Evaluation of Capnography Using a Genetic Algorithm To Predict Paco2
Noninvasive estimates of Paco2 are usually done by measuring exhaled carbon dioxide at end-expiration (Petco2). While commonly used in studies involving healthy patients, it is less useful in sicker patients. Conditions that affect the terminal dead space and hence the accuracy of Petco2 as a surrog...
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| Published in | Chest Vol. 127; no. 2; pp. 579 - 584 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Elsevier Inc
01.02.2005
American College of Chest Physicians |
| Subjects | |
| Online Access | Get full text |
| ISSN | 0012-3692 1931-3543 |
| DOI | 10.1378/chest.127.2.579 |
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| Abstract | Noninvasive estimates of Paco2 are usually done by measuring exhaled carbon dioxide at end-expiration (Petco2). While commonly used in studies involving healthy patients, it is less useful in sicker patients. Conditions that affect the terminal dead space and hence the accuracy of Petco2 as a surrogate for Paco2 may also affect other components of the capnogram. A genetic algorithm is a computer technique for discovering relationships between variables. The purpose of this study was to use a genetic algorithm to improve the precision of Paco2 prediction in comparison to Petco2.
Inspiratory and expiratory volumes were measured and analyzed by the computerized capnogram. Data were recorded for 2 min. Within 5 min of recording the capnograms, arterial blood gases were obtained. After excluding artifact and incomplete capnograms, five of the remaining breaths from each patient were selected. A genetic algorithm, constructed in postfix notation, consisted of 1,000 chromosomes with genes randomly selected from the 11 capnographic data fields and mathematical operators. The algorithm was constructed on 400 breaths from 83 randomly selected patients (construction group) and tested on 160 breaths from the remaining 32 patients (test group).
For the construction group, the bias and precision between Petco2 and Paco2 were 4.3 ± 4.9 mm Hg (mean ± SD). For the 160 breaths in the test group, Petco2 predicted Paco2 with bias and precision of 2.9 ± 4.2 mm Hg. The best chromosome found by the genetic algorithm was (10 × 5 + 5 × 5 × 5)/(10 × 10) × Petco2 – (5 × 5 × 10 + 5 × 5)/(10 × 10) × int time + 2 × 2 × 2 × 2 + (2 × 2)/10, which reduces to 0.65 × Petco2 – 2.75 × int time + 16.4. This produced a bias and precision of 0.9 ± 4.1 mm Hg in the construction group and 0 ± 3.7 mm Hg in the test group (p < 0.01).
In this study of nonintubated emergency department patients, a genetic algorithm produced an improvement in bias and precision of Paco2 prediction. |
|---|---|
| AbstractList | Introduction: Noninvasive estimates of Pa co 2 are usually done by measuring exhaled carbon dioxide at end-expiration (Pet co 2 ). While commonly used in studies involving healthy patients, it is less useful in sicker patients. Conditions that affect
the terminal dead space and hence the accuracy of Pet co 2 as a surrogate for Pa co 2 may also affect other components of the capnogram. A genetic algorithm is a computer technique for discovering relationships
between variables. The purpose of this study was to use a genetic algorithm to improve the precision of Pa co 2 prediction in comparison to Pet co 2 .
Methods: Inspiratory and expiratory volumes were measured and analyzed by the computerized capnogram. Data were recorded for 2 min.
Within 5 min of recording the capnograms, arterial blood gases were obtained. After excluding artifact and incomplete capnograms,
five of the remaining breaths from each patient were selected. A genetic algorithm, constructed in postfix notation, consisted
of 1,000 chromosomes with genes randomly selected from the 11 capnographic data fields and mathematical operators. The algorithm
was constructed on 400 breaths from 83 randomly selected patients (construction group) and tested on 160 breaths from the
remaining 32 patients (test group).
Results: For the construction group, the bias and precision between Pet co 2 and Pa co 2 were 4.3 ± 4.9 mm Hg (mean ± SD). For the 160 breaths in the test group, Pet co 2 predicted Pa co 2 with bias and precision of 2.9 ± 4.2 mm Hg. The best chromosome found by the genetic algorithm was (10 à 5 + 5 à 5 à 5)/(10
à 10) à Pet co 2 â (5 à 5 à 10 + 5 à 5)/(10 à 10) à int time + 2 à 2 à 2 à 2 + (2 à 2)/10, which reduces to 0.65 à Pet co 2 â 2.75 à int time + 16.4. This produced a bias and precision of 0.9 ± 4.1 mm Hg in the construction group and 0 ± 3.7 mm
Hg in the test group (p < 0.01).
Conclusions: In this study of nonintubated emergency department patients, a genetic algorithm produced an improvement in bias and precision
of Pa co 2 prediction. Noninvasive estimates of Paco2 are usually done by measuring exhaled carbon dioxide at end-expiration (Petco2). While commonly used in studies involving healthy patients, it is less useful in sicker patients. Conditions that affect the terminal dead space and hence the accuracy of Petco2 as a surrogate for Paco2 may also affect other components of the capnogram. A genetic algorithm is a computer technique for discovering relationships between variables. The purpose of this study was to use a genetic algorithm to improve the precision of Paco2 prediction in comparison to Petco2. Inspiratory and expiratory volumes were measured and analyzed by the computerized capnogram. Data were recorded for 2 min. Within 5 min of recording the capnograms, arterial blood gases were obtained. After excluding artifact and incomplete capnograms, five of the remaining breaths from each patient were selected. A genetic algorithm, constructed in postfix notation, consisted of 1,000 chromosomes with genes randomly selected from the 11 capnographic data fields and mathematical operators. The algorithm was constructed on 400 breaths from 83 randomly selected patients (construction group) and tested on 160 breaths from the remaining 32 patients (test group). For the construction group, the bias and precision between Petco2 and Paco2 were 4.3 ± 4.9 mm Hg (mean ± SD). For the 160 breaths in the test group, Petco2 predicted Paco2 with bias and precision of 2.9 ± 4.2 mm Hg. The best chromosome found by the genetic algorithm was (10 × 5 + 5 × 5 × 5)/(10 × 10) × Petco2 – (5 × 5 × 10 + 5 × 5)/(10 × 10) × int time + 2 × 2 × 2 × 2 + (2 × 2)/10, which reduces to 0.65 × Petco2 – 2.75 × int time + 16.4. This produced a bias and precision of 0.9 ± 4.1 mm Hg in the construction group and 0 ± 3.7 mm Hg in the test group (p < 0.01). In this study of nonintubated emergency department patients, a genetic algorithm produced an improvement in bias and precision of Paco2 prediction. Noninvasive estimates of Paco(2) are usually done by measuring exhaled carbon dioxide at end-expiration (Petco(2)). While commonly used in studies involving healthy patients, it is less useful in sicker patients. Conditions that affect the terminal dead space and hence the accuracy of Petco(2) as a surrogate for Paco(2) may also affect other components of the capnogram. A genetic algorithm is a computer technique for discovering relationships between variables. The purpose of this study was to use a genetic algorithm to improve the precision of Paco(2) prediction in comparison to Petco(2). Inspiratory and expiratory volumes were measured and analyzed by the computerized capnogram. Data were recorded for 2 min. Within 5 min of recording the capnograms, arterial blood gases were obtained. After excluding artifact and incomplete capnograms, five of the remaining breaths from each patient were selected. A genetic algorithm, constructed in postfix notation, consisted of 1,000 chromosomes with genes randomly selected from the 11 capnographic data fields and mathematical operators. The algorithm was constructed on 400 breaths from 83 randomly selected patients (construction group) and tested on 160 breaths from the remaining 32 patients (test group). For the construction group, the bias and precision between Petco(2) and Paco(2) were 4.3 +/- 4.9 mm Hg (mean +/- SD). For the 160 breaths in the test group, Petco(2) predicted Paco(2) with bias and precision of 2.9 +/- 4.2 mm Hg. The best chromosome found by the genetic algorithm was (10 x 5 + 5 x 5 x 5)/(10 x 10) x Petco(2) - (5 x 5 x 10 + 5 x 5)/(10 x 10) x int time + 2 x 2 x 2 x 2 + (2 x 2)/10, which reduces to 0.65 x Petco(2) - 2.75 x int time + 16.4. This produced a bias and precision of 0.9 +/- 4.1 mm Hg in the construction group and 0 +/- 3.7 mm Hg in the test group (p < 0.01). In this study of nonintubated emergency department patients, a genetic algorithm produced an improvement in bias and precision of Paco(2) prediction. Noninvasive estimates of Paco(2) are usually done by measuring exhaled carbon dioxide at end-expiration (Petco(2)). While commonly used in studies involving healthy patients, it is less useful in sicker patients. Conditions that affect the terminal dead space and hence the accuracy of Petco(2) as a surrogate for Paco(2) may also affect other components of the capnogram. A genetic algorithm is a computer technique for discovering relationships between variables. The purpose of this study was to use a genetic algorithm to improve the precision of Paco(2) prediction in comparison to Petco(2).INTRODUCTIONNoninvasive estimates of Paco(2) are usually done by measuring exhaled carbon dioxide at end-expiration (Petco(2)). While commonly used in studies involving healthy patients, it is less useful in sicker patients. Conditions that affect the terminal dead space and hence the accuracy of Petco(2) as a surrogate for Paco(2) may also affect other components of the capnogram. A genetic algorithm is a computer technique for discovering relationships between variables. The purpose of this study was to use a genetic algorithm to improve the precision of Paco(2) prediction in comparison to Petco(2).Inspiratory and expiratory volumes were measured and analyzed by the computerized capnogram. Data were recorded for 2 min. Within 5 min of recording the capnograms, arterial blood gases were obtained. After excluding artifact and incomplete capnograms, five of the remaining breaths from each patient were selected. A genetic algorithm, constructed in postfix notation, consisted of 1,000 chromosomes with genes randomly selected from the 11 capnographic data fields and mathematical operators. The algorithm was constructed on 400 breaths from 83 randomly selected patients (construction group) and tested on 160 breaths from the remaining 32 patients (test group).METHODSInspiratory and expiratory volumes were measured and analyzed by the computerized capnogram. Data were recorded for 2 min. Within 5 min of recording the capnograms, arterial blood gases were obtained. After excluding artifact and incomplete capnograms, five of the remaining breaths from each patient were selected. A genetic algorithm, constructed in postfix notation, consisted of 1,000 chromosomes with genes randomly selected from the 11 capnographic data fields and mathematical operators. The algorithm was constructed on 400 breaths from 83 randomly selected patients (construction group) and tested on 160 breaths from the remaining 32 patients (test group).For the construction group, the bias and precision between Petco(2) and Paco(2) were 4.3 +/- 4.9 mm Hg (mean +/- SD). For the 160 breaths in the test group, Petco(2) predicted Paco(2) with bias and precision of 2.9 +/- 4.2 mm Hg. The best chromosome found by the genetic algorithm was (10 x 5 + 5 x 5 x 5)/(10 x 10) x Petco(2) - (5 x 5 x 10 + 5 x 5)/(10 x 10) x int time + 2 x 2 x 2 x 2 + (2 x 2)/10, which reduces to 0.65 x Petco(2) - 2.75 x int time + 16.4. This produced a bias and precision of 0.9 +/- 4.1 mm Hg in the construction group and 0 +/- 3.7 mm Hg in the test group (p < 0.01).RESULTSFor the construction group, the bias and precision between Petco(2) and Paco(2) were 4.3 +/- 4.9 mm Hg (mean +/- SD). For the 160 breaths in the test group, Petco(2) predicted Paco(2) with bias and precision of 2.9 +/- 4.2 mm Hg. The best chromosome found by the genetic algorithm was (10 x 5 + 5 x 5 x 5)/(10 x 10) x Petco(2) - (5 x 5 x 10 + 5 x 5)/(10 x 10) x int time + 2 x 2 x 2 x 2 + (2 x 2)/10, which reduces to 0.65 x Petco(2) - 2.75 x int time + 16.4. This produced a bias and precision of 0.9 +/- 4.1 mm Hg in the construction group and 0 +/- 3.7 mm Hg in the test group (p < 0.01).In this study of nonintubated emergency department patients, a genetic algorithm produced an improvement in bias and precision of Paco(2) prediction.CONCLUSIONSIn this study of nonintubated emergency department patients, a genetic algorithm produced an improvement in bias and precision of Paco(2) prediction. |
| Author | Plewa, Michael Engoren, Milo O'Hara, David Kline, Jeffrey A. |
| Author_xml | – sequence: 1 givenname: Milo surname: Engoren fullname: Engoren, Milo organization: Department of Anesthesiology, Department of Emergency Medicine, St. Vincent Mercy Medical Center, Toledo, OH – sequence: 2 givenname: Michael surname: Plewa fullname: Plewa, Michael organization: Department of Anesthesiology, Department of Emergency Medicine, St. Vincent Mercy Medical Center, Toledo, OH – sequence: 3 givenname: David surname: O'Hara fullname: O'Hara, David organization: Department of Anesthesiology, Department of Emergency Medicine, St. Vincent Mercy Medical Center, Toledo, OH – sequence: 4 givenname: Jeffrey A. surname: Kline fullname: Kline, Jeffrey A. organization: Carolinas Medical Center, Charlotte, NC |
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| Keywords | Paco2 computer programs Pintco2 int time genetic algorithms Petco2 Ve PII Te Vi Ti end-tidal CO2 PIII capnography |
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| References | Hoffman, Krieger, Kramer (bib6) 1989; 140 Wahba, Tessler (bib8) 1996; 43 Koza (bib12) 1992 Engoren (bib4) 1992; 4 Herholz, Straub, Moens (bib17) 2001; 48 Kentala, Laurikkala, Pyykko (bib20) 1999; 108 Falk, Rackow, Wiel (bib11) 1988; 318 Carlon, Cole, Miodownik (bib5) 1988; 16 Jacob (bib13) 2001 Bouillon, Bruhn, Radu-Radulescu (bib1) 2003; 99 Engoren (bib3) 1993; 7 Martin, Tsunoda, Young (bib15) 1974; 21 Russell, Graybeal (bib2) 1992; 4 Vinterbo, Ohno-Machado (bib18) 1999 Tavernier, Rey, Thevenin (bib16) 1997; 78 Plewa, Sikora, Engoren (bib7) 1995; 2 Dybowski, Weller, Chang (bib19) 1996; 347 Kline, Israel, Michelson (bib9) 2001; 285 Morley, Giaimo, Maroszan (bib10) 1993; 148 Bhavani-Shankar, Kumar, Moseley (bib14) 1995; 11 |
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| Snippet | Noninvasive estimates of Paco2 are usually done by measuring exhaled carbon dioxide at end-expiration (Petco2). While commonly used in studies involving... Introduction: Noninvasive estimates of Pa co 2 are usually done by measuring exhaled carbon dioxide at end-expiration (Pet co 2 ). While commonly used in... Noninvasive estimates of Paco(2) are usually done by measuring exhaled carbon dioxide at end-expiration (Petco(2)). While commonly used in studies involving... |
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| SubjectTerms | Adult Aged Algorithms capnography Capnography - statistics & numerical data Carbon Dioxide - blood computer programs Computer Simulation Coronary Disease - diagnosis Coronary Disease - physiopathology Data Collection - statistics & numerical data end-tidal CO2 Female genetic algorithms Humans Lung Diseases - diagnosis Lung Diseases - physiopathology Male Mathematical Computing Middle Aged Models, Genetic Oximetry - statistics & numerical data Paco2 Pulmonary Disease, Chronic Obstructive - diagnosis Pulmonary Disease, Chronic Obstructive - physiopathology Reference Values Sensitivity and Specificity Signal Processing, Computer-Assisted Smoking - adverse effects Smoking - physiopathology Software |
| Title | Evaluation of Capnography Using a Genetic Algorithm To Predict Paco2 |
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