- Email: [email protected]
Bedside temporary transvenous cardiac pacemaker placement
Journal Pre-proof Bedside temporary transvenous cardiac pacemaker placement
Meng Liu, Xiaotong Han PII:
S0735-6757(19)30804-6
DOI:
https://doi.org/10.1016/j.ajem.2019.12.013
Reference:
YAJEM 158641
To appear in:
American Journal of Emergency Medicine
Received date:
21 October 2019
Revised date:
23 November 2019
Accepted date:
3 December 2019
Please cite this article as: M. Liu and X. Han, Bedside temporary transvenous cardiac pacemaker placement, American Journal of Emergency Medicine(2018), https://doi.org/ 10.1016/j.ajem.2019.12.013
This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
© 2018 Published by Elsevier.
Journal Pre-proof
Bedside Temporary Transvenous Cardiac Pacemaker Placement
Meng Liu, MD
2.
Xiaotong Han, MD
Key
words:
of
1.
pacing,
Temporary
-p
ro
Temporary transvenous cardiac
lP
re
pacemaker, Intracavity electrocardiogram.
na
From Emergency Department, Hunan Provincial People’s Hospital,
Jo ur
Medical School of Hunan Normal University, Changsha, China.
Correspondence to Meng Liu , Emergency Department, Hunan Provincial People’s Hospital, Medical School of Hunan Normal University.
Address:
No.
61,
Jiefang
Road,
Changsha,
[email protected] TEL +86 15084858606
China.
Email:
Journal Pre-proof
Jo ur
na
lP
re
-p
ro
of
Bedside Temporary Transvenous Cardiac Pacemaker Placement
Journal Pre-proof
Bedside Temporary Transvenous Cardiac Pacemaker Placement
of
Abstract: Temporary transvenous cardiac pacing is a life-saving
by
intracavitary
electrocardiogram
(IC-ECG),
instead
of
re
guided
-p
ro
procedure in an emergency. Transvenous cardiac pacing catheterization
lP
fluoroscope, is practical. Tips for controlling the orientation of the pacing
bedside
temporary
Jo ur
make
na
catheter tip and utilizing IC-ECG to monitor the positions of electrodes transvenous
cardiac
pacing
catheter
placement feasible and ‘ visible ’ . The technique discussed here is comparable to the operation under fluoroscopy,but without exposure to X-ray.
Introduction
Journal Pre-proof
With a decline in the number of temporary transvenous cardiac pacing (TVCP) procedures clinically performed, the opportunity to learn and teach this skill is becoming increasingly scarce [1]. Nonetheless, it is a
of
core emergency procedure [2]. TVCP involves placing a TVCP catheter
ro
into right side of the heart. Usually, the procedure is performed as
-p
followed: establishing central venous access; inserting introducer sheath;
lP
re
advancing TVCP catheter in venous system through the sheath;
na
touching endocardium of right ventricle wall with TVCP catheter tip.
Jo ur
Bedside atrial TVCP can only be recommended for anti-tachycardia pacing because of its instability.
Extensively used bipolar TVCP catheter tip has two electrodes which are about 1 cm apart (Figure 1). Distal electrode is negative (-) and active, proximal electrode is positive (+) and indifferent. For bedside TVCP catheter placement, 6 Fr in size non-floating catheter ( Figure 1 )
Journal Pre-proof
facilitates manipulation and not prone to dislocation if properly placed.
Establishing central venous access under ultrasound guidance is secure and has a low rate of complications [2]. Emergency cases with indication
of
for TVCP usually come with central venous distention which makes
ro
cannulation easy.
re
-p
Catheterization Technique of Temporary Transvenous Cardiac Pacing
electrodes
of
pacing
na
monitoring
lP
Controlling the direction of catheter tip (Figure 1) combined with catheter
tip
by
intracavitary
‘visible’.
Jo ur
electrocardiogram (IC-ECG) (Figure 2,3) makes bedside placement
Ideally, there should be a 20-30° curve at the catheter tip [3]. If difficulty is experienced in crossing the tricuspid valve, remove the catheter and try fashioning a different curve [3]. Orifice of the tricuspid valve necessitates leftward of the catheter tip [3]. Controls tip orientation by
Journal Pre-proof
turning the loops (Figure 1). Therefore, TVCP catheter tip orientation can be manipulated accurately no matter which venous access is chosen, right jugular or right subclavian vein. The loops direction determines the
of
catheter tip orientation. Inserted length of the catheter could help
ro
estimate the position of the catheter tip. In the meantime, IC-ECG
re
-p
provides more precise position of catheter tip.
lP
Pacing catheterization guided by IC-ECG has been practiced for half a
na
century [4]. The appearance of a characteristic right ventricular
Jo ur
endocardial complex recorded from the catheter tip is the most reliable guide to proper electrode placement [5]. Traditional IC-ECG guiding TVCP catheter insertion requires that the distal electrode from the end of the catheter be attached to any one of the precordial (V) leads on the ECG machine by an alligator clip or adapter. The adapter is supplied in some kit of TVCP catheter. Limbs electrodes are routinely connected.
Journal Pre-proof
The V lead which connects distal tip of TVCP catheter is monitored (Figure 2). As TVCP catheter approaches right atrium, the amplitude of P waves increases progressively; as TVCP catheter approaches the
of
right ventricular wall, QRS amplitude increases progressively. When the
ro
catheter enters the ventricle, the QRS amplitude increases markedly.
-p
When the catheter tip touches the endocardial surface, ST-segment
lP
re
elevation (STEMI pattern) is seen. The highest QRS amplitude appears
na
when tip against the thickest ventricle wall which usually is the apex.
Jo ur
Jeffrey etc. suggested that TVCP catheter should be positioned against the ventricular wall to achieve <2 mV of ST elevation (Figure 2 F) [6]. Marked ST elevation (Figure 2 G) has been suggested as a characteristic sign of myocardial perforation [7].
Three kinds of catheter malposition shown in Figure 3 B, C & D, E are rare but should be paid attention to. Catheter malposition in the coronary
Journal Pre-proof
veins may not be recognized even under fluoroscope, however, IC-ECG provides a quick, reliable method to identify it [5]. By traditional single distal electrode IC-ECG [4], it may be difficult for the operator to identify
of
malposition in those situations in Figure 3 C & D, E. ’Current of injury’
ro
can be recorded when electrode contacts with the atrial or ventricular
-p
endocardium, PR (atrial) elevation or STEMI pattern (ventricular). PR
lP
re
elevation could be mistaken as STEMI pattern (Figure 3 C & D). STEMI
na
pattern of distal electrode IC-ECG only guarantees the tip to contact
E).
Jo ur
ventricle wall which includes entrapped in chordae tendineae (Figure 3
We use both distal (-) and proximal (+) electrodes which can be attached to any two of the V leads, record as V(-) and V(+). Monitoring positions of the electrodes by V(-) and V(+) could provide more information about the tip position. Comparing the QRS amplitudes between V(-) and V(+),
Journal Pre-proof
when catheter tip enters right ventricle chamber: the case of V(-) > V(+) infers tip toward apex ventricle wall (Figure 3 A); conversely, the case of V(-)
of
Monitoring both V(-) and V(+) helps distinguish PR elevation (Figure 3 C
ro
& D) to STEMI pattern and identify catheter tip entrapped in chordae
re
-p
tendineae (Figure 3 E).
lP
After IC-ECG guiding placement which assures TVCP catheter tip
na
contacting properly with the ventricle wall, setting the pacing parameters
Jo ur
would be simple. Parameters include heart rate, sense and output. Default sense setting as 2 mV usually does not need to adjust. Premier cause of sensing and pacing malfunction is catheter dislocation. It can be identified by IC-ECG if temporary pacemaker could disconnect for a while. Pacing threshold usually is less than 1 mA [8], default output setting as 3-4 mA would be appropriate, whereas a few pathological
Journal Pre-proof
situations, such as myocarditis, pacing threshold may be more than 5 mA.
Technique Summary
of
After establishing central venous access and placing introducer sheath,
ro
bedside TVCP catheterization can be practiced with following skills:
re
-p
furnishing TVCP catheter tip an appropriate curve, coiling the catheter
lP
as 2-3 loops, and manipulating loops to control catheter tip direction;
na
estimating catheter tip position according to inserted length and
Discussion
Jo ur
precisely locating catheter tip by bipolar IC-ECG monitoring.
The use of fluoroscopy to guide TVCP catheterization is desirable from a technical point of view, but it may not be practical or available in the acute care setting. 5 Fr flexible, balloon flotation catheters are most commonly used in emergency cases [8, 9]. Guidance was attained by
Journal Pre-proof
using continuous ECG monitoring or by IC-ECG of a distal lead [8, 9]. Benefit of balloon flotation catheter is that forward blood flow guides the balloon through the venous system into the right ventricle. Then the
of
catheter tip is required to be placed in a stable position, the right
ro
ventricle apex. But forward blood flow tends to guide balloon catheter tip
-p
to the right ventricular outflow tract. Though balloon flotation catheters
lP
re
may help to reduce procedure time and improve positioning under
na
fluoroscopic guidance [10], Nicole et al. reported: without fluoroscopic
Jo ur
visualization, only 44% (n=39) of catheters tips were in the apex of the right ventricle [9]. 5 Fr balloon flotation catheter tends to be curled, and too flexible to be manipulated as 6 Fr non-floating catheter.
With technique tips discussed above, 6 Fr non-floating catheter is practical for bedside insertion. For the patient in cardiac arrest, balloon flotation catheter carries no benefit. And blind insertion of a 6 Fr non-
Journal Pre-proof
floating catheter by direction control tips described in Figure 1 would be the best choice. Traditional single distal electrode IC-ECG indicates the lead location [4], included in ventricle or contacting ventricle wall (Figure
of
2), but it cannot distinguish right ventricular apex from elsewhere in the
ro
right ventricle. The bipolar IC-ECG provides adequate information about
-p
the tip position (Figure 2, 3), which is comparable to fluoroscopic
lP
re
visualization. With no exposure to X-ray, consequently it may encourage
na
more physicians to learn this skill.
Reference
Jo ur
Conflict of interest: None.
[1] Sharma S, Sandler B, Cristopoulos C, Saraf S, Markides V, Gorog DA. Temporary transvenous pacing: endangered skill. Emerg Med J. 2012; 29:926-7. https://doi:10.1136/emermed-2011-200044
[2] O'Leary R, Ahmed SM, McLure H, Oram J, Mallick A, Bhambra B, et
Journal Pre-proof
al. Ultrasound-guided infraclavicular axillary vein cannulation: a useful alternative to the internal jugular vein. Br J Anaesth. 2012; 109:762-8. https://doi:10.1093/bja/aes262
of
[3] Fitzpatrick A, Sutton R. A guide to temporary pacing. BMJ. 1992;
ro
304:365-9. https://doi:10.1136/bmj.304.6823.365
re
-p
[4] Bing OH, McDowell JW, Hantman J and Messer JV. Pacemaker
lP
placement by electrocardiographic monitoring. N Engl J Med. 1972;
na
287:651. https://doi:10.1056/NEJM197209282871309
Jo ur
[5] Gulotta SJ. Transvenous cardiac pacing. Technics for optimal electrode positioning and prevention of coronary sinus placement.
Circulation. 1970; 42:701-18. https://doi:10.1161/01.cir.42.4.701
[6] Goldberger J, Kruse J, Ehlert FA, Kadish A. Temporary transvenous pacemaker placement: what criteria constitute an adequate pacing site?
Am Heart J. 1993; 126:488-93. https://doi:10.1016/0002-8703(93)91083-
Journal Pre-proof
q
[7] Mond HG, Stuckey JG, Sloman G. The diagnosis of right ventricular perforation by an endocardial pacemaker electrode. Pacing Clin
Electrophysiol.
1:62-7.
https://doi:10.1111/j.1540-
of
1978;
ro
8159.1978.tb03442.x
re
-p
[8] Gangathimmaiah V. Emergency transvenous cardiac pacing. Emerg
lP
Med Australas. 2017; 29:229-232. https://doi:10.1111/1742-6723.12757
na
[9] Piela N, Kornweiss S, Sacchetti A, Gallagher A, Abrams A. Outcomes
Jo ur
of emergency department placement of transvenous pacemakers. Am J Emerg Med 2016;34(8):1411-4. https://doi: 10.1016/j.ajem.2016.04.017
[10] Ferguson JD, Banning AP, Bashir Y. Randomised trial of temporary cardiac pacing with semirigid and balloon-flotation electrode catheters. Lancet.
1997;349(9069):1883.
6736(97)24026-2
https://doi:10.1016/S0140-
Journal Pre-proof
Author Contribution Statement
Meng Liu:Conceptualization and draft writing.
Jo ur
na
lP
re
-p
ro
of
Xiaotong Han: Supervision.
Journal Pre-proof
Caption 1
Tips for Control Catheter Direction.
Inserting TVCP catheter through right subclavian vein. The catheter tip
of
orients to right at beginning. When catheter tip approaching right atrium,
ro
which could estimate by inserted length or/and monitor by IC-ECG,
re
-p
change the tip orientation to left by flipping the loops. The angle of loops
Jo ur
na
lP
turning is exactly the one of the catheter rotating.
Journal Pre-proof
Caption 2
Typical Intracavity-ECG
A, Superior vena cava; B, High right atrium to mid right atrium; C, Inferior
of
vena cava; D, Crossing tricuspid valves; E, Right ventricle (Free); F,
Jo ur
na
lP
re
-p
touching wall). F & G, STEMI pattern.
ro
Right ventricle (Contact wall); G, Right ventricle (Against or continue
Journal Pre-proof
Caption 3
Bipolar Intracavity-ECG Avoid Malposition of Pacing Catheter.
A. Catheter tip is properly located. V(-) STEMI pattern, ST-segment
of
elevate slightly (<2 mV) indicate distal tip contact properly with ventricle
ro
wall; V(+) QRS amplitude remarkedly high and QS inscribed indicate
re
-p
proximal tip nearby but not touch with ventricle wall. B. Catheter enters
lP
mid coronary sinus. C & D. Catheter tip against atrium wall. V(-) PR
na
elevate is similar with STEMI pattern, V(+) no remarkedly high amplitude
Jo ur
waves indicates catheter tip does not enter in ventricle. Synchronized V4 could help to distinguish P and QRS waves easily. E. Catheter tip entrapped in chordae tendineae. V(-) P waves vanish, QRS amplitude remarkedly increases, and then big R wave indicate catheter tip leaves atrium, enters ventricle and against ventricle wall. V(+) P waves vanish, QRS amplitude do not increases remarkedly indicate proximal electrode
Journal Pre-proof
Jo ur
na
lP
re
-p
ro
of
leaves atrium but not enters ventricle.
Figure 1
Figure 2
Figure 3
Meng Liu, Xiaotong Han PII:
S0735-6757(19)30804-6
DOI:
https://doi.org/10.1016/j.ajem.2019.12.013
Reference:
YAJEM 158641
To appear in:
American Journal of Emergency Medicine
Received date:
21 October 2019
Revised date:
23 November 2019
Accepted date:
3 December 2019
Please cite this article as: M. Liu and X. Han, Bedside temporary transvenous cardiac pacemaker placement, American Journal of Emergency Medicine(2018), https://doi.org/ 10.1016/j.ajem.2019.12.013
This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
© 2018 Published by Elsevier.
Journal Pre-proof
Bedside Temporary Transvenous Cardiac Pacemaker Placement
Meng Liu, MD
2.
Xiaotong Han, MD
Key
words:
of
1.
pacing,
Temporary
-p
ro
Temporary transvenous cardiac
lP
re
pacemaker, Intracavity electrocardiogram.
na
From Emergency Department, Hunan Provincial People’s Hospital,
Jo ur
Medical School of Hunan Normal University, Changsha, China.
Correspondence to Meng Liu , Emergency Department, Hunan Provincial People’s Hospital, Medical School of Hunan Normal University.
Address:
No.
61,
Jiefang
Road,
Changsha,
[email protected] TEL +86 15084858606
China.
Email:
Journal Pre-proof
Jo ur
na
lP
re
-p
ro
of
Bedside Temporary Transvenous Cardiac Pacemaker Placement
Journal Pre-proof
Bedside Temporary Transvenous Cardiac Pacemaker Placement
of
Abstract: Temporary transvenous cardiac pacing is a life-saving
by
intracavitary
electrocardiogram
(IC-ECG),
instead
of
re
guided
-p
ro
procedure in an emergency. Transvenous cardiac pacing catheterization
lP
fluoroscope, is practical. Tips for controlling the orientation of the pacing
bedside
temporary
Jo ur
make
na
catheter tip and utilizing IC-ECG to monitor the positions of electrodes transvenous
cardiac
pacing
catheter
placement feasible and ‘ visible ’ . The technique discussed here is comparable to the operation under fluoroscopy,but without exposure to X-ray.
Introduction
Journal Pre-proof
With a decline in the number of temporary transvenous cardiac pacing (TVCP) procedures clinically performed, the opportunity to learn and teach this skill is becoming increasingly scarce [1]. Nonetheless, it is a
of
core emergency procedure [2]. TVCP involves placing a TVCP catheter
ro
into right side of the heart. Usually, the procedure is performed as
-p
followed: establishing central venous access; inserting introducer sheath;
lP
re
advancing TVCP catheter in venous system through the sheath;
na
touching endocardium of right ventricle wall with TVCP catheter tip.
Jo ur
Bedside atrial TVCP can only be recommended for anti-tachycardia pacing because of its instability.
Extensively used bipolar TVCP catheter tip has two electrodes which are about 1 cm apart (Figure 1). Distal electrode is negative (-) and active, proximal electrode is positive (+) and indifferent. For bedside TVCP catheter placement, 6 Fr in size non-floating catheter ( Figure 1 )
Journal Pre-proof
facilitates manipulation and not prone to dislocation if properly placed.
Establishing central venous access under ultrasound guidance is secure and has a low rate of complications [2]. Emergency cases with indication
of
for TVCP usually come with central venous distention which makes
ro
cannulation easy.
re
-p
Catheterization Technique of Temporary Transvenous Cardiac Pacing
electrodes
of
pacing
na
monitoring
lP
Controlling the direction of catheter tip (Figure 1) combined with catheter
tip
by
intracavitary
‘visible’.
Jo ur
electrocardiogram (IC-ECG) (Figure 2,3) makes bedside placement
Ideally, there should be a 20-30° curve at the catheter tip [3]. If difficulty is experienced in crossing the tricuspid valve, remove the catheter and try fashioning a different curve [3]. Orifice of the tricuspid valve necessitates leftward of the catheter tip [3]. Controls tip orientation by
Journal Pre-proof
turning the loops (Figure 1). Therefore, TVCP catheter tip orientation can be manipulated accurately no matter which venous access is chosen, right jugular or right subclavian vein. The loops direction determines the
of
catheter tip orientation. Inserted length of the catheter could help
ro
estimate the position of the catheter tip. In the meantime, IC-ECG
re
-p
provides more precise position of catheter tip.
lP
Pacing catheterization guided by IC-ECG has been practiced for half a
na
century [4]. The appearance of a characteristic right ventricular
Jo ur
endocardial complex recorded from the catheter tip is the most reliable guide to proper electrode placement [5]. Traditional IC-ECG guiding TVCP catheter insertion requires that the distal electrode from the end of the catheter be attached to any one of the precordial (V) leads on the ECG machine by an alligator clip or adapter. The adapter is supplied in some kit of TVCP catheter. Limbs electrodes are routinely connected.
Journal Pre-proof
The V lead which connects distal tip of TVCP catheter is monitored (Figure 2). As TVCP catheter approaches right atrium, the amplitude of P waves increases progressively; as TVCP catheter approaches the
of
right ventricular wall, QRS amplitude increases progressively. When the
ro
catheter enters the ventricle, the QRS amplitude increases markedly.
-p
When the catheter tip touches the endocardial surface, ST-segment
lP
re
elevation (STEMI pattern) is seen. The highest QRS amplitude appears
na
when tip against the thickest ventricle wall which usually is the apex.
Jo ur
Jeffrey etc. suggested that TVCP catheter should be positioned against the ventricular wall to achieve <2 mV of ST elevation (Figure 2 F) [6]. Marked ST elevation (Figure 2 G) has been suggested as a characteristic sign of myocardial perforation [7].
Three kinds of catheter malposition shown in Figure 3 B, C & D, E are rare but should be paid attention to. Catheter malposition in the coronary
Journal Pre-proof
veins may not be recognized even under fluoroscope, however, IC-ECG provides a quick, reliable method to identify it [5]. By traditional single distal electrode IC-ECG [4], it may be difficult for the operator to identify
of
malposition in those situations in Figure 3 C & D, E. ’Current of injury’
ro
can be recorded when electrode contacts with the atrial or ventricular
-p
endocardium, PR (atrial) elevation or STEMI pattern (ventricular). PR
lP
re
elevation could be mistaken as STEMI pattern (Figure 3 C & D). STEMI
na
pattern of distal electrode IC-ECG only guarantees the tip to contact
E).
Jo ur
ventricle wall which includes entrapped in chordae tendineae (Figure 3
We use both distal (-) and proximal (+) electrodes which can be attached to any two of the V leads, record as V(-) and V(+). Monitoring positions of the electrodes by V(-) and V(+) could provide more information about the tip position. Comparing the QRS amplitudes between V(-) and V(+),
Journal Pre-proof
when catheter tip enters right ventricle chamber: the case of V(-) > V(+) infers tip toward apex ventricle wall (Figure 3 A); conversely, the case of V(-)
of
Monitoring both V(-) and V(+) helps distinguish PR elevation (Figure 3 C
ro
& D) to STEMI pattern and identify catheter tip entrapped in chordae
re
-p
tendineae (Figure 3 E).
lP
After IC-ECG guiding placement which assures TVCP catheter tip
na
contacting properly with the ventricle wall, setting the pacing parameters
Jo ur
would be simple. Parameters include heart rate, sense and output. Default sense setting as 2 mV usually does not need to adjust. Premier cause of sensing and pacing malfunction is catheter dislocation. It can be identified by IC-ECG if temporary pacemaker could disconnect for a while. Pacing threshold usually is less than 1 mA [8], default output setting as 3-4 mA would be appropriate, whereas a few pathological
Journal Pre-proof
situations, such as myocarditis, pacing threshold may be more than 5 mA.
Technique Summary
of
After establishing central venous access and placing introducer sheath,
ro
bedside TVCP catheterization can be practiced with following skills:
re
-p
furnishing TVCP catheter tip an appropriate curve, coiling the catheter
lP
as 2-3 loops, and manipulating loops to control catheter tip direction;
na
estimating catheter tip position according to inserted length and
Discussion
Jo ur
precisely locating catheter tip by bipolar IC-ECG monitoring.
The use of fluoroscopy to guide TVCP catheterization is desirable from a technical point of view, but it may not be practical or available in the acute care setting. 5 Fr flexible, balloon flotation catheters are most commonly used in emergency cases [8, 9]. Guidance was attained by
Journal Pre-proof
using continuous ECG monitoring or by IC-ECG of a distal lead [8, 9]. Benefit of balloon flotation catheter is that forward blood flow guides the balloon through the venous system into the right ventricle. Then the
of
catheter tip is required to be placed in a stable position, the right
ro
ventricle apex. But forward blood flow tends to guide balloon catheter tip
-p
to the right ventricular outflow tract. Though balloon flotation catheters
lP
re
may help to reduce procedure time and improve positioning under
na
fluoroscopic guidance [10], Nicole et al. reported: without fluoroscopic
Jo ur
visualization, only 44% (n=39) of catheters tips were in the apex of the right ventricle [9]. 5 Fr balloon flotation catheter tends to be curled, and too flexible to be manipulated as 6 Fr non-floating catheter.
With technique tips discussed above, 6 Fr non-floating catheter is practical for bedside insertion. For the patient in cardiac arrest, balloon flotation catheter carries no benefit. And blind insertion of a 6 Fr non-
Journal Pre-proof
floating catheter by direction control tips described in Figure 1 would be the best choice. Traditional single distal electrode IC-ECG indicates the lead location [4], included in ventricle or contacting ventricle wall (Figure
of
2), but it cannot distinguish right ventricular apex from elsewhere in the
ro
right ventricle. The bipolar IC-ECG provides adequate information about
-p
the tip position (Figure 2, 3), which is comparable to fluoroscopic
lP
re
visualization. With no exposure to X-ray, consequently it may encourage
na
more physicians to learn this skill.
Reference
Jo ur
Conflict of interest: None.
[1] Sharma S, Sandler B, Cristopoulos C, Saraf S, Markides V, Gorog DA. Temporary transvenous pacing: endangered skill. Emerg Med J. 2012; 29:926-7. https://doi:10.1136/emermed-2011-200044
[2] O'Leary R, Ahmed SM, McLure H, Oram J, Mallick A, Bhambra B, et
Journal Pre-proof
al. Ultrasound-guided infraclavicular axillary vein cannulation: a useful alternative to the internal jugular vein. Br J Anaesth. 2012; 109:762-8. https://doi:10.1093/bja/aes262
of
[3] Fitzpatrick A, Sutton R. A guide to temporary pacing. BMJ. 1992;
ro
304:365-9. https://doi:10.1136/bmj.304.6823.365
re
-p
[4] Bing OH, McDowell JW, Hantman J and Messer JV. Pacemaker
lP
placement by electrocardiographic monitoring. N Engl J Med. 1972;
na
287:651. https://doi:10.1056/NEJM197209282871309
Jo ur
[5] Gulotta SJ. Transvenous cardiac pacing. Technics for optimal electrode positioning and prevention of coronary sinus placement.
Circulation. 1970; 42:701-18. https://doi:10.1161/01.cir.42.4.701
[6] Goldberger J, Kruse J, Ehlert FA, Kadish A. Temporary transvenous pacemaker placement: what criteria constitute an adequate pacing site?
Am Heart J. 1993; 126:488-93. https://doi:10.1016/0002-8703(93)91083-
Journal Pre-proof
q
[7] Mond HG, Stuckey JG, Sloman G. The diagnosis of right ventricular perforation by an endocardial pacemaker electrode. Pacing Clin
Electrophysiol.
1:62-7.
https://doi:10.1111/j.1540-
of
1978;
ro
8159.1978.tb03442.x
re
-p
[8] Gangathimmaiah V. Emergency transvenous cardiac pacing. Emerg
lP
Med Australas. 2017; 29:229-232. https://doi:10.1111/1742-6723.12757
na
[9] Piela N, Kornweiss S, Sacchetti A, Gallagher A, Abrams A. Outcomes
Jo ur
of emergency department placement of transvenous pacemakers. Am J Emerg Med 2016;34(8):1411-4. https://doi: 10.1016/j.ajem.2016.04.017
[10] Ferguson JD, Banning AP, Bashir Y. Randomised trial of temporary cardiac pacing with semirigid and balloon-flotation electrode catheters. Lancet.
1997;349(9069):1883.
6736(97)24026-2
https://doi:10.1016/S0140-
Journal Pre-proof
Author Contribution Statement
Meng Liu:Conceptualization and draft writing.
Jo ur
na
lP
re
-p
ro
of
Xiaotong Han: Supervision.
Journal Pre-proof
Caption 1
Tips for Control Catheter Direction.
Inserting TVCP catheter through right subclavian vein. The catheter tip
of
orients to right at beginning. When catheter tip approaching right atrium,
ro
which could estimate by inserted length or/and monitor by IC-ECG,
re
-p
change the tip orientation to left by flipping the loops. The angle of loops
Jo ur
na
lP
turning is exactly the one of the catheter rotating.
Journal Pre-proof
Caption 2
Typical Intracavity-ECG
A, Superior vena cava; B, High right atrium to mid right atrium; C, Inferior
of
vena cava; D, Crossing tricuspid valves; E, Right ventricle (Free); F,
Jo ur
na
lP
re
-p
touching wall). F & G, STEMI pattern.
ro
Right ventricle (Contact wall); G, Right ventricle (Against or continue
Journal Pre-proof
Caption 3
Bipolar Intracavity-ECG Avoid Malposition of Pacing Catheter.
A. Catheter tip is properly located. V(-) STEMI pattern, ST-segment
of
elevate slightly (<2 mV) indicate distal tip contact properly with ventricle
ro
wall; V(+) QRS amplitude remarkedly high and QS inscribed indicate
re
-p
proximal tip nearby but not touch with ventricle wall. B. Catheter enters
lP
mid coronary sinus. C & D. Catheter tip against atrium wall. V(-) PR
na
elevate is similar with STEMI pattern, V(+) no remarkedly high amplitude
Jo ur
waves indicates catheter tip does not enter in ventricle. Synchronized V4 could help to distinguish P and QRS waves easily. E. Catheter tip entrapped in chordae tendineae. V(-) P waves vanish, QRS amplitude remarkedly increases, and then big R wave indicate catheter tip leaves atrium, enters ventricle and against ventricle wall. V(+) P waves vanish, QRS amplitude do not increases remarkedly indicate proximal electrode
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Jo ur
na
lP
re
-p
ro
of
leaves atrium but not enters ventricle.
Figure 1
Figure 2
Figure 3