Critical Care Controversies: The REBEL vs The SKEPTIC at #SMACC 2019

On the last day of the last SMACC conference, Dr. Ken Milne (The SGEM) and I had a cage match debating four critical care controversies. It was all done in good fun with both of us taking our opportunities to poke a little fun at each other. While we took a pro vs con approach to the presentation, our positions are much closer than the debate demonstrates. Although the literature is far from perfect, development of critical appraisal skills and application of evidence-based medicine to the literature is what we should be using to inform our care but not dictate our care. It is equally as important to incorporate clinical judgment and ask our patients what their values and preferences are before making decisions about care.

Critical Care Controversies: The REBEL vs The Skeptic at #SMACC 2019

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Dr. Justin Morgenstern from First10EM was the referee for this SMACC down. He also provided the introduction and the rules of this epic battle, which went a bit like this…

Ladies and gentlemen. Today, we are going to witness the most anticipated evidence-based medicine battle (of the day). Are you ready?

For the thousands in attendance, and the millions on twitter around the world. Live from Sydney Australia’s Convention Centre. Let’s get ready to to rumble!

In this corner, from the great white north. He will hit you HARD, with EBM knowledge. But follow it up with nice Canadian apology. Aka BatDoc. It’s Ken “The Skeptic” Milne.

In the opposite corner. Coming to us from deep in the heart of Texas Officially the center of the FOAMed universe. Unofficially known as the sexiest man in FOAM. Salim “The REBEL” Rezaie.

Now this is an EBM match. Ken – there will be no hockey brawls tonight. Please keep it above the belt. No hits to your P-values

There will be four rounds of four minutes. Each round will address one critical care controversy. When you hear the bell ring…come out EBMing.

Round 1: Mechanical CPR in OHCA

REBEL:

Mechanical CPR Devices are not Superior to Manual CPR, but they May be Equivalent in Some Settings

High quality CPR, with limited interruptions and early defibrillation are the keys to survival with good neuro outcomes in OHCA

Mechanical CPR provides standard depth and frequency of compressions for prolonged periods of time allowing for other aspects of patient care LINC Trial [3]: Higher CCF (0.84 vs 0.79), Shorter pauses (0sec vs 10sec) (Able to defibrillate through compressions without pauses) Application of device needs to be streamlined to avoid delays in CPR (compressions paused for 36sec to apply device) [3]

Location of compressions needs to be confirmed to ensure optimal point of compression is being compressed (Some studies without CPR feedback devices)

No difference in ROSC, Survival, or Survival with good neuro outcomes [1]

Deployment of mechanical devices without appropriate training might cause patient harm through an increase in no-flow time during the early part of the cardiac arrest and delay defibrillation in patients with a shockable rhythm.

Injuries from mechanical CPR devices are possible, but most studies don’t have a comparator group. One study by Koster et al showed no difference in serious or life-threatening resuscitation-related visceral organ damage compared to manual CPR with LUCAS devices [4]

Consider mechanical CPR in limited man/woman power settings, pre-hospital (i.e. moving vehicle), prolonged CPR, cognitive offload

SKEPTIC:

mCPR may get you ROSC but not increase of survival with good neurologic outcome

ROSC with a non-shockable rhythm is low (<10%)

30-day survival is even lower (1.2%) and good neuro almost zero

People rarely survive more than 30 minutes of CPR neurologically intact

Rare cases you may need prolonged CPR, but it needs to be a bridge to somewhere

It is crazy that we apply the same tool to every single patient with OHCA

Ensuring high-quality CPR with the right depth and rate is going to make very little difference to a 90 year old with dementia from a nursing home with multiple co-morbidities

Safety? – How about some seatbelt/restraining device in the back of the EMS that allows for CPR?

You might have the same outcomes but cost way less money than mCPR

We need to raise the bar before adopting new technology (see how many things are reversed when high quality studies are done)

Clinical Bottom Line: Buyer beware. Recognize you are spending money on a device that does not improve a patient-oriented outcome

References:

Gates S et al. Mechanical Chest Compression for out of hospital cardiac arrest: Systematic review and meta-analysis. Resus 2015. PMID: 26190673 Perkins GD et al. Mechanical Versus Manual Chest Compression for Out-of-Hospital Cardiac Arrest (PARAMEDIC): A Pragmatic, cluster Randomised Controlled Trial. Lancet 2015. PMID: 28979419 Rubertsson S et al. Mechanical Chest Compressions and Simultaneous Defibrillation vs Conventional Cardiopulmonary Resuscitation in Out-of-Hospital Cardiac Arrest: The LINC Randomized Trial. JAMA 2014. PMID: 24240611 Koster RW et al. Safety of Mechanical Chest Compression Devices AutoPulse and LUCAS in Cardiac Arrest: A Randomized clinical Trial for Non-Inferiority. Eur Heart J 2017. PMID: 29088439 Matsuyama et al. Impact of Cardiopulmonary Resuscitation Duration on Neurologically Favourable Outcome after Out-of-Hospital Cardiac Arrest: A Population-Based study in Japan. Resuscitation 2017. PMID: 28109995 Rajan et al. Incidence and Survival Outcome According to Heart Rhythm During Resuscitation Attempt in Out-of-Hospital Cardiac Arrest Patients with Presumed Cardiac Etiology. Resuscitation 2017. PMID: 28087286 Prasad and Cifu. Medical Reversal: Why We Must Raise the Bar Before Adopting New Technologies. Yale J Biol Med 2011. PMID: 22180684

Round 2: Epinephrine in OHCA

REBEL:

We don’t know the optimal dose of epinephrine in cardiac arrest

We Need to Save the Heart and the Brain, NOT the Heart at the Expense of the Brain Epinephrine increases peripheral vasoconstriction to increase coronary perfusion pressure (Alpha Effect) Epinephrine also has adverse effects including myocardial oxygen consumption, post-ROSC myocardial dysfunction, ventricular arrhythmias, and decreased microcirculation to superficial areas of the brain (Beta Effect) Jacob et al [1]: 1 st RCT on topic, but was underpowered, showed increased ROSC, but no difference in survival PARAMEDIC-2 [2]: Largest RCT to date on topic, increased ROSC & Survival to Hospital, but more mRs of 4 & 5 in survivors (31% vs 18%) Pooling all the evidence: 9 trials, 5 increased ROSC, 6 no survival difference, 2 increased mortality We don’t know the optimal dosing of epinephrine in cardiac arrest…so until then, we have to fill in the gaps with clinical judgment Is there a better way? HD-Guided Epi Drip 4 Swine studies [3][4][5][6] showed improved, ROSC, Survival, & Cerebral Perfusion Pressure Found one human trial from 1990 [7] that showed as CPP increased so did ROSC The key difference with the drip vs bolus is linear titration, and much smaller doses, therefore potentially less beta effects on the brain We shouldn’t be targeting ROSC and Survival but Survival with Good Neuro Outcomes…the current dosing of epi, does not achieve this HD-guided epinephrine is linear titration at much smaller doses, therefore potentially less beta effects on the brain



SKEPTIC:

There has never been any evidence that epinephrine improves survival with good neurologic outcome

The burden of proof is on those making the positive claim

We have given biological plausibility as the reason for many things over the years only to have them reversed once high-quality research is done

How does squeezing the vascular bed (brain/heart/kidney) be a good thing?

You presented a logical fallacy (false dichotomy) bolus vs. drip.

How about a placebo group…certainly there is equipoise because nothing has ever worked

Have you seen the new JAMA paper on AHA guidelines?

Less than 10% (8.5%) are based Level A based on multiple RCTs and 50% are level C (expert opinion)

Clinical Bottom Line: We still don’t know the amount of epinephrine to give, how to give it (bolus or drip) or even if epinephrine has a patient-oriented benefit

References:

Jacobs IG et al. Effect of Adrenaline on Survival in Out-of-Hospital Cardiac Arrest: A Randomised Double-Blind Placebo-Controlled Trial. Resus 2011. PMID: 21745533 Perkins GD et al. A Randomized Trial of Epinephrine in Out-of-Hospital Cardiac Arrest. NEJM 2018. PMID: 30021076 Friess SH et al. Hemodynamic Directed Cardiopulmonary Resuscitation Improves Short-Term Survival from Ventricular Fibrillation Cardiac Arrest. Crit Care Med 2013. PMID: 23887237 Sutton RM et al. Hemodynamic directed CPR Improves Short-Term Survival From Asphyxia-Associated Cardiac Arrest. Resus 2013. PMID: 23142199 Sutton RM et al. Patient-Centric Blood Pressure-Targeted Cardiopulmonary Resuscitation Improves Survival from Cardiac Arrest. Am J Respir Crit Care Med 2014. PMID: 25321490 Friess SH et al. Hemodynamic Directed CPR Improves Cerebral Perfusion Pressure and Brain Tissue Oxygenation. Resus 2014. PMID: 24945902 Paradis NA et al. Coronary Perfusion Pressure and the Return of Spontaneous Circulation in Human Cardiopulmonary Resuscitation. JAMA 1990. PMID: 2386557 Fanaroff et al. Levels of Evidence Supporting American College of Cardiology/American Heart Association and European Society of Cardiology Guidelines, 2008-2018. JAMA 2019. PMID: 30874755

Round 3: Stroke Ambulances?

REBEL:

Too be fair I don’t actually advocate for stroke ambulances, however it is important when we are feeling strongly about an argument, to think about potential benefits to ensure we are not missing anything

Time to tPA is Decreased (If you are a believer in time is brain) Majority of patients show up in the >90-minute range.<25% show up in the 0 – 90-minute window [1] Stroke ambulances increase the percentage of patients in the 0 – 90-minute window (57.5% with STEMO vs 37.4% without STEMO) Stroke ambulance decreased alarm to tPA time by 25 minutes Patients in the STEMO arm had higher percentage of patients with NIHSS scores ≥20 (12% vs 6%) No difference in in-hospital mortality, 7d mortality, days in hospital or ICH rates Overall rate of ICH with STEMO was 2.2% despite more patients getting tPA (33% vs 21% of ischemic strokes) mRs of 0 – 2 at 3 months: STEMO 40.7% vs No STEMO 50.6% but population too small to make absolute conclusions (Study not powered to assess this outcome) Second study [4] evaluating over 50,000 patients with acute ischemic stroke trying to cut down door to tPA time Door to tPA time decreased from 77min to 67minIn hospital all-cause mortality decreased from 9.93 to 8.25% and symptomatic ICH decreased from 5.68% to 4.68% Third study pooling ECASS, NINDS, and ATLANTIS showed time to tPA does improve patient-oriented outcomes (mRS 0 – 1) but still showed a 3% ICH rate which was less than the 6% ICH rate in the 271 – 360 min window [3]

If you believe the time is brain mantra Biologic plausibility that without fibrin cross deposition, clots are “softer” and more likely to lyse Earlier tPA in <90min had better neurologic outcomes

Early identification of pts can get them to appropriate stroke centers or just closest facility for EVT & Stroke Rehab facilities. Secondary transfer of these patients can cause delays in care and worsened neurological status and mortality

SKEPTIC:

Show me the Patient-Oriented Outcome (POO)

It costs about $1 million to buy and $1 million/year to operate

Regular ambulance cost about $200,000 to buy and per year to operate

Why add something to our healthcare system without proven benefit?

Faster is not always better, look at what happened with STEMI

They changed the definition of TIAs in 2009 and that made both TIAs and CVAs look better (Lake Wobegon effect) [8]

Would that money be better spent on the social determinants of health?

Clinical Bottom Line: We cannot recommend purchasing a stroke ambulance if and until it demonstrates an improved patient-oriented outcome

References:

Ebinger M et al. Effect of the Use of Ambulance-Based Thrombolysis on Time to Thrombolysis in Acute Ischemic Stroke: A Randomized Clinical Trial. JAMA 2014. PMID: 24756512 Lin E et al. World’s First 24/7 Mobile Stroke Unit: Initial 6-Month Experience at Mercy Health in Toledo, Ohio. Front Neurol 2018. PMID: 29867711 Lees KR et al. Time to Treatment with Intravenous Alteplase and Outcome in Stroke: An Updated Pooled Analysis of ECASS, ATLANTIS, NINDS, and EPITHET Trials. Lancet 2010. PMID: 20472172 Fonarow GC et al. Door-to-Needle Times for Tissue Plasminogen Activator Administration and Clinical Outcomes in Acute Ischemic Stroke Before and After a Quality Improvement Initiative. JAMA 2014. PMID: 24756513 Calderon VJ et al. Review of the Mobile Stroke Unit Experience Worldwide. Intervent Neurol 2018. PMID: 30410512 Zaher et al. Aggressive Measures to Decrease “Door to Balloon” Time and Incidence of Unnecessary Cardiac Catheterization: Potential Risks and Role of Quality Improvement. Mayo Clin Proc 2016. PMID: 26549506 Easton JD et al. Definition and Evaluation of Transient Ischemic Attack. Stroke 2009. PMID: 19423857 Lake Wobegon. Wikipedia [Link is HERE] Social Determinants of Health. Public Health Agency of Canada. [Link is HERE]

Round 4: Bougie 1st Intubation

REBEL:

Higher First Pass Success Rate

Prior to these studies 1st pass success rate ≈85%

Increasing attempts worsens morbidity and mortality

Retrospective Study [1] of >500 pts: FPS was 95% with bougie 1st 86% without bougie 1st, but duration of intubation was 40sec vs. 27sec respectively

Prospective RCT (BEAM trial) [2] of >700pts: FPS in pts with one difficult airway characteristic was 96% with bougie 1stvs 82% without bougie

Difficult airway characteristics: body fluids obscuring laryngeal view, airway obstruction or edema, obesity, short neck, small mandible, large tongue, facial trauma, or need for cervical immobilization

1st pass success in all comers: 98% bougie 1st vs 87% no bougie, and in this study no difference in median duration of 1st intubation attempt 38sec vs 36sec respectively

Standard geometry blade (usually VL for me) with non-malleable bougie

Hyperangulated blade can be used if have a malleable bougie (more expensive)

Pre-loading or not pre-loading bougie makes no difference, just pick a technique and go with it

SKEPTIC:

It’s called ABC and we in EM/Critical care own the airway

Study by Brown et al in Annals EM showed we had an esophageal intubation rate of only 3%

Successful intubation rate was over 99%

This was a single centre study where 80% were done boogie first already

Clinical Bottom Line: Get very good at one technique, have a couple back up methods and don’t be afraid to cut the neck.

References:

Driver B et al. The Bougie and First-Pass Success in the Emergency Department. Ann Emerg Med 2017. PMID: 28601269 Driver B et al. Effect of Use of Bougie vs Endotracheal Tube and Stylet on First-Attempt Intubation Success Among Patients with Difficult Airways Undergoing Emergency Intubation: A Randomized Clinical Trial. JAMA 2018. PMID: 29800096 Brown et al. Techniques, Success, and Adverse Events of Emergency Department Adult Intubations. Ann Emerg Med 2015. PMID: 25533140

And the Winner Was…

And the winner was…our patients…Evidence based medicine includes the best literature, our clinical judgement and patients’ values and preferences. The literature should not dictate our care but rather guide our care.

Some Photos From the Event

Also Checkout Ken Milne’s Writeup at The SGEM: SGEM Xtra – The REBEL vs. The SKEPTIC – SMACC 2019

Post Peer Reviewed By: Anand Swaminathan, MD (Twitter: @EMSwami)