Post on 17-Aug-2019
CPR Algorithm : from present to future
Dimosthenis AvramidisPediatric Cardiology Dpt.Mitera Children's Hospital
Worldwide there are > 135 million cardiovascular death annually
The incidence of out of hospital cardiac arrest ranges from 20-140/100000 in the US
Survival ranges from 2-11% in the US
These statistics establish cardiac arrest as one of the most lethal public health problems in the US taking more lives than colorectal cancer, breast cancer, prostate cancer, influenza, pneumonia auto accidents HIV firearms and house fires combined
Causes of Death (U.S.)
Lloyd-Jones D, et al. American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Heart disease and stroke statistics--2009 update: a report from the American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Circulation. 2009 Jan 27;119(3):e21-
181.
Sudden Cardiac
Arrest
• Heart disease kills more people each year than cancer− 1 in every 2.9 of all deaths
• Every year 230,000 - 325,000 people have a cardiac arrest outside of a hospital.− Only 7.6% will survive
Heart
Disease
26%
Cancer23%
All other causes
19%
Stroke6%
Historical Perspective
• 1960s – Peter Safar
– Prone position inadequate
– Expired air did provide sufficient O2.
– Head tilt, chin lift kept patent airway
1961
A. Peter Safar, 1950s
B. Early symposium on CPR
A B
CPR is over 50 years old, but recent changes have shown increases in survival
Coronary Perfusion Pressure
How Does CPR Cause Blood Flow?Thoracic Pump
+
Ensure Total Chest Recoil with:1) Lifting palm during compressions
or2) Using feedback device
+
CouldNotResuscitate
ResuscitatedButExpired
24-hourSurvivors
35302520151050
Co
ron
ary
Perf
usi
on
Pre
ssu
re (
mm
Hg)
Kern, Ewy, Voorhees, Babbs, Tacker Resuscitation 1988; 16: 241-250
Not the pH
Not the oxygen content
Survival is related to arterial pressures
generated by chest compressions
It’s all about Coronary
Perfusion Pressure !
Paradis et al. JAMA 1990; 263:1106
5 sec
80
160
mm
Hg
Time (sec)
40
120
0
Coronary Perfusion Pressures
Cerebral Perfusion
Pressures
No Cerebral
Perfusion
Single rescuer performing 30:2 with realistic 16 sec.
interruption of chest compressions for MTM ventilations
Ewy GA, Zuercher, M. Hilwig, R.W. et al Circulation 2007;116:2525
0
5 sec
80
160
mm
Hg
Time (sec)
40
120
Coronary Perfusion Pressures
Continuous Cerebral Perfusion Pressures
Single rescuer performing
continuous chest compressions
Ewy GA, Zuercher, M. Hilwig, R.W. et al Circulation 2007;116:2525
Perfusion with continuous compressions
10-20 20-30 30-40 40-50 50-60 60-70 70-80 80-90 90-100 100-110 110-120 R>120
Chest compression rate (min-1)
Nu
mb
er
of
30
se
c s
eg
me
nts
300
250
200
150
100
50
0
n=1626 segments
Chest compression rates
Abella et al, 2005
No ROSCROSC
10-20 20-30 30-40 40-50 50-60 60-70 70-80 80-90 90-100 100-110 110-120 >120
Chest compression rate (min-1)
Mean rate, ROSC group90 ± 17 *
Mean rate,
no ROSC group79 ± 18 *
210
180
150
120
90
60
30
0
Nu
mb
er
of
30
se
c s
eg
me
nts
Survival better with compression rate of
100 – 120 compressions/minute
Abella et al, 2005
p=0.003
40
32
24
16
8
0
1 2 3
CPR duration, min
CPP,
mm
Hg
ICCM, 2005
2 inches vs 1.5 inchesSurvival:
100%
15%
Survival better with compressions >2 inches deep
Probability of ROSC
Stiell et al. Crit Care Med 2012; 40:1192-1198
One Day Survival
Stiell et al. Crit Care Med 2012; 40:1192-1198
Survival to Discharge
Stiell et al. Crit Care Med 2012; 40:1192-1198
Sho
ck s
ucc
ess
, pe
rce
nt
Compression depth, inches
n=10 n=5n=14n=13
p=0.02
Shock success by compression depth
Edelson et al, 2006
Aufderheide et al, 2004
mean ventilation rate: 30 ± 3.2
first group: 37 ± 4 after retraining: 22 ± 3
16 seconds
v v v v v v v v v v
Patients can be hyperventilated to DEATH!
Pause before shock
4:55 5:00 5:05 5:10
Co
mp
ress
ion
s
ECG
Chest compression pauses before shocks
0
20
40
60
80
100
≤10.3(n=10)
10.5-13.9(n=11)
14.4-30.4(n=11)
≥33.2(n=10)
Pre-shock pause, seconds
Sho
ck s
ucc
ess
, pe
rce
nt
90%
10%
55%64%
p=0.003
Shock success by pre-shock pauses
Edelson et al, 2006
2005 AHA Guidelines
2010 AHA Guidelines
EVENEVENEVEN
Medications proven to improve outcome in cardiac arrest?
•
•
•
The priority is quality compressions
2009
Reflected in the poor impact of ACLS meds:
Randomized trial of EPINEPHrine versus no EPINEPHrineFor EMS treated cardiac arrest NO BENEFIT IN
SURVIVAL TO DISCHARGE FROM HOSPITAL!
The Metabolic Phase (~>10 minutes)Survival decreasedScience searching for more successful treatments
3-Phase Time-Sensitive Model of Cardiac Arrest Due to VF
The Electrical Phase (0 to ~5 minutes)Early defibrillation life-saving
The Circulatory Phase (~5 to ~10 minutes)Intubation and immediate AED can be detrimentalCompressions first may be life saving
Weisfeldt ML, Becker LB. JAMA 2002;288:3035
“Tucson” version (2003) Cardiocerebral Resuscitation(Intubation delayed; Bag Valve Mask ventilation)
200 chestcompressions
200 chestcompressions
No intubation:Bag Valve Maskventilation
An
alys
is
200 chestcompressions
An
alys
is
Follow ACLS Guidelines?
200 chestcompressions
EMSarrival
Begin IV 1 mg EPINEPHrine every3 to 5 minutes
•If adequate bystander chest compressions are provided, EMS providers perform immediate rhythm analysis and shock if indicated
An
alys
is
CPR (2010) emphasizes:
Circulation
Airway
Breathing
CCR (Cardiocerebral Resuscitation) emphasizes:
Circulation (uninterrupted compressions)
Deemphasizes ventilation
Monitoring the effects of CPR:“if you don’t measure it you can not improve it”
Cardiac perfusion pressure (CPP)of>20 mmHg-defined by arterial end diastolic pressure minus central venous pressure (CVP). Requires and arterial line and a
central line during CPR
Capnography-ET CO2 of > 20 mmHg
Waveform CapnographyAttaches to ET tube, measures CO2
Oxygen Lungs alveoli blood
Muscles + Organs
Oxygen
Cells
Oxygen
Oxygen+
Glucose
ENERGY
CO2
Blood
Lungs
CO2
Breath
CO2
Physiology of Metabolism
SpO2 versus EtCO2
Oxygenation and VentilationOxygenation (Pulse Ox)
– O2 for metabolism
– SpO2 measures % of O2 in RBCs
– Reflects changes in oxygenation within 5 minutes
Ventilation (Capnography)
– CO2 from metabolism
– EtCO2 measures exhaled CO2
at point of exit
– Reflects changes in ventilation within 10 seconds
Capnography Waveforms
45
0
45
0
Hypoventilation
Normal
Hyperventilation
45
0
Capnography1) Qualitative waveform capnography
(PETC02) provides a quality measure for CPR
2) Optimal goal for CPR is PETC02 of 35-40 mmHg equates to same as when ROSC
3) If PET Co2 is < 10 mmHg attempt to improve CPR-a PetC02 is 10 or less after initiation of ACLS is associated with poor outcomes.
Guidelines 2005EtCO2 recommended to confirm ET tube
placement
Guidelines 2010• Continuous quantitative waveform
capnography recommended for intubated patients throughout peri-arrest period. In adults:
1. Confirm ETT placement
2. Monitor CPR quality
3. Detect ROSC with EtCO2 values
Handheld Feedback Device
Handheld accelerometer-based audiovisual device
Generation of Feedback
Post Code Reviews
(Code Stat ™)
Anesthesia and Analgesia 1959;38 (6): 423
Anesthesia and Analgesia 1959;38 (6): 423
Hypothermia
The new guidelines recommend cooling comatose adult patients with ROSC after out of hospital VF, PEA and Asystole cardiac arrest to 32-34 degrees C (89-93 degrees F) for up to 12-24 hours
P=0.51
No difference in survival
Survival
Outcomes
Outcome TTM33 TTM36 HR or RR (95% CI) P Value
PRIMARY OUTCOME
Mortality at the end of trial
Dead no./total no. (%) 235/473 (50) 225/466 (48) HR=1.06 (0.89-1.28) 0.51
SECONDARY OUTCOMES
Neurological function at
follow-up
CPC 3-5–no./total no. (%)
mRS 4-6–no./total no. (%)
Serious adverse events
Any event–no./total no. (%)
252/469 (54)
245/469 (52)
439/472 (93)
242/464 (52)
239/464 (52)
417/464 (90)
RR=1.02 (0.88-1.16)
RR=1.01 (0.89-1.14)
RR=1.03 (1.00-1.08)
0.78
0.87
0.09
100% follow-up
99% follow-up
ConclusionIn unconscious survivors of out-of-hospital cardiac arrest of presumed cardiac cause
targeting a temperature of 33°C did not confer any benefit compared to
targeting a temperature of 36°C
Equipment organized to be efficient
Team member roles pre-assigned
Frequent practice/ simulation
Pit Crew ApproachCompressions are Priority
• Continuous chest compressions with minimal interruption are key
• USE any available feedback device/ metronome
• Alternate compressions between providers across patient’s chest (e.g. 100 each)
• Chest compressions should continue when charging an AED or manual defibrillator
• Chest compressions should resume immediately after any shock
Goal = keep interruptions for rhythm check/defibrillation < 10 seconds
Goal = NO interruption for airway device insertion
Pit Crew ApproachAirway Options During CPR
• Airway insertion must not interrupt compressions !
Pit Crew ApproachMechanical CPR Devices
• Mechanical CPR devices do not lead to more survivors than manual CPR
• Minimizing interruption in chest compressions during first 10 minutes of cardiac arrest is critical, so mechanical CPR device by BLS providers must be delayed until after the first 4 cycles of uninterrupted compressions/defibrillation attempts
Post-resuscitation Care Checklist
Before moving patient:
Augment marginal BP with IV fluid bolus and pressor drip
Obtain 12-lead ECG if possible
Titrate O2 to SpO2 between 95 – 99%
Monitor continous ETCO2 and ventilation rate if advanced airway
Mask travels with bag-valve no matter what airway is in place
Package on backboard/firm surface
Is transport to center capable of PCI / hypothermia possible?