not PL. Most studies utilizing esophageal manometry report only the changes in PL and Pes, discounting by subtraction the baseline values (10, 17, 21). This practice ignores information about the chest wall that could be potentially useful.

Studies in animals have shown that ventilator pressures that are too high at end inflation or inappropriately low at end exhalation can worsen lung damage or cause ventilator-induced lung injury (8, 19). Recent articles on mechanical ventilation in acute respiratory distress syndrome have recommended a ventilatory strategy that prevents alveolar collapse by maintaining relatively high levels of positive end-expiratory pressure (9, 14, 19, 20) while limiting tidal volume to avoid lung injury from overdistension (1). However, these recommendations specify airway pressures and do not account for the variability in Ppl observed in critical illness (22). We suggest that estimating Ppl with esophageal manometry could reduce ventilator-induced lung injury and improve patient care.

The utility of esophageal manometry to estimate Ppl in supine patients has been debated (5, 11) and is at present unknown. We have confirmed in healthy subjects that, when adjusted for decreased lung volume, the average decrease in PL from the upright to supine is <3 cmH₂O. This difference is nearly an order of magnitude less than the range of Pes values observed in critically ill patients with acute respiratory failure (22). It remains to be determined whether esophageal manometry can be useful in managing mechanical ventilation in patients.

	GRANTS

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This study was supported by National Heart, Lung, and Blood Institute Grant HL-52586.

	ACKNOWLEDGMENTS

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The authors thank Elizabeth Tegins and Heidi Matus for help in data collection and analysis, and Atul Malhotra for constructive criticism of the manuscript.

	FOOTNOTES

 

Address for reprint requests and other correspondence: S. Loring, Anesthesia, Dana 717, 330 Brookline Ave., Boston MA 02215 (e-mail: Sloring{at}BIDMC.Harvard.edu)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

	REFERENCES

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