Changes in left ventricular ejection time and pulse transit time derived from finger photoplethysmogram and electrocardiogram during moderate haemorrhage

Summary Objectives: Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger photoplethysmographic (PPG) waveform derived left ventricular ejection time (LVETp) and pulse transit time (PTT) for detecting blood loss, b...

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Published in:	Clinical physiology and functional imaging Vol. 29; no. 3; pp. 163 - 169
Main Authors:	Middleton, Paul M., Chan, Gregory S.H., O'Lone, Emma, Steel, Elizabeth, Carroll, Rebecca, Celler, Branko G., Lovell, Nigel H.
Format:	Journal Article
Language:	English
Published:	Oxford, UK Blackwell Publishing Ltd 01-05-2009 Blackwell
Subjects:	Adult Biological and medical sciences blood donation Blood Donors Blood Pressure Electrocardiography Female Fingers - blood supply Fundamental and applied biological sciences. Psychology Heart Rate Hemorrhage - diagnosis Hemorrhage - physiopathology Humans hypovolaemia Male Middle Aged Monitoring, Physiologic - methods Photoplethysmography - methods pre-ejection period Predictive Value of Tests preload Prospective Studies pulse oximetry Stroke Volume systolic time intervals Time Factors Ventricular Function, Left Vertebrates: anatomy and physiology, studies on body, several organs or systems pulse oximetry systolic time intervals Vertebrata Systolic time interval Mammalia Finger Ventricular ejection Hemorrhage pre-ejection period preload blood donation hypovolaemia
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Abstract	Summary Objectives: Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger photoplethysmographic (PPG) waveform derived left ventricular ejection time (LVETp) and pulse transit time (PTT) for detecting blood loss, by using blood donation as a model of controlled mild to moderate haemorrhage. Methods: This was a prospective, observational study carried out in a convenience sample of blood donors. LVETp, PTT and R‐R interval (RRi) were computed from simultaneous measurement of the electrocardiogram (ECG) and the finger infrared photoplethysmogram obtained from 43 healthy volunteers during blood donation. The blood donation process was divided into four stages: (i) Pre‐donation (PRE), (ii) first half of donation (FIRST), (iii) second half of donation (SECOND), (iv) post‐donation (POST). Results and conclusions: Shortening of LVETp from 303+/−2 to 293+/−3 ms (mean+/−SEM; P<0·01) and prolongation of PTT from 177+/−3 to 186+/−4 ms (P<0·01) were observed in 81% and 91% of subjects respectively when comparing PRE and POST. During blood donation, progressive blood loss produced falling trends in LVETp (P<0·01) and rising trends in PTT (P<0·01) in FIRST and SECOND, but a falling trend in RRi (P<0·01) was only observed in SECOND. Monitoring trends in timing variables derived from non‐invasive ECG and finger PPG signals may facilitate detection of blood loss in the early phase.
AbstractList	Objectives:Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger photoplethysmographic (PPG) waveform derived left ventricular ejection time (LVETp) and pulse transit time (PTT) for detecting blood loss, by using blood donation as a model of controlled mild to moderate haemorrhage.Methods:This was a prospective, observational study carried out in a convenience sample of blood donors. LVETp, PTT and R-R interval (RRi) were computed from simultaneous measurement of the electrocardiogram (ECG) and the finger infrared photoplethysmogram obtained from 43 healthy volunteers during blood donation. The blood donation process was divided into four stages: (i) Pre-donation (PRE), (ii) first half of donation (FIRST), (iii) second half of donation (SECOND), (iv) post-donation (POST).Results and conclusions:Shortening of LVETp from 303+/-2 to 293+/-3ms (mean+/-SEM; P < 001) and prolongation of PTT from 177+/-3 to 186+/-4ms (P < 001) were observed in 81% and 91% of subjects respectively when comparing PRE and POST. During blood donation, progressive blood loss produced falling trends in LVETp (P < 001) and rising trends in PTT (P < 001) in FIRST and SECOND, but a falling trend in RRi (P < 0*01) was only observed in SECOND. Monitoring trends in timing variables derived from non-invasive ECG and finger PPG signals may facilitate detection of blood loss in the early phase. Summary Objectives: Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger photoplethysmographic (PPG) waveform derived left ventricular ejection time (LVETp) and pulse transit time (PTT) for detecting blood loss, by using blood donation as a model of controlled mild to moderate haemorrhage. Methods: This was a prospective, observational study carried out in a convenience sample of blood donors. LVETp, PTT and R‐R interval (RRi) were computed from simultaneous measurement of the electrocardiogram (ECG) and the finger infrared photoplethysmogram obtained from 43 healthy volunteers during blood donation. The blood donation process was divided into four stages: (i) Pre‐donation (PRE), (ii) first half of donation (FIRST), (iii) second half of donation (SECOND), (iv) post‐donation (POST). Results and conclusions: Shortening of LVETp from 303+/−2 to 293+/−3 ms (mean+/−SEM; P<0·01) and prolongation of PTT from 177+/−3 to 186+/−4 ms (P<0·01) were observed in 81% and 91% of subjects respectively when comparing PRE and POST. During blood donation, progressive blood loss produced falling trends in LVETp (P<0·01) and rising trends in PTT (P<0·01) in FIRST and SECOND, but a falling trend in RRi (P<0·01) was only observed in SECOND. Monitoring trends in timing variables derived from non‐invasive ECG and finger PPG signals may facilitate detection of blood loss in the early phase. OBJECTIVESEarly identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger photoplethysmographic (PPG) waveform derived left ventricular ejection time (LVET(p)) and pulse transit time (PTT) for detecting blood loss, by using blood donation as a model of controlled mild to moderate haemorrhage.METHODSThis was a prospective, observational study carried out in a convenience sample of blood donors. LVET(p), PTT and R-R interval (RRi) were computed from simultaneous measurement of the electrocardiogram (ECG) and the finger infrared photoplethysmogram obtained from 43 healthy volunteers during blood donation. The blood donation process was divided into four stages: (i) Pre-donation (PRE), (ii) first half of donation (FIRST), (iii) second half of donation (SECOND), (iv) post-donation (POST).RESULTS AND CONCLUSIONSShortening of LVET(p) from 303+/-2 to 293+/-3 ms (mean+/-SEM; P<0.01) and prolongation of PTT from 177+/-3 to 186+/-4 ms (P<0.01) were observed in 81% and 91% of subjects respectively when comparing PRE and POST. During blood donation, progressive blood loss produced falling trends in LVET(p) (P<0.01) and rising trends in PTT (P<0.01) in FIRST and SECOND, but a falling trend in RRi (P<0.01) was only observed in SECOND. Monitoring trends in timing variables derived from non-invasive ECG and finger PPG signals may facilitate detection of blood loss in the early phase. Objectives: Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger photoplethysmographic (PPG) waveform derived left ventricular ejection time (LVET p ) and pulse transit time (PTT) for detecting blood loss, by using blood donation as a model of controlled mild to moderate haemorrhage. Methods: This was a prospective, observational study carried out in a convenience sample of blood donors. LVET p , PTT and R‐R interval (RRi) were computed from simultaneous measurement of the electrocardiogram (ECG) and the finger infrared photoplethysmogram obtained from 43 healthy volunteers during blood donation. The blood donation process was divided into four stages: (i) Pre‐donation (PRE), (ii) first half of donation (FIRST), (iii) second half of donation (SECOND), (iv) post‐donation (POST). Results and conclusions: Shortening of LVET p from 303+/−2 to 293+/−3 ms (mean+/−SEM; P <0·01) and prolongation of PTT from 177+/−3 to 186+/−4 ms ( P <0·01) were observed in 81% and 91% of subjects respectively when comparing PRE and POST. During blood donation, progressive blood loss produced falling trends in LVET p ( P <0·01) and rising trends in PTT ( P <0·01) in FIRST and SECOND, but a falling trend in RRi ( P <0·01) was only observed in SECOND. Monitoring trends in timing variables derived from non‐invasive ECG and finger PPG signals may facilitate detection of blood loss in the early phase. Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger photoplethysmographic (PPG) waveform derived left ventricular ejection time (LVET(p)) and pulse transit time (PTT) for detecting blood loss, by using blood donation as a model of controlled mild to moderate haemorrhage. This was a prospective, observational study carried out in a convenience sample of blood donors. LVET(p), PTT and R-R interval (RRi) were computed from simultaneous measurement of the electrocardiogram (ECG) and the finger infrared photoplethysmogram obtained from 43 healthy volunteers during blood donation. The blood donation process was divided into four stages: (i) Pre-donation (PRE), (ii) first half of donation (FIRST), (iii) second half of donation (SECOND), (iv) post-donation (POST). Shortening of LVET(p) from 303+/-2 to 293+/-3 ms (mean+/-SEM; P<0.01) and prolongation of PTT from 177+/-3 to 186+/-4 ms (P<0.01) were observed in 81% and 91% of subjects respectively when comparing PRE and POST. During blood donation, progressive blood loss produced falling trends in LVET(p) (P<0.01) and rising trends in PTT (P<0.01) in FIRST and SECOND, but a falling trend in RRi (P<0.01) was only observed in SECOND. Monitoring trends in timing variables derived from non-invasive ECG and finger PPG signals may facilitate detection of blood loss in the early phase.
Author	O'Lone, Emma Celler, Branko G. Carroll, Rebecca Chan, Gregory S.H. Steel, Elizabeth Lovell, Nigel H. Middleton, Paul M.
Author_xml	– sequence: 1 givenname: Paul M. surname: Middleton fullname: Middleton, Paul M. organization: Emergency Department, Prince of Wales Hospital, Sydney, NSW – sequence: 2 givenname: Gregory S.H. surname: Chan fullname: Chan, Gregory S.H. organization: Biomedical Systems Laboratory, School of Electrical Engineering and Telecommunications, University of New South Wales, Sydney, NSW – sequence: 3 givenname: Emma surname: O'Lone fullname: O'Lone, Emma organization: Intensive Care Unit, Prince of Wales Hospital, Sydney, NSW, Australia – sequence: 4 givenname: Elizabeth surname: Steel fullname: Steel, Elizabeth organization: Intensive Care Unit, Prince of Wales Hospital, Sydney, NSW, Australia – sequence: 5 givenname: Rebecca surname: Carroll fullname: Carroll, Rebecca organization: Emergency Department, Prince of Wales Hospital, Sydney, NSW – sequence: 6 givenname: Branko G. surname: Celler fullname: Celler, Branko G. organization: Biomedical Systems Laboratory, School of Electrical Engineering and Telecommunications, University of New South Wales, Sydney, NSW – sequence: 7 givenname: Nigel H. surname: Lovell fullname: Lovell, Nigel H. organization: Biomedical Systems Laboratory, School of Electrical Engineering and Telecommunications, University of New South Wales, Sydney, NSW
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Keywords	pulse oximetry systolic time intervals Vertebrata Systolic time interval Mammalia Finger Ventricular ejection Hemorrhage pre-ejection period preload blood donation hypovolaemia
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Snippet	Summary Objectives: Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger... Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger... Objectives: Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger... Objectives:Early identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger... OBJECTIVESEarly identification of haemorrhage is difficult when a bleeding site is not apparent. This study explored the potential use of the finger...
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SubjectTerms	Adult Biological and medical sciences blood donation Blood Donors Blood Pressure Electrocardiography Female Fingers - blood supply Fundamental and applied biological sciences. Psychology Heart Rate Hemorrhage - diagnosis Hemorrhage - physiopathology Humans hypovolaemia Male Middle Aged Monitoring, Physiologic - methods Photoplethysmography - methods pre-ejection period Predictive Value of Tests preload Prospective Studies pulse oximetry Stroke Volume systolic time intervals Time Factors Ventricular Function, Left Vertebrates: anatomy and physiology, studies on body, several organs or systems
Title	Changes in left ventricular ejection time and pulse transit time derived from finger photoplethysmogram and electrocardiogram during moderate haemorrhage
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