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Transcript 
Electrical Impedance Tomography for lung
recruitment monitoring
— Technical aspects of clinical
usage and interpretation
Karel Roubík, Vladimír Sobota
Faculty of Biomedical Engineering
Czech Technical University in Prague, Czech Republic
[email protected], www.ventilation.cz
Electrical impedance tomography
Monitoring of ventilation:
+ noninvasive, + bedside, + continuous, + no using ionizing radiation,
+ relatively inexpensive,
+ ... + “modern”
EIT systems currently used in lung ventilation monitoring
Number of Electrodes
Electrode Belt
Maltron Sheffield Mk 3.5
8
NO
Goe MF II
16
NO
Dräger PulmoVista 500
16
YES, rubber
Timpel Enlight
32
YES, rubber
Swisstom‐based devices
32
YES, textile
EIT System
EIT systems currently used in lung
ventilation monitoring
Maltron Sheffield Mk 3.5
Goe MF II
EIT systems currently used in lung ventilation monitoring
Dräger PulmoVista 500
Timpel Enlight (Brasil)
EIT systems currently used in lung
ventilation monitoring
Swisstom BB2
Salvia Elisa 800 VIT Electrical impedance tomography
Monitoring of ventilation:
+ noninvasive, + bedside, + continuous, + no using ionizing radiation,
+ relatively inexpensive,
+ ... ‐ limitations, problems with evaluation and problems with EIT interpretation
Electrical impedance tomography
Monitoring of ventilation:
+ noninvasive, + bedside, + continuous, + no using ionizing radiation,
+ relatively inexpensive,
+ ... The aim of the presentation is to show how EIT can be used for lung recruitment evaluation and to show possible sources of error during EIT data processing.
Comparison of CT and EIT
Low spatial resolution of EIT—does it matter?
CT scan
EIT image
Contrast in the lung EIT image is directly proportional to the changes of the lung volume.
These changes in EIT image can be directly recalculated to changes in the lung volume. COULOMBE, N. et al. Physiol. Meas. 2005, 26, pp. 401‐411 Electrical Impedance Tomography
principles
Tomographic plane
Electrical Impedance Tomography
principles
Principle: Conductivity of lungs is strongly affected by presence of gas. The more gas in the lungs, the higher the lung resistance.
drop of
voltage
0
drop of
voltage
0
V
V
0
0
V
(( ))
U=R.I
V
high resistance
current source
current source
Principle: Measurement of impedances (resistances) of the lungs at different angles with a consequent image reconstruction similar to CT.
Principles of EIT
Low spatial resolution
X‐ray tube
electrode #1
electrode #2
X‐ray detector
• El. current preferably flows through regions with lowest resistance
• Resolution towards the center of the image decreases
Further increase in number of electrodes does not improve the image resolution significantly
Principles of EIT
Wide “U.F.O.‐disc‐like” tomographic plane
• The tomographic plane is more than 10 cm wide, the width increases with depth
• Contribution of impedance changes from neighboring organs (heart, stomach)
Stolen from Drëger
Courtesy of 365PSD.com
Data Acquisition
Placement of electrodes (when not integrated in a belt)
• Time consuming procedure
• The reconstruction algorithm assumes a certain (equidistant) position of electrodes—when electrodes are placed improperly, reconstruction errors occur
http://en.wikipedia.org/wiki/Electrical_impe
dance_tomography
Data Acquisition
Radial Rotation of the electrode belt
The image of electrode belt may be disturbing during X‐ray imaging—temporary repositioning of the electrode belt may cause its rotation Animal experiment (pigs)
with PulmoVista 500.
Data Acquisition
Radial Rotation of the electrode belt
Comparison of regional ventilation (in %) at layer‐defined regions of interest (ROIs) at a standard image and the same image rotated by 45°
9
16
39
35
47
37
5
12
Data Acquisition
Insufficient contact of one or more electrodes
Comparison of two images within the same breath cycle when the electrode placed at sternum lost its contact at maximum inspirium
Data Processing
In time domain
Relative Impedance (AU)
4000
2000
0
‐2000
‐4000
‐6000
‐8000
0
1
2
3
4
5
Time (min)
6
7
8
9
In spatial domain
Contrary to CT, evaluation of EIT image by looking at it does not work!
Image analysis is required. Data Processing
Selection of baseline
Change of color scale during PEEP steps—baseline in the beginning Inspirium
Expirium
Inspirium
Expirium
Relative Impedance (AU)
12000
10000
8000
6000
4000
2000
0
[B]
‐2000
0
1
2
3
4
5
Time (min)
6
7
8
9
Data Processing
Selection of baseline
Change of color scale during PEEP steps—baseline in the end
Inspirium
Expirium
Inspirium
Expirium
Relative Impedance (AU)
4000
2000
0
[B]
‐2000
‐4000
‐6000
‐8000
0
1
2
3
4
5
Time (min)
6
7
8
9
EIT in spatial domain
Regions Of Interest (ROIs)
Functional ROIs
• The edge criteria depend on the regional ventilatory function of the lungs
Standard deviation of relative impedance change of each pixel. The higher the SD, the brighter the grey color.
PULLETZ, S. et al. Physiol Meas 2006, 27, S115‐127
EIT in spatial domain
Regions Of Interest (ROIs)
Functional ROIs
• The edge criteria depend on the regional ventilatory function of the lungs
Values of linear regression coefficient calculated in each image pixel with pixel data as dependent variable and global (average) data as independent variable. The higher the value of the regression coefficient, the brighter the grey color.
PULLETZ, S. et al. Physiol Meas 2006, 27, S115‐127
EIT in spatial domain
Regions Of Interest (ROIs)
Arbitrary ROIs
• Defined as simple geometric objects
• Serve for calculation of regional ventilation (% of total VT)
Layers
Quadrants 1
Quadrants 2
Images by authors
PULLETZ, S. et al. Physiol Meas 2006, 27, S115‐127
EIT in spatial domain
EIT in morbidly obese patients
Distorted EIT images from a morbidly obese patient (top) at different PEEP levels and corresponding images from a normal weight patient (bottom).
ERLANDSSON, K. et al. Acta Anaesthesiol. Scand. 2006, 50, pp. 833‐839
EIT in spatial domain
Center of Ventilation (CoV)
„The Center of Ventilation (CoV) reflects the distribution of ventilation in ventral‐to‐dorsal direction“
TIV = Tidal Impedance Variation
BLANKMAN, P. et al. Critical Care 2014, 18:R95
VAN HEERDE, M. Acta Anaesthesiol Scand 2010; 54: 1248‐1256
EIT in spatial domain
Center of Gravity (CoG)
The Center of Gravity (CoG) is calculated as a weighted average of row / column sums.
Note: Authors frequently interchange the terms CoV
and CoG. Thus, in some articles CoV refers to CoG.
RADKE, O.C. et al. Anesthesiology 2012 Jun; 116(6): 1227‐1234
EIT in spatial domain
Regional Ventilation Delay
MUDERS, T. et al. Crit Care Med 2012, Vol. 40, No. 3
EIT in spatial domain
Regional Opening / Closing Pressure
PULLETZ, S. et al. J Crit Care. 2012 Jun, 27(3):323.e11‐8
EIT in spatial domain
Regional Compliance
Estimation of regional compliance helps to determine regional hyperdistension or collapse of lungs.
COSTA, E. L. V. et al. Intensive Care Med. 2009, 35, pp. 1132‐1137
EIT in time domain
Evaluation of lung recruitment
Example of recruitment maneuver. The difference in End‐Expiratory Lung Impedance (EELI) corresponds to the recruited parts of the lungs.
12000
Relative Impedance (AU)
10000
8000
6000
4000
2000
ΔEELI
0
0
20
40
60
80
Time (s)
100
120
140
160
180
EIT in time domain
Evaluation of lung recruitment
Example of recruitment maneuver failure. Probably insufficient PEEP unable to keep the lungs open.
12000
Relative Impedance (AU)
10000
8000
6000
4000
2000
ΔEELI
0
0
20
40
60
80
Time (s)
100
120
140
160
180
EIT ambiguities
Continuous drift not caused by atelectasis
60
ROI (%)
ROI 2
40
ROI 3
20
ROI 1
ROI 2
Relative Impedance (AU)
0
10000
8000
6000
4000
2000
0
0
5
10
15
20
25
Time
30
35
40
45
50
Conclusion
• EIT is an interesting imaging monitoring¹
modality offering real time information about lung ventilation. Data processing is necessary.
• EIT data always have to be interpreted depending on the actual situation and procedure (since EIT is a functional imaging).
• Due to the complex processing and recent fast development, a ‘Gold Standard’ of data processing and visualization is still missing.
¹ based on imaging
Conclusion
• EIT is an interesting imaging monitoring modality offering real time information about lung ventilation. Data processing is necessary.
• EIT data always have to be interpreted depending on the actual situation and procedure (since EIT is a functional imaging).
• Due to the complex processing and recent fast development, a ‘Gold Standard’ of data processing and visualization is still missing.
Thank you for your attention!
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