scholarly journals End-Tidal Partial Pressure of CO2 for Estimating Arterial Partial Pressure of CO2 during Inhalation Anesthesia in Dogs

1999 ◽  
Vol 52 (1) ◽  
pp. 27-31
Author(s):  
Kazuto YAMASHITA ◽  
Yasushi SASAKI ◽  
Yasuharu IZUMISAWA ◽  
Tadao KOTANI
Keyword(s):  
Partial Pressure ◽  
Inhalation Anesthesia ◽  
Arterial Partial Pressure ◽  
Partial Pressure Of Co2 ◽  
End Tidal

Expiratory and arterial partial pressure relations under different ventilation-perfusion conditions

1983 ◽  
Vol 54 (6) ◽  
pp. 1745-1753 ◽  
Author(s):  
A. Zwart ◽  
S. C. Luijendijk ◽  
W. R. de Vries
Keyword(s):  
Partial Pressure ◽  
Dead Space ◽  
Gas Analysis ◽  
Lung Model ◽  
Breathing Patterns ◽  
Tracer Gas ◽  
Physiological Dead Space ◽  
Arterial Partial Pressure ◽  
The Difference ◽  
End Tidal

Inert tracer gas exchange across the human respiratory system is simulated in an asymmetric lung model for different oscillatory breathing patterns. The momentary volume-averaged alveolar partial pressure (PA), the expiratory partial pressure (PE), the mixed expiratory partial pressure (PE), the end-tidal partial pressure (PET), and the mean arterial partial pressure (Pa), are calculated as functions of the blood-gas partition coefficient (lambda) and the diffusion coefficient (D) of the tracer gas. The lambda values vary from 0.01 to 330.0 inclusive, and four values of D are used (0.5, 0.22, 0.1, and 0.01). Three ventilation-perfusion conditions corresponding to rest and mild and moderate exercise are simulated. Under simulated exercise conditions, we compute a reversed difference between PET and Pa compared with the rest condition. This reversal is directly reflected in the relation between the physiological dead space fraction (1--PE/Pa) and the Bohr dead space fraction (1--PE/PET). It is argued that the difference (PET--Pa) depends on the lambda of the tracer gas, the buffering capacity of lung tissue, and the stratification caused by diffusion-limited gas transport in the gas phase. Finally some determinants for the reversed difference (PET--Pa) and the significance for conventional gas analysis are discussed.

scholarly journals Right-to-left shunt determination in dog lungs under inhalation anesthesia with rebreathing and non-rebreathing system

2006 ◽  
Vol 21 (6) ◽  
pp. 374-379 ◽  
Author(s):  
André Leguthe Rosa ◽  
Patrícia Cristina Azevedo Mota ◽  
Yara Marcondes Machado Castiglia
Keyword(s):  
Partial Pressure ◽  
Carbon Dioxide Partial Pressure ◽  
Partial Pressure Of Oxygen ◽  
Intrapulmonary Shunt ◽  
Inhalation Anesthesia ◽  
Arterial Partial Pressure ◽  
Venous Oxygen Saturation ◽  
Fraction Of Inspired Oxygen ◽  
Inspired Oxygen ◽  
Mixed Venous

PURPOSE: To investigatge right-to-left shunt determination in dog lungs under inhalantion anesthesia with non-rebreathing and rebreathing systems and fraction of inspired oxygen (F I O2) of 0.9 and 0.4, respectively. METHODS: Two groups of 10 dogs each under inhalation anesthesia with sevoflurane: GI in which it was utilized non-rebreathing semiclosed system and F I O2 = 0.9, and GII in which it was utilized rebreathing semiclosed system and F I O2 = 0.4. The study parameters were: heart rate, medium arterial pressure, right-to-left intrapulmonary shunt, hematocrit, hemoglobin, arterial partial pressure of oxygen, mixed venous partial pressure of oxygen, mixed venous oxygen saturation, arterial partial pressure of carbon dioxide, partial pressure of water in the alveoli. RESULTS: Shunt results were significantly different between the two groups - GI data were higher than GII in all the evaluated moments. Hence, the group with nonrebreathing (GI) developed a superior grade of intrapulmonary shunt when compared with the rebreathing group (GII). The partial pressure of water in the alveoli was significantly higher in GII. CONCLUSION: The inhalation anesthesia with non-rebreathing system and F I O2 = 0.9 developed a higher grade of intrapulmonary right-to-left shunt when compared with the rebreathing system and F I O2 = 0.4. The higher humidity in GII contributed to the result.

scholarly journals Recent Insights into the Measurement of Carbon Dioxide Concentrations for Clinical Practice in Respiratory Medicine

Sensors ◽  
2021 ◽  
Vol 21 (16) ◽  
pp. 5636
Author(s):  
Akira Umeda ◽  
Masahiro Ishizaka ◽  
Akane Ikeda ◽  
Kazuya Miyagawa ◽  
Atsumi Mochida ◽  
...  
Keyword(s):  
Carbon Dioxide ◽  
Clinical Practice ◽  
Partial Pressure ◽  
Sleep Apnea Syndrome ◽  
The Body ◽  
Non Invasive ◽  
Arterial Blood ◽  
Co2 Concentrations ◽  
Partial Pressure Of Co2 ◽  
End Tidal

In the field of respiratory clinical practice, the importance of measuring carbon dioxide (CO2) concentrations cannot be overemphasized. Within the body, assessment of the arterial partial pressure of CO2 (PaCO2) has been the gold standard for many decades. Non-invasive assessments are usually predicated on the measurement of CO2 concentrations in the air, usually using an infrared analyzer, and these data are clearly important regarding climate changes as well as regulations of air quality in buildings to ascertain adequate ventilation. Measurements of CO2 production with oxygen consumption yield important indices such as the respiratory quotient and estimates of energy expenditure, which may be used for further investigation in the various fields of metabolism, obesity, sleep disorders, and lifestyle-related issues. Measures of PaCO2 are nowadays performed using the Severinghaus electrode in arterial blood or in arterialized capillary blood, while the same electrode system has been modified to enable relatively accurate non-invasive monitoring of the transcutaneous partial pressure of CO2 (PtcCO2). PtcCO2 monitoring during sleep can be helpful for evaluating sleep apnea syndrome, particularly in children. End-tidal PCO2 is inferior to PtcCO2 as far as accuracy, but it provides breath-by-breath estimates of respiratory gas exchange, while PtcCO2 reflects temporal trends in alveolar ventilation. The frequency of monitoring end-tidal PCO2 has markedly increased in light of its multiple applications (e.g., verify endotracheal intubation, anesthesia or mechanical ventilation, exercise testing, respiratory patterning during sleep, etc.).

scholarly journals IS THE END-TIDAL PARTIAL PRESSURE OF ISOFLURANE A GOOD PREDICTOR OF ITS ARTERIAL PARTIAL PRESSURE?

1991 ◽  
Vol 66 (3) ◽  
pp. 331-339 ◽  
Author(s):  
F.J. FREI ◽  
A.M. ZBINDEN ◽  
D.A. THOMSON ◽  
H.U. RIEDER
Keyword(s):  
Partial Pressure ◽  
Good Predictor ◽  
Arterial Partial Pressure ◽  
End Tidal

Effect of arterial PCO2 on 2-[1-14C]deoxy-D-glucose uptake by feline cerebral arteries

1986 ◽  
Vol 61 (4) ◽  
pp. 1288-1292
Author(s):  
D. R. Kostreva ◽  
J. McNeely ◽  
E. J. Zuperku
Keyword(s):  
Partial Pressure ◽  
Glucose Uptake ◽  
Blood Vessels ◽  
Glucose Utilization ◽  
Cerebral Arteries ◽  
Arterial Pco2 ◽  
Arterial Partial Pressure ◽  
Partial Pressure Of Co2 ◽  
Autoradiographic Technique

The effect of high and low arterial CO2 on the glucose utilization of nine major cerebral arteries was studied in cats anesthetized with pentothal using the quantitative 2-[1–14C]deoxy-D-glucose autoradiographic technique. All nine cerebral arteries from animals subjected to an arterial partial pressure of CO2 (PCO2) of 20 Torr utilized significantly more (P less than 0.025) glucose than the group subjected to an arterial PCO2 of 60 Torr. Mean relative glucose utilization of the 20-Torr PCO2 group was 105 +/- 9.5 mumol X 100g-1 X min-1 (+/- SE, n = 18) as compared with 49 +/- 6 mumol X 100g-1 X min-1 (+/- SE, n = 26) for the 60-Torr PCO2 group. This study demonstrates that blood vessels can be studied in vivo using the 2-[1-14C]deoxy-D-glucose autoradiographic technique. It also demonstrates that a physiological stimulus like CO2 can produce measurable changes in glucose utilization of cerebral arteries in vivo.

Timing of deep breaths during rest and light exercise in man

1990 ◽  
Vol 78 (6) ◽  
pp. 573-578 ◽  
Author(s):  
C. P. Patil ◽  
K. B. Saunders ◽  
B. McA. Sayers
Keyword(s):  
Partial Pressure ◽  
Tidal Volume ◽  
Digital Filtering ◽  
Segmental Analysis ◽  
Partial Pressure Of Co2 ◽  
The Mean ◽  
End Tidal ◽  
Normal Adults ◽  
Respiratory Variables ◽  
Three Components

1. We used digital filtering techniques and segmental analysis to dissect a series of respiratory variables into three components: (a) outlying values, including deep breaths or sighs; (b) random variation; (c) non-stationary baseline variation. 2. Records of about 30 min breathing were obtained from normal adults at rest and at 50 W exercise. 3. Deep breaths were defined as having a tidal volume >2.5 sd above the mean. 4. We related these deep breaths to preceding trends in tidal volume and end-tidal partial pressure of CO2. 5. At rest, there was no relation between deep breaths and tidal volume, but the deep breaths were significantly clustered around the troughs in end-tidal partial pressure of CO2. 6. At 50 W exercise, there was no relation between deep breaths and end-tidal partial pressure of CO2, but the deep breaths were significantly clustered around tidal volume troughs. 7. Results obtained by pneumography were concordant with those obtained by using a mouthpiece to measure ventilation.

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