If your you grind your teeth when you have resuscitated a patient post cardiac arrest in fear of having to initiate a cumbersome protocol with hypothermia, the TTM trial may be just what you were looking for. Up to this point only 2 randomized trials have been performed comparing “usual care” to hypothermia, totaling about 350 patients. These 2 studies have changed the way we approach post-cardiac arrest resuscitation, but many questions were left unanswered.  

Why is this topic important?

All emergency physicians will face caring for patients after cardiac arrest, and few interventions have been shown to improve neurologic survival. Therapeutic hypothermia has demonstrated in two RCT to improve neurologically intact survival with a number needed to treat of six. However, despite the dramatic effects seen with treatment many unanswered questions remained. How cold, how fast, how long and how to rewarm these patients? The TTM attempted to answer one small piece of this puzzle.

What does this study attempt to show?

The study hypothesis was that targeting “relative” normothermia at 36 degrees and avoiding febrile episodes would be non-inferior to hypothermia at 33 degrees Celsius. The authors believed most of the benefit from trials comparing hypothermia to control was derived from avoiding hyperthermia and not necessarily from the neuroprotective effects of hypothermia.

Patients aged 18 years and older who had a GCS < 8, with out of hospital cardiac arrest (OOHCA) irrespective of initial rhythm and had maintained pulses > 20 consecutive minutes were eligible.

The primary outcome of the study was all-cause mortality at the end of the trial, with a predefined secondary outcome of poor neurologic function or death defined as a CPC >2 (basically unable to function independently). I think this is a great primary end-point mostly because it is binary; as compared with CPC scores which we know from the stroke studies that the mRS can be highly subjective.

What are the essential findings?

Between January 2010 and January 2013 950 patients were enrolled, with 476 assigned to the 33 degrees Celsius and 473 to the 36 degrees Celsius.  The groups had similar pre-randomization characteristics, although some skeptics have argued that fewer patients in the normothermia group had AMI and ischemic heart disease, although there were not more interventions completed for this previously.

Of the patients randomized to T33C 253/473 (50%) had died by the end of the trial as compared to 255/466 (48%) in the T36C cohort (OR 1.06 95% CI  0.98-1.28, p = 0.51).  Minimal neurologic deficit (CPC 1 and 2) occurred in 47% in both arms and mRS </= 2 occurred in 45 and 44% in the 33 degree and 36 degree groups respectively.

There was shorter duration of mechanical ventilation in the T36C group: T33C = 0.83 versus T33C = 0.76 median days receiving mechanical ventilation/days in ICU (P=0.006)

How is patient care impacted?

Everyone will likely have a different opinion on this. The fact of the matter is survival after cardiac arrest has improved since the original publication of the HACA and Bernard hypothermia trials. New interventions like hands only CPR, early defibrillation, and cardiac catheterization likely have a part in some of the improvements in mortality seen, but certainly a proportion of this improvement must be attributed to the hypothermia protocol.

That being said, in the largest trial performed to date on optimal temperature management there was no difference in the primary outcome of mortality. The HACA and Bernard papers were flawed in that they only included patients with VF/VT arrest and had NO regulation of temperature in the control arm, which resulted in many patients becoming febrile.

Hypothermia induces diuresis, electrolyte disturbances, shivering, and often requires heavy sedation and sometimes paralytics. These nuances make targeted temperature control a more attractive option, with the best available evidence suggesting at least equivalent outcomes.

As a clinician in both the emergency department and ICU I am always looking for the simplest answer for a complex problem. Thus in my view TTM to 36 degrees seems, at least for the time being, to be a reasonable alternative. The MAJOR drawback of TTM is for clinicians to get relaxed about temperature management and patients may develop fever which is has been demonstrated, albeit in different patient populations, to result in worse neurologic outcome. THEREFORE, if you adopt a 36-degree protocol you should think of the temperature like you would blood pressure, and aggressively treat fluctuations.  

 Major Limitations of the Study

The study does not reflect the subset of patients seen in most urban county hospitals, with prolonged downtime and most initial rhythms in this study being shockable. That being said, the Bernard and HACA trials excluded all patients with non-shockable rhythyms and these studies still dramatically changed our practice.

Also the study was powered to detect an 11% changed in mortality, which is rather large. Excluding a smaller improvement in mortality is not possible, however there was no trend or even suggestion based on this study that this would be the case.

Lastly the improved survival in all of these studies could reflect increase attentiveness to critically ill patients may result in improved outcomes regardless of the actual intervention employed.   

TAKE HOME POINTS:

-No difference in mortality between T36C and T33C by the end of the study.

-T36C is less cumbersome and associated with less physiologic perturbations and is simpler.

-Ignoring temperature management all together SHOULD BE DISCOURAGED, and temperature management should be considered a critical component of resuscitation until proven otherwise.

-Dave

TRANSFUSIONS IN ACUTE UPPER GASTROINTESTINAL BLEEDING

Transfusion thresholds in medicine have been steadily falling, as more and more literature demonstrates either no improvement in outcomes or associated harms.  

Today’s mini-JC focuses on a topic extremely relevant to our practice as emergency physicians: transfusion thresholds of PRBC’s in patients with acute upper gastrointestinal bleeding (UGIB). If the patient is exsanguinating, we all know what to do, but what about in hemodynamically stable patients with an upper GI bleed?

1.  Why is this topic important?

Several non-randomized trials, and animals studies have evaluated a restrictive approach to blood transfusion in patients with bleeding from portal hypertension, as increases in effective circulating volume may lead to a rebound in portal pressure, which is associated with a risk of re-bleeding.

In addition, trauma surgery has propagated the idea of “don’t pop the clot” in patients who have penetrating trauma in order to prevent rebleeding and coagulopathy after surgery. These same mechanisms have been suggested to be beneficial in patients with arterial hemorrhage from a perforated peptic ulcer.

2.  What does this study attempt to show?

This study attempts to demonstrate that in patients with UGIB without massive exsanguination, a restrictive transfusion threshold of 7 is non-inferior to a transfusion threshold of 9. Patients were eligible if they had hematemesis, (or bloody nasogastric aspirate), melena or both as confirmed by hospital staff.

They attempted to exclude critically ill patients as well as completely stable patients as defined below:

-Patients were excluded if they had a lower GI bleed, active acute coronary syndrome (new EKG findings or positive biomarkers), massive exsanguination (hypotension, with active bleeding requiring emergent transfusion), or acute CVA.

-Patients with rockall score of 0, or a hemoglobin of 12 or greater were also excluded as these patients represented the lowest risk group.

Patients were randomized to a restrictive (transfuse if hgb <7, goal hgb 7-9) or liberal (transfuse if hgb <9, goal 9-11) transfusion groups. Randomization also was stratified for presence or absence of cirrhosis in blocks of four.

Treatment was otherwise kept the same between the two groups (protonix bolus and drip, emergency EGD within 6 hours with banding or sclerotherapy as necessary, octreotide and antibiotics if the bleed was deemed to be variceal.)

3.  What are the essential findings?

A total of 921 patients underwent randomization and 32 were withdrawn or withdrawn by investigators. 444 patients were left in the restrictive-strategy group and 445 in the liberal-transfusion group. Baseline characteristics were similar in both groups, as described in table 1.

225 (51%) of patients in the liberal group got transfusions, as compared with 61 (14%) in the restrictive group.

Mortality at 45 days was significantly lower in the restrictive-strategy group than in the liberal group 5% (23 patients) as compared with 9% (41 patients) hazard ratio 0.55 (0.33-0.92) respectively, p < 0.05.  

Death was due to unsuccessfully controlled bleeding in 3 patients in the restrictive strategy group (0.7%), and 14 patients in the liberal strategy group (3.1%).

Overall the liberal strategy group got more blood, had more rebleeding and thus required more salvage procedures especially in patients with variceal bleeding (TIPS and balloon tamponade). There were more medical associated deaths (sepsis, acute MI, acute CVA etc.) in patients who received the liberal transfusion strategies.  

4.  How is patient care impacted?

Among patients with severe acute upper gastrointestinal hemorrhage a restrictive strategy of blood transfusion improved mortality at 45 days. This survival benefit was likely conferred due to better control of factors contributing to death, such as further bleeding, rescue therapy and adverse events.  

5.  Is this an area of controversy?

Although this is an area of controversy, the evidence that blood transfusions, especially older blood in which the oxygen carrying capacity has diminished, may result in increased complications has been suggested previously. The TRICC trial, the Houston study, and several other large randomized controlled trials have all shown that patients have improved or equivalent outcomes when using a restrictive transfusion strategy.  The mechanisms for this difference in mortality are certainly different, as we know that transfusions may propagate further bleeding in patients at risk of hemorrhage. In addition, it is known that blood transfusions can result in significant immunomodulation and cytokine release resulting in acute renal failure, pulmonary edema, ARDS, and higher infectious complications in the critically ill medical patient.

This must be balanced in the situation in which acute hemorrhage is life threatening and rapid transfusion is required to restore the effective circulating blood volume.  

6.  Major Limitations of the study?

The study is a well completed randomized controlled trial. However, several limitations still exist. First, there is no direct statement as to what was defined as a life-threatening hemorrhage that excluded patients from the trial, and therefore knowing how to apply this to our patients is somewhat confusing. In addition, 32 patients were withdrawn from the study because the investigator did not believe that there was clinical equipoise. They do not further specify this in the intention to treat analysis, and how many patients from each group were removed (if all 32 patients from the restrictive strategy group were removed because the attending physicians believed that they required blood transfusions this could have a significant effect on the statistically significant mortality benefit shown in this paper.)

However, despite some limitations in the study there are several important concepts:

1.    Transfusing patients based on hemoglobin levels only may be short sighted. Looking at perfusion parameters (lactate, oxygen delivery, end organ malperfusion) may be a more appropriate approach rather than transfusing to a number (MUST KEEP KGB > 9).  

2.    Giving a blood product should be viewed as giving a potentially dangerous medication (not dissimilar to heparin, Plavix etc.) and each time you order it you should consider the risks and the benefits. It has been demonstrated time and time again that blood products have associated harms (certainly I am not arguing against transfusing the actively bleeding patient with obvious signs of malperfusion), especially in the elderly patients with multiple comorbidities or patients with cancer.

UNTIL NEXT TIME

-Dave

Villanueva et al. Transfusions Strategies for Acute Upper gastrointestinal Bleeding. NEJM. 2013; 368:11-21.

Do you hate chest pain, or is it easy if you have a chest and you have pain you get admitted. Or if you are ultra-low risk (usually 0 risk) you just send them home, no testing. But what about people with a decent story? Is it safe to send someone home, or do these people need further testing as recommended by the AHA (stress within 72 hours?) 

Chest pain represents about 10% of ED visits and a diagnostic strategy to safely identify and discharge low risk patients in a rapid fashion has been debated. A quarter of all hospital admissions are secondary to chest pain, and about 85% do not leave the hospital with a diagnosis of acute coronary syndrome.

Today’s mini JC focuses on the safety of a rapid identification of the “low risk” patient who can be safely discharged from the hospital with a 2 hour-accelerated diagnostic protocol.

1.  Why is this topic important?

Rapid evaluation and discharge of low risk chest pain may substantially reduce both outpatient and inpatient LOS, cost to the patient and health care system, and reduce physician liability. A rapid diagnostic protocol that can discharge patients within two hours of being evaluated represents a superior alternative to admission for serial enzymes, and possible a stress test (which more and more seems to be of limited utility.)

2.  What does this study attempt to show?

The study attempts to demonstrate that in patients whom are low risk defined as two negative troponins, 2 hours apart, a TIMI risk score of 0 (see below) and no new EKG changes (see manuscript, but a LBBB if it was old did not preclude them from enrollment in the study) can be safely discharged home with a 30 day event rate < 1%.  Major adverse cardiac events (MACE) were identified as: death, cardiac arrest, emergent revascularization procedure, high degree AV block, and acute MI. AMI is defined as having ischemic symptoms + a rising biomarker (troponin). In this protocol no physician judgment including (patients whom the provider deemed to be low risk) was included to provide more generalizable results.  It is important to note this a prospective observational study, not an intervention study.

 3.  What are the essential findings?

1,975 patients were prospectively enrolled, and ultimately 302 patients (15.3%) developed MACE within 30 days. The accelerated diagnostic protocol (ADP) classified 392 patients (20%) as low risk. One lone patient who was ADP negative developed MACE at 30 days giving the ADP a sensitivity of 99.7%, (95% CI 98.1%-99.9%), and a specificity of 23.4% (95% CI 21.4% to 35.4%).  The lone patient that was missed by the ADP was previously healthy with no risk factors, a normal EKG, and first trop of <0.01, and 2^nd of 0.03, with the 3^rd troponin being 16.8. Angiography showed right coronary artery and circumflex artery stenosis and he had stenting in both vessels. No cardiac problems at one year follow-up.

In addition, the supplemental data from table’s 2A/B suggests that 75% of ADP negative patients underwent further diagnostic evaluation with stress testing.  7 ultimately had “non-emergent cardiac catheterization with revascularization.” Many patients were exposed to potentially dangerous anti-coagulants. 

Table 2a Use of further investigations in ADP negative patients within 30 days

Table 2b Acute treatments on ADP negative patients within 30 days

ADP = Accelerated Diagnostic Protocol, LMW = Low Molecular Weight.

4.  How is patient care impacted?

Although this study is not an intervention study, it is strong food for thought. Using a TIMI risk score of 0, no new EKG changes, and 2 negative troponins, (<99%ile for your lab) 2 hours apart suggest these patients are low risk for MACE at 30 days. This study suggests that about 1/5^th of our chest pain patients, who make up approximately 10,000 patients visits a year, can be safely discharged within a few hours of their initial ED evaluation. That’s 2,000 patients annually that could avoid admission and further diagnostic testing as an inpatient.

5.  Is this an area of controversy?

Of course. The study is prospective observational, and 75% of ADP negative patients ultimately had further diagnostic testing. In order for us to believe that an accelerated diagnostic protocol is useful the protocol needs to be used on patients in a prospective fashion (patients actually getting assigned the ADP vs. traditional care), and followed for 30-day outcomes.

Others may state that although only one lone patient in the ADP negative group developed MACE at 30 days, many more ADP negative patients received further diagnostic testing (CTCA, stress echo/EKG/radio nucleotide, and angiography with 7 patients ultimately getting non-emergent revascularization.) 

What do I think about this? Well if you were to take a cohort of patients walking around who developed chest pain > 50, many may have coronary artery disease, and if cathed may have a >70% lesion. However, what we have learned from prior mini JC’s is that stable coronary artery disease can be managed medically with equivalent if not superior results to invasively. Therefore, the benefit of an invasive strategy in these patients with NO EKG changes, negative biomarkers and perhaps a positive stress test must be questioned.

6.  Major Limitations of the study?

As stated previously this is a prospective observational study, not an intervention study, although not a limitation of the study itself, it may limit the applicability to your daily practice. However, other studies have suggested similar results including 30 day outcomes in “low risk patients” when evaluating CCTA. Therefore if you have a low risk patient by history, EKG, and a delta troponin at 2 hours it is reasonable to discharge those patients home with follow-up with their primary medical doctor.

The argument against this strategy is that you are missing the “unstable angina people”.  One important factor to remember is that likely the old “unstable angina patient” who came in 20 years ago before ultrasensitive troponins likely was having some trop leak as they exerted themselves with a partially occluded coronary artery. Those patients are likely called NSTEMI nowadays. In addition, plaques that are about 70-80% lesions are much less likely to rupture than are plaques that are say 20,30,40% as these plaques are much more unstable. These type of lesions will not be picked up by a stress test, and wouldn’t get a stent if they were cathed, and maximal medical therapy would be undertaken. Therefore the utility of identifying a plaque that may rupture is inherently flawed.

I reference you to an alternative approach, used at the mayo clinic, for placing the power of decision making back into the patients hands.  

I know two articles in one mini JC, but try using it next time you have a patient with chest pain, and let me know how it works for you! Essentially it is a protocol that after initial evaluation patients are given a pamphlet with 4 options to help them decide what they ultimately want to do. See chest pain decision aid I attached for you. 

Hess E et al. The chest pain choice Decision Aid. Circ Cardiovasc Qual Outcomes. 2012;5:251-259.

Ultimately I think an ADP is useful, and that patients who meet the aforementioned ADP negative criteria can be safely discharged home, and that further diagnostic testing is not warranted from the emergency department. I would recommend having that discussion using the decision aid with your patients so that they can be part of the medical decision making process. 

Until next time!

-Dave

2-Hour accelerated diagnostic protocol to assess patients with chest pain symptoms using contemporary troponins as the only biomarker: the ADAPT trial. Than M, Cullen L, Aldous S, Parsonage WA, Reid CM, Greenslade J, Flaws D, Hammett CJ, Beam DM, Ardagh MW, Troughton R, Brown AF, George P, Florkowski CM, Kline JA, Peacock WF, Maisel AS, Lim SH, Lamanna A, Richards AM. J Am Coll Cardiol. 2012 Jun 5;59(23):2091-8

4. How is patient care impacted?

-Dave

Hey guys,
Its been far too long for the mini JC series, but thats what happens when you are about to have a baby. This JC was stimulated by Elise, Harwood and my discussion about a cancer patient and the evaluation of pulmonary embolism. I'll set it up for you and you think about how you would evaluate the patient.

65 y/o F presents to the ED with shortness of breath. She says this started 2 days ago, and has worsened since that time. She is a breast cancer survivor and is undergoing active chemotherapy. She is not on home O2, but she has smoked and does think she has COPD as evidenced by her inhalers. 
VSS: 95, 95% on RA, 110/70, 37.1 (R), 18 (real) FSG 99
Lungs are reduced BS at bases otherwise unremarkable 
She has no signs or symptoms of DVT, she has never had a blood clot, no recent surgeries. 
What labs and imaging studies do you want?? (US machine is broken sorry!)

SO today's study is the CHristopher study looking at the evaluation of pulmonary embolism in the emergency department. 

Van Belle A et al. Effectiveness of managing suspected pulmonary embolism using an algorithm combining clinical probability, D-dimer testing, and computed tomography. JAMA 2006. 11; 295(2): 172-9.

1. Why is this topic important?

Pulmonary embolism is a commonly feared diagnosis in emergency departments in the United States. The frequency with which pulmonary embolism has been diagnosed has increased over the past ten years, with the number of massive and sub-massive pulmonary embolisms remaining relatively unchanged. This is due in large part to the over zealous testing, and the subsequent diagnosis of likely non-clinically significant pulmonary embolism. A simplified dichotomized clinical decision rule, D-dimer testing and computed tomography may reduce the number of unneeded evaluations for pulmonary embolism in the United States today.

2. What does the study attempt to show?

Consecutive patients in whom the treating physician suspected the possibility of pulmonary embolism, defined as sudden onset of dyspnea, sudden deterioration of existing dyspnea or sudden onset of pleuritic chest pain, without another apparent cause, could be potentially included in this study. The study then applied the wells score, dichotomizing patients into pulmonary embolism unlikely (score <4) and pulmonary embolism likely (score >/= 4). In all patients with a wells score of less than 4, a d-dimer test was applied, with the cutoff of >/= 500ng/mL being considered positive. If the d-dimer was negative, no further investigation was obtained, but if the d-dimer was positive, or if the wells score was >/= 4 a CT was obtained to evaluate for the diagnosis of pulmonary embolism. The study attempts to demonstrate that using this simplified dichotimzed approach to the wells score <4, and a negative d-dimer assay patients can be safely discharged home without further diagnostic evaluation.

3.  What are the key findings?

3306 study patients were eligible for inclusion, and 2206 patients (66.7%) were classified as unlikely as having a pulmonary embolism using the dichotomized wells score and underwent d-dimer testing. 1057 patients had a normal d-dimer, and 1028 (32%) were not treated with anti-coagulation.  Subsequent nonfatal venous thromboembolism (VTE) occurred in 5 patients (0.5% [95% CI 0.2%-1.1%]) no patients in this group died from a pulmonary embolism at 3-month follow-up.

In the high-risk wells group (wells score >/= 4) 674 patients (20.4%) were included. CT excluded pulmonary embolism in 1505, of which 1,436 patients were not treated with anti-coagulants; with a 3-month incidence of VTE of 1.3% (95% CI, 0.7%-2.0%). In patients in whom the initial CT scan was negative, PE was considered a possible cause of death in 7 (0.5% [95% CI, 0.2%-1.0%]). Overall 674 patients (20.3%) were diagnosed with a pulmonary embolism in patients included in this study cohort. 

4. How is patient care impacted?

This study demonstrates that in patients in whom a physician suspects the diagnosis of pulmonary embolism, the use of a dichotomized wells score < 4 and a negative d-dimer assay negate further evaluation for pulmonary embolism, with a < 1% incidence of VTE at 3-months, and no fatal pulmonary embolisms identified at follow-up.  

5. Is this an area of controversy?

The evaluation for pulmonary embolism continues to produce anxiety amongst emergency physicians. However, one of the most striking finding in this study is that the overall incidence of pulmonary embolism was 20%. Compare this to the PERC study by Dr. Kline in which the incidence was 7%, this is almost a 3-fold increase in the number of patients with pulmonary embolism. In addition, just 0.15% of patients in the Kline cohort ultimately died from pulmonary embolism, where in the Christopher Study mentioned here 0.5% died from fatal pulmonary embolism. This suggests that emergency physicians, particularly in the United States, evaluate for pulmonary embolism in a lower risk cohort than physicians in other countries. This occurs despite the fact that there is no mortality benefit, and there is a potential for harm.

6. What are the major limitations of the study?

 Several patients received anti-coagulation despite being low risk for pulmonary embolism, or having been excluded for pulmonary embolism for other pathologic causes. This could have reduced the number of VTE identified at three months in the negative, or low risk cohorts.  Also, the type of CT detector used was not standardized, and the d-dimer assay varied by site. These represent potential confounders of the study results. However, the generalizability of the study and the large number of patients included with few exclusion criteria make this an important piece of the literature for emergency medicine physicians. 

Reviewed by David Barounis

So I know this was written more research-like and I apologize, but the end result is what are you going to do about evaluation of PE in the above patient. 

I think in our patient  her wells score was between 1.5 (active cancer) and a 4 (if you said diagnosis is PE or at least as likely). If you got a trop and a BNP and they were both normal (< 0.02, and a BNP< 100) would you feel better? I think I would, and a diagnosis of PE in my mind is < 2%. However I don't think its unreasonable to get a d-dimer, and if you have a negative d-dimer, a neg trop and a neg BNP in this patient population I think the above study suggests you really do not need to CT scan these patients to look for PE. I think many people would not even get a d-dimer either. Far too often I think d-dimer is used in the ultra low risk patient or "0" risk patient, instead of the patient it was meant for, which is our wells score <4 patients. 

-Dave