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First published online November 14, 2008
Journal of Experimental Biology 211, 3759-3763 (2008)
Published by The Company of Biologists 2008
doi: 10.1242/jeb.021089

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Changes in pulmonary blood flow do not affect gas exchange during intermittent ventilation in resting turtles

Tobias Wang^1,2,* and James W. Hicks²

¹ Zoophysiology, Department of Biological Sciences, University of Aarhus, 8000 Aarhus C, Denmark
² Department of Ecology and Evolutionary Biology, University of California at Irvine, Irvine, CA 92697, USA

^* Author for correspondence (e-mail: tobias.wang{at}biology.au.dk)

Accepted 11 September 2008

	Summary

TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

 
The breathing pattern of many different air-breathing vertebrates, including lungfish, anuran amphibians, turtles, crocodiles and snakes, is characterized by brief periods of lung ventilation interspersed among apnoeas of variable duration. These intermittent ventilatory cycles are associated with characteristic increases in pulmonary blood flow and tachycardia. In animals with central vascular shunts, the rise in pulmonary blood flow during ventilation is associated with the development of left-to-right (L–R) cardiac shunt (pulmonary recirculation of oxygenated blood returning from the lungs). By contrast, a large net right-to-left (R–L) shunt (pulmonary bypass) normally prevails during apnoea. The cardio–respiratory interaction and the changes in cardiac shunting have been suggested to improve pulmonary gas exchange but the benefits of L–R shunting on pulmonary gas transport have not been studied experimentally. The present study measured pulmonary gas exchange in fully recovered, freely diving turtles, where changes in pulmonary blood flow were prevented by partial occlusion of the pulmonary artery. Prevention of L–R shunt during ventilation did not impair CO₂ excretion and overall, oxygen uptake and CO₂ excretion did not correlate with changes in pulmonary blood flow. We conclude that increases in pulmonary blood flow associated with ventilation are not required to maintain resting rates of oxygen uptake and CO₂ excretion in resting animals.

Key words: reptile, turtle, periodic ventilation, pulmonary blood flow, cardiac shunt, left-to-right shunt, gas exchange, CO₂ excretion, respiratory gas exchange ratio

	INTRODUCTION

TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

 
Animals with an intermittent ventilatory pattern normally increase pulmonary blood flow (_pul) and heart rate (f_H) during the brief periods of lung ventilation, providing a temporal matching of perfusion and ventilation of the lungs that may improve gas exchange efficacy (e.g. Johansen et al., 1970; Shelton, 1970; Shelton and Burggren, 1976; Lillywhite and Donald, 1989; Wang and Hicks, 1996) (cf. Hopkins et al., 1996). In animals with central vascular shunts, the rise in _pul during ventilation is associated with the development of a left-to-right (L–R) cardiac shunt (pulmonary recirculation of oxygenated blood returning from the lungs) whereas a large net right-to-left (R–L) shunt (pulmonary bypass) predominates during apnoea. These hemodynamic changes are particularly evident in freshwater turtles (Shelton and Burggren, 1976; White et al., 1989; Wang and Hicks, 1996).

The physiological consequences of cardiac shunts on pulmonary gas exchange are not clear (Burggren, 1987; Hicks and Wang, 1996). R–L shunts lower arterial oxygen content because of the venous admixture and the resulting decrease in systemic oxygen delivery has been suggested to induce hypometabolism (Hicks and Wang, 1999; Platzack and Hicks, 2001). Such a reduction in oxygen requirement could be an important mechanism for extending aerobic dive durations but remains to be demonstrated in recovered and freely diving animals.

The effects of L–R shunt that returns oxygenated blood to the lungs are not easily predicted but functional consequences have been suggested (cf. Hicks and Wang, 1996). One hypothesis is that the increased oxygenation of pulmonary arterial blood caused by L–R shunt, facilitates pulmonary CO₂ excretion (Ackerman and White, 1979) (cf. White, 1985). According to this hypothesis, the L–R shunt increases pulmonary arterial hemoglobin oxygenation, which, in turn, elevates pulmonary arterial partial pressure of CO₂ (P_CO2) through the Haldane effect and, therefore, enlarges the P_CO2 gradient between the pulmonary capillaries and lung gas (White, 1985; White et al., 1989). However, a theoretical analysis of L–R shunting on CO₂ excretion provided conflicting results (Hicks and Wang, 1996). Thus, the change in pulmonary arterial P_CO2 is determined by the slope of the CO₂ dissociation curve, the magnitude of the Haldane effects, the degree of the L–R shunt as well as other physiological variables (Hicks and Wang, 1996) rendering a priori predictions concerning the role of L–R shunt on CO₂ excretion extremely difficult.

The objective of this study was to experimentally investigate the effects of changes in _pul and net cardiac shunts on pulmonary gas exchange in an intermittently breathing vertebrate with cardiac shunts. For the present study, we chose the freshwater turtle, Trachemys scripta because this species normally exhibit intermittent breathing associated with large changes in cardiac shunt patterns (Shelton and Burggren, 1976; White, 1985; Wang and Hicks, 1996). In addition, the cardiovascular anatomy lends itself to a level of instrumentation and experimental manipulation not easily obtainable in other animals. This enabled us to manipulate _pul in free diving turtles while measuring gas exchange and ventilation. By inflating a vascular occluder placed around the common pulmonary artery, we prevented the normal rise in _pul and the associated L–R shunt during ventilation. Simultaneously, partially occluding pulmonary blood flow would result in a net R–L shunt during ventilation. If indeed L–R shunt facilitates CO₂ excretion, an abolishment of L–R shunt during ventilation should result in CO₂ retention, which will be evident as a transient decrease in the respiratory gas exchange ratio. Conversely, if R–L shunt induces a hypometabolic state, then oxygen uptake should be reduced.

	MATERIALS AND METHODS

TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

 
Animals and instrumentation
Freshwater turtles (Trachemys scripta Gray) with a body mass ranging from 1.6 to 1.8 kg were purchased from Lemberger (Oshkosh, WI, USA) and freighted by air to the University of California at Irvine, USA. Here, the turtles were kept in open aquaria with free access to water and dry basking areas allowing for behavioral thermoregulation. They were fed fish but food was withheld for at least four days prior to surgery. For anesthesia, a short piece of soft rubber tubing was inserted through the glottis for artificial ventilation at 8–15 min^–1 with a tidal volume of 10–20 ml kg^–1 using a gas mixture consisting of 30% O₂, 3% CO₂ (balance N₂) prepared by a gas mixer (GF-3, Cameron Institute, TX, USA). This gas mixture passed through a Halothane vaporizer (Drager, Lübeck, FRG, Germany) set at 4% to induce anesthesia. The Halothane level was reduced to 0.5–1% after 5–15 min when the turtles no longer responded to tactile stimulation. The heart and central blood vessels were exposed by removing a 4x5 cm portion of the plastron using a bone saw. The common pulmonary artery was freed from the systemic vessels in the aortic trunk and a vascular occluder (In Vivo Metric, Healdsburg, CA, USA) was placed around the common pulmonary artery. Short sections (1.5 cm) of the left pulmonary artery and the left aortic arch vessels were freed from the connecting tissue in order to place the two blood flow probes (2R, Transonic System, Ithaca, NY, USA). Acoustical gel (Mohawk Medical Supply, NY, USA) was injected around the probe to enhance the signal. Leads from the probes and the occluder were carried out ventrally and strapped to the carapace, and the excised piece of plastron was glued in place. Artificial ventilation was continued until the turtle regained spontaneous breathing.

Measurement of blood flows, ventilation and gas exchange
Ventilation and gas exchange was determined in an experimental setup similar to that described by Glass et al. (Glass et al., 1983), where the turtle could move freely within a shielded holding tank (30x30x60 cm) covered by a grid forcing it to breathe at a funnel-shaped breathing hole with a diameter of 7 cm. The holding tank was covered on all sides to prevent visual disturbance. Airflow leaving the funnel covering the breathing hole was maintained constant at 500 ml min^–1 and continuously analysed using a Beckman OM-11 paramagnetic O₂ analyzer and a Beckman LB-2 CO₂ analyzer connected in series (Anaheim, CA, USA). Given the constant flow rate, oxygen consumption and CO₂ production could be calculated as the respective areas below or above the baseline values. In addition, this relationship was verified by artificially simulating exhalations with known gas compositions through the funnel. A pneumotachograph (0–5 LPM, Hans Rudolph, Shawney, MO, USA) placed at the gas inlet and connected to a Validyne differential pressure transducer (DP45-14, Validyne Engineering Sales Corp., Northridge, CA, USA) recorded increases in gas flow during inhalations and decreases in gas flow during exhalations. The pneumotachograph was calibrated by manually simulating breaths of a known volume using a syringe, which was directly connected to the breathing funnel. As originally described by Funk et al. (Funk et al., 1986), we found that the integrated airflow signal of a given tidal volume decreased with increased frequency. Therefore, a calibration at several frequencies was necessary, and the instantaneous breathing frequency (breath-to-breath frequency within a ventilatory period) of several turtles was analysed in detail to provide the exact correction factor. The flow probes were connected to a dual channel blood flow meter (T201, Transonic system) and f_H was calculated on the basis of the instantaneous blood flow profiles. Total _pul was calculated as 2x_LPA (left pulmonary artery) whereas the systemic cardiac output (_sys) was calculated as 2.75x_LAo (left aortic arch) (Wang and Hicks, 1996). All measurements were collected continuously at 15 Hz on a computer using Acknowledge data aquisition program (v. 3.0; Biopac System, Goleta, CA, USA).

Experimental protocol
All animals recovered for a minimum of two days following surgery. On the morning of the measurements, the turtle was placed in the experimental setup and left undisturbed for 4–6 h. During this period, ventilatory and cardiovascular parameters approached the values previously reported in this species, under resting conditions. All physiological parameters were then collected for 60 min, and the vascular occluder was manually inflated to maintain _pul at a level similar to that observed during apnoea prior to manipulation. The partial pulmonary artery occlusion was maintained for 60 min and then released. After this period, the turtle was left undisturbed for an additional 60 min. In two instances, pulmonary artery occlusion elicited noticeable activity and the measurements were aborted and repeated on the following day.

Data analysis
Recordings of blood flows, ventilation and gas exchange were analyzed using Acknowledge (3.0) data analysis system (Biopac System). All experiments were divided into 18 ten-minute intervals (60 min control, 60 min of reduction of pulmonary blood flow and 60 min of subsequent control) and each interval was analysed for mean _pul, mean _sys, total ventilated volume, and total O₂ uptake and CO₂ excretion. For each 10 min interval, a mean and standard error of each of the five turtles were calculated. Because the analysis of ventilatory and cardiovascular parameters in turtles are complicated by the intermittent breathing pattern, a presentation of mean values, as described above, could mask possible effects of manipulating pulmonary blood flow on gas exchange. We, therefore, also present gas exchange values for each individual animal during the 10 min intervals as a function of ventilatory and cardiovascular variables.

Statistics
The effects of partial occlusion of the physiological parameters were evaluated with a one-way analysis of variance (ANOVA) for repeated measures. In case of a significant effect, differences among means were assessed with a Student–Newman–Keuls test. To further evaluate the effects of _pul on gas exchange, linear regression of data points was conducted. In all statistical analyses, a fiducial limit for significance of P<0.05 was applied. All data are presented as means ±1 s.e.m.

	RESULTS

TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

 
An example of blood flows and ventilation recorded during an experiment is shown in Fig. 1. Mean values for _pul and _sys, as well as minute ventilation (Ve) and pulmonary gas exchange ratios (RE), are presented in Figs 2 and 3. The mean values obtained for ventilation, gas exchange and blood flows in the present study correspond well with previous reports on the same species at similar temperatures (e.g. Shelton and Burggren, 1976; Glass et al., 1983; Milsom and Chan, 1986; Wang and Hicks, 1996). Partial occlusion of the common pulmonary artery lowered _pul to the levels measured during apnoea and elicited a small rise in _sys (Figs 1 and 2). The manipulation of pulmonary artery blood flow abolished the net L–R cardiac shunt (_pul/_sys>1) during ventilation and induced a chronic R–L shunt throughout the ventilatory cycle, as reflected in a significant decrease of _pul/_sys to values below 1 (Fig. 2). This altered cardiac shunt pattern did not affect overall Ve or RE during the 60 min period of partial occlusion (Fig. 3). Upon releasing the occlusion, the normal hemodynamic changes associated with ventilation and apnoea were rapidly restored (see Fig. 1). In some individuals, _pul increased drastically following release of the occlusion. A similar pattern of changes in blood flow and ventilation was observed in all experimental animals.

View larger version (23K): [in this window] [in a new window]   Fig. 1. An example of ventilation and blood flows in a turtle instrumented with flow probes on the left aortic arch (LAo) and the left pulmonary artery, as well as a vascular occluder around the common pulmonary artery. During the first 60 min, pulmonary blood flow (pul) and heart rate (fH) increased substantially during ventilation, and caused the development of a net left–to-right (L–R) cardiac shunt pattern. This rise in pul was then prevented by partial occlusion of the common pulmonary by inflation of the vascular occluder for the following 60 min. As a consequence, a net cardiac right-to-left (R–L) shunt prevailed even during ventilation. Blood flows and ventilation are also shown during 60 min after releasing the occlusion.

View larger version (13K): [in this window] [in a new window]   Fig. 2. Blood flows and cardiac shunt pattern before, during and after partial occlusion of the common pulmonary artery. (A) Mean pulmonary blood flow (pul); (B) mean systemic blood flow (sys); (C) pul/sys. Values are means ±1 s.e.m. (N=5) over 10 min periods. Values significantly different from control conditions are marked with an asterisk (P<0.05).

View larger version (17K): [in this window] [in a new window]   Fig. 3. Ventilation and gas exchange before, during and after partial occlusion of the common pulmonary artery. (A) Pulmonary ventilation (Ve); (B) oxygen uptake (O2); (C) CO2 excretion (CO2) (D) respiratory gas exchange ratio (RE). Values are means ±1 s.e.m. (N=5) over 10 min period. Values significantly different from control conditions are marked with an asterisk (P<0.05). No mean values during manipulation are significantly different than those obtained during the preceding control period.

All individual data points for gas exchange over 10 min intervals for all five turtles are presented in Fig. 4. These results demonstrate that measured values of rate of oxygen uptake (_O2), rate of CO₂ excretion (_CO2) and RE were correlated with Ve but were independent of total _pul and _pul/_sys.

View larger version (33K): [in this window] [in a new window]   Fig. 4. Oxygen uptake (O2), CO2 excretion (CO2) and the respiratory gas exchange ratio (RE) as a function of minute ventilation (Ve, left panel), pulmonary blood flow (pul middle panel) and pul/sys (right panel). Open circles represent periods of partial occlusion of the pulmonary artery, and closed circles represent pre- and post-occlusion. Each symbol represents the mean value determined every 10 min, during a three hour experimental protocol.

	DISCUSSION

TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

A central aim of the present study was to investigate the hypothesis that net L–R cardiac shunt during the ventilatory periods augments the cyclic excretion of CO₂ (Ackerman and White, 1979; White, 1985). L–R shunt increases hemoglobin oxygen saturation (HbO_2sat) of pulmonary arterial blood relative to right atrial blood. This has been proposed to increase HbO_2sat of pulmonary arterial blood and lower blood CO₂ affinity through the Haldane effect, which would increase P_CO2 in the pulmonary arterial blood. This elevated P_CO2 would then increase the P_CO2 gradient between pulmonary capillary blood and the lungs, and facilitate CO₂ excretion into the lungs (White, 1985). The magnitude of this effect depends on the magnitude of the L–R shunt, the CO₂ dissociation curve and oxygenation differences between the two atria but the complex interaction between these various physiological parameters renders theoretical predictions difficult (Hicks and Wang, 1996). However, if L–R shunt contributes significantly to CO₂ excretion, the experimental prevention of L–R cardiac shunt during ventilation by partial occlusion of the pulmonary artery should have led to a reduction in pulmonary CO₂ excretion. This effect would best be evaluated as a reduction in the RE because this ratio would not be affected by altered metabolism. Our manipulation of _pul successfully prevented L–R shunt during ventilation and maintained a net R–L shunt (_pul/_sys<1) during both ventilatory periods and apnoea. The results of the present study demonstrate that eliminating net L–R shunt had no significant effect on pulmonary gas exchange in recovered animals and our study, therefore, does not support the hypothesis that L–R shunt during ventilation facilitates CO₂ excretion in turtles at rest.

This study showed that overall gas exchange of resting turtles was not influenced by the reduction of _pul and the induction of a chronic R–L shunt. A previous study investigating V/Q (ventilation-perfusion) distributions on the efficacy of gas exchange, indicated that a 10-fold change in _pul and 6-fold change in _pul/_sys had no effect on overall _CO2 and _O2 in artificially ventilated, anesthetized turtles (Hopkins et al., 1996). Our study extends these observations to a fully recovered, freely diving turtle and underscores the notion that improved efficacy of lung function at high _pul does not affect overall gas exchange of resting animal. Resting gas exchange is maintained both at high and low pulmonary blood flow, with R–L shunt (_pul/_sys<1) or L–R shunt (_pul/_sys>1). Consequently, we suggest that in animals with low resting oxygen demands, increases in _pul associated with ventilation are not required to meet or maintain resting _O2 and _CO2.

The observation that a prevailing R–L shunt (_pul/_sys<1) did not reduce _O2 contrasts with previous studies on anesthetized and artificially ventilated turtles, where arterial hypoxemia, resulting either from reductions in inspired oxygen levels or a vagally induced R–L cardiac shunt, triggered a significant reduction in _O2 (Hicks and Wang, 1999; Platzack and Hicks, 2001). In these acute studies, the fully anesthetized turtles were artificially ventilated, and the 30–70% reductions in _O2 were fully reversed by injections of 2,4-dinitrophenol, which uncouples the mitochondria and shows that normal _O2 could be sustained at the reduced level of systemic oxygen delivery (_sysxarterial O₂ concentration) (Hicks and Wang, 1999; Platzack and Hicks, 2001). Such hypoxemic-induced hypometabolism would be a powerful mechanism for extending aerobic dive times in animals with central vascular shunts (Hicks and Wang, 2004). In the present study, the absence of a significant reduction in _O2 with low _pul and _pul/_sys<1 suggests that hypometabolism may not occur in recovered, freely diving turtles. In previous studies on anesthetized Trachemys, systemic oxygen delivery was reduced by over 50% through reductions in inspired oxygen levels and by over 60% during electrical stimulation of the right vagal afferent nerves (Hicks and Wang, 1999; Platzack and Hicks, 2001). In freely diving turtles, it is possible that the overall reduction in systemic oxygen delivery may not have may have been of sufficient magnitude to trigger a hypometabolic state. Unfortunately, we did not measure arterial blood gases, so although a net R–L shunt occurred (_pul/_sys<1), the absolute reduction in systemic oxygen delivery could not be assessed.

Our overall findings do not necessarily negate the relative importance of altering _pul and cardiac shunt patterns during intermittent ventilation. Whereas an increased _pul alone did not affect resting pulmonary gas exchange, a low _pul/_sys lowers arterial oxygen content through the addition of venous admixture to arterial blood. Conversely, an elevation of _pul during ventilation and the attending increases in _pul/_sys will elevate arterial blood oxygen content. If _pul/_sys were to remain relatively low during ventilation, as we demonstrated in this study, the resting oxygen demands will be satisfied but the result is accomplished under conditions of lowered arterial oxygen saturation, due to R–L shunt (_pul/_sys<1). Such a condition may, over the long term, influence the potential for aerobic diving.

	Acknowledgments

 
J.W.H. was supported by a NSF grant (IOB 0445680), while T.W. was supported by the Danish Research Council and the Carlsberg Foundation (Denmark). The years teach much which the days never knew – Ralph Waldo Emerson.

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TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

 

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