(PDF) Figure 8: Relative Changes in Duration of Inspiration

Figure 8: Relative Changes in Duration of Inspiration and Expiration, Total Duration of One Ventilatory Cycle, and Instantaneous Breathing Frequency in Testudines Under Hypoxic and Hypercarbic Exposures.

doi 10.7717/peerj.5137/fig-8

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Figure 4: Duration of Inspiration, Duration of Expiration, Total Duration of One Ventilatory Cycle, and Instantaneous Breathing Frequency in Trachemys Scripta and Chelonoidis Carbonarius.

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Figure 7: Relative Changes in Breathing Frequency During Breathing Episodes, Number of Breathing Episodes, and Duration of the Non-Ventilatory Period in Testudines Under Hypoxic and Hypercarbic Exposures.

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Figure 10: Relative Changes in Tidal Volume, Breathing Frequency, and Minute Ventilation in Testudines Under Hypoxic and Hypercarbic Exposures.

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Figure 9: Relative Changes in the Relation Between Expiration and Total Duration of One Ventilatory Cycle, the Relation Between Inspiration and Expiration, and Expiratory Flow Rate.

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Figure 11: Relative Changes in Oxygen Consumption and Air Convection Requirement in Testudines Under Hypoxic and Hypercarbic Exposures.

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Figure 5: Relation Between Expiration and Total Duration of One Ventilatory Cycle, the Relation Between Inspiration and Expiration, and the Expiratory Flow Rate in Trachemys Scripta and Chelonoidis Carbonarius.

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Figure 3: Breathing Frequency During Breathing Episodes, Number of Breathing Episodes, and Duration of the Non-Ventilatory Period in Trachemys Scripta and Chelonoidis Carbonarius.

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Periodic Breathing Cycle Duration in Preterm Infants

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Job Displacement, Relative Wage Changes, and Duration of Unemployment

Journal of Labor Economics

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Amanote Research

Figure 8: Relative Changes in Duration of Inspiration and Expiration, Total Duration of One Ventilatory Cycle, and Instantaneous Breathing Frequency in Testudines Under Hypoxic and Hypercarbic Exposures.

doi 10.7717/peerj.5137/fig-8

Full Text

Abstract

Date

Authors

Publisher

Related search

Figure 4: Duration of Inspiration, Duration of Expiration, Total Duration of One Ventilatory Cycle, and Instantaneous Breathing Frequency in Trachemys Scripta and Chelonoidis Carbonarius.

Figure 7: Relative Changes in Breathing Frequency During Breathing Episodes, Number of Breathing Episodes, and Duration of the Non-Ventilatory Period in Testudines Under Hypoxic and Hypercarbic Exposures.

Figure 10: Relative Changes in Tidal Volume, Breathing Frequency, and Minute Ventilation in Testudines Under Hypoxic and Hypercarbic Exposures.

Figure 9: Relative Changes in the Relation Between Expiration and Total Duration of One Ventilatory Cycle, the Relation Between Inspiration and Expiration, and Expiratory Flow Rate.

Figure 11: Relative Changes in Oxygen Consumption and Air Convection Requirement in Testudines Under Hypoxic and Hypercarbic Exposures.

Figure 5: Relation Between Expiration and Total Duration of One Ventilatory Cycle, the Relation Between Inspiration and Expiration, and the Expiratory Flow Rate in Trachemys Scripta and Chelonoidis Carbonarius.

Figure 3: Breathing Frequency During Breathing Episodes, Number of Breathing Episodes, and Duration of the Non-Ventilatory Period in Trachemys Scripta and Chelonoidis Carbonarius.

Periodic Breathing Cycle Duration in Preterm Infants

Job Displacement, Relative Wage Changes, and Duration of Unemployment