Title :
Improvement of mini-bolus thermodilution using an optimal subspace-based matrix filter
Author :
Semnani, RJ ; Womack, BF ; Diller, KR
Author_Institution :
Electr. & Biomed. Eng. Dept., Texas Univ., Austin, TX, USA
Abstract :
Cardiac output estimation by thermodilution is the cornerstone of hemodynamic monitoring in the intensive-care setting. However, the clinical utility of thermodilution has been hampered by the application of heat as the indicator. The major source of error in thermodilution is the pulmonary artery thermal noise arising from respiration, cardiac contractions and Mayer waves. To obtain an acceptable signal-to-noise ratio, improve precision and bias, 3-7 measurements using 10 cc iced or room-temperature injectate are averaged. This limits applicability of thermodilution to intermittent CO monitoring due to possible risks to the patient. The authors describe the application of a subspace decomposition based optimal signal enhancement method to mini-bolus thermodilution signals as small as 1 cc
Keywords :
biothermics; cardiology; haemodynamics; medical signal processing; patient care; patient monitoring; Mayer waves; acceptable signal-to-noise ratio; cardiac contractions; heart performance indicator; hemodynamic monitoring; iced injectate; intensive-care setting; mini-bolus thermodilution improvement; optimal subspace-based matrix filter; pulmonary artery thermal noise; respiration; room-temperature injectate; Arteries; Biomedical engineering; Blood; Equations; Filters; Frequency; Heart; Matrix decomposition; Signal to noise ratio; Temperature;
Conference_Titel :
Computers in Cardiology 1998
Conference_Location :
Cleveland, OH
Print_ISBN :
0-7803-5200-9
DOI :
10.1109/CIC.1998.731965
