Below, youโll find the full script for our discussion on the PALS cardiac arrest algorithm. For more details on some of the items covered in ourย PALS certification online, continue reading below:
Hi. Iโm Mark. Welcome to the first in our video series covering PALS (pediatric advanced life support). Today weโre going to review the PALS cardiac arrest algorithm.
When it comes to PALS (pediatric advanced life support) and cardiac arrest in children, thereโs kind of good news and bad news. The good news is that in America, in the field and in the ER, we donโt have to treat critically ill or injured children every day, which is a good thing. I have kids, you have kids, and nobody wants to see a busted up kid. The bad news is that every day across America, in the field and in the ER, weโre not treating critically ill or injured children, which means we donโt do it very often, which means weโre not always real great at it. Combine that with the emotional stress of treating a child, it makes dealing with a pediatric emergency very difficult. How do we manage that? How do we minimize, mitigate our messing upย PALS? One, education, doing what weโre doing today. Weโre going to review the algorithms. Weโre going to talk about it.
In an emergency, one of your best friends when it comes to pediatric emergencies is the Broselow tape. Hands downโIโve used itโa wonderful tool. How the Broselow tape works is you lay this tape out, starting from the head of the child to the foot. What Dr. Broselow did is he found a correlation between the length of the child and the weight of the child, because most of our interventions are weight-based in the pediatric patient. Start at the head. Lay the Broselow tape out. Where their feet wind up on the tape, itโll give you the weight of the childโthe rough, estimated weight of the childโand all the interventions. Your airway, tube size, blade size, IV size, your drug references, how much drug and what kind of drugโall those are calculated on the Broselow tape. In addition to the Broselow tape, Iโve been using a lot of pediatric apps for years on my smartphone. There are very handy. If Iโm going to fly a kid, as soon as I know the weight I punch the kid into this application. Then I already know the drugs that Iโm going to need and all the toys that Iโm going to need to treat this kid. Itโs all right there in the application. Find an app that you like. Become familiar with it, know how to use it, and use that. Minimize the stress, be prepared.
We know that the leading cause of cardiac arrest in a child is respiratory failure. Our goal in the cardiac arrest algorithm is prevention, avoidance. We do not want the child to get to this. We do not want to be in this algorithm. We can help minimize our travel of this algorithm by treating the respiratory component first. Letโs take a look at respiratory distress and respiratory failure and try to keep this kid out of this algorithm.
The average 4-year-old uses twice as much oxygen per minute as an adult does. He has a faster metabolism. Everything is sped up. He needs more oxygen. You look at a small kid, twice as much oxygen as an adult. An infant under the age of 1, three times as much. Theyโre chewing through oxygen. We have to constantly be aware of that. They are oxygen-dependent little creatures. They have little Ferrari metabolisms, and theyโre fed on oxygen. Respiratory distress: This is a kid whoโs tachypneic. Theyโre breathing fast. Theyโre compensating. Theyโre going to be positioning, tripoding. Use of accessory musclesโyouโre going to see tugging in the neck, seesaw respirations. You want to be listening to this kidโs chest. Theyโre going to be tachycardic. Everything is sped up in respiratory distress. Thatโs where we need to jump on this kid and treat him aggressively. If you see a kid come into the ER in respiratory distress and you read the chart, the doctor gave him albuterol, steroids, antipyretics, antibiotics, a college scholarship. Heโs throwing everything at this kid to keep him from going into respiratory failure. In respiratory failure, everything starts to slow down. The respiratory rate starts to slow down, altered level of consciousnessโhuge, this kid has petered out and heโs losing consciousness now. Bradycardiaโthe heart rate is going to start slowing down. Bradycardia in a child is an ominous sign. This is pre-arrest. This kid is about to arrest on you. In respiratory distress, remember, everything is speeding up. In respiratory failure, everything is starting to slow down. Letโs dive into this algorithm.
First, start CPR. Start your chest compressions. Next, the algorithm says give oxygen. How are you going to give this oxygen? Positive pressure ventilation with 100% oxygen, 100% FiO2. Remember, kids and small children have these huge, giant alien heads on the top of their necks. When theyโre lying flat on their back, this large head puts their airway in deflection. It can really block off their airway. To perform effective bagging on a child, we have to position the airway. We need to get something behind those shoulders, raise the shoulders, allow for that huge melon on the top of their neck, so we can properly align their airway and perform positive pressure ventilations. What are we looking for when we ventilate? Chest rise, the same as an adult. The air should be going in and coming out. Next, get him on a monitor. Is this a shockable rhythm? Shock your patient. The dosing, the amount of energy weโre going to administer to our pediatric patient, the first shock, first defibrillation is 2 J/kg. Subsequent shocks are at 4 J/kg. If you think about itโand I try to make things easyโthat 2 J/kg is the same as the patientโs weight in pounds, right, as 1 kg is 2.2 pounds. Instead of 2 J/kgโand I still think in American terms; I still think pounds, ounces, gallons; Iโm not always thinking metricโif I look at this kid and I have a 25-pound kid, thatโs my first shock, 25 J. The second shock is going to be twice that, 50 J. I tend to think pounds, double-pounds when it comes to defibrillating kids. Now, weโve administered the shock. Immediately after weโve defibrillated this patient, resume chest compressions. While weโre doing the chest compressions, we need to gain vascular access, either intravascular (IV) or IO access, which is very popularโdrill that kidโs leg, gain vascular access. First drug up is epinephrine. Administer epinephrine as quickly as you can. Our dose is 0.01 mg/kg. Thatโs 0.01 mg/kg of 1:10,000 epinephrine. Where the rubber meets the road is you actually have to draw this up and give it to your patient. That 0.01 mg/kg equals 0.1 mL/kg administered. Rather than trying to calculate the dose and how much youโre going to draw up, if youโre using 1:10,000 epinephrine, which you should, that 0.01 mg/kg is the same as 0.1 mL/kg. Draw that up, administer it to your patient. Remember to apply a syringe flush of saline afterwards. We need to move that drug to the heart. We have to get that drug out of the periphery and get it to the heart so it can be effective. So far, weโve gained vascular access and weโve administered our epinephrine. We need to think about an advanced airway. One of the number one reasons that pediatric patients cardiac arrest is respiratory failure, so be thinking early about an advanced airway on your pediatric patient. Youโre going to continue your chest compressions for 2 minutes, then reassess the rhythm. If itโs a shockable rhythm, youโre going to administer another defibrillation. However, this would be your second defibrillation, so youโre going to increase the amount of energy to 4 J/kg, or double-pounds. You gave the first shock, say they weighed 25 pounds, 25 J. Subsequent shock, double that, 50 J. Immediately after your second defibrillation, resume chest compressions. Any time you administer a defibrillation, immediately after you shock them, resume chest compressions. Our next drug up, we need to think about an antiarrhythmic. One of the new guideline changes this year has been between lidocaine and amiodaroneโeither is fine. In 2010, they preferred amiodarone over lidocaine. Iโm a lidocaine guy, everybody knows that. With the new guideline changes, you can select either amiodarone or lidocaine. Theyโve both been proven to be effective. For amiodarone, 5 mg/kg IV push followed by a flush to move that drug to the central circulation. If weโre using lidocaine, 1 mg/kg. Again, IV push followed with a flush to move that drug to the heart. Get it out of the periphery and get it to the heart so it can do something. After weโve administered your antiarrhythmic, be thinking about a reversible cause. Is there a cause why this child cardiac arrested, and can we fix that? We need to assess for it, find it, and fix that reversible cause. If this is not a shockable rhythm, is it asystole or is it PEA (pulseless electrical activity), which is an organized rhythm on the monitor but the patient has no pulse? If this is the case, immediately begin chest compressions, gain vascular accessโeither peripheral IV (again, 2 attempts, 90 seconds is kind of the rule) or if not, go right to intraosseous infusionโand administer epinephrine immediately. The first drug for any pulseless rhythm is always epinephrine. After 2 minutes of chest compressions, reassess the rhythm. Are they now in a shockable rhythm? If they are, administer a defibrillation and move down that side of the algorithm. If theyโre not, continue your chest compressions, continue your bagging, and, again, assess for reversible causes. If we do have a return of spontaneous circulationโweโve shocked them, weโve gotten our airway, we now have a breathing patient, and we have a pulseโwe want to assess the blood pressure, maintain adequate oxygenation, maintain adequate blood pressure, which may require fluids or pressors, and then consider therapeutic hypothermia treatment. If this patient is not responsive and theyโve had a return of spontaneous circulation, think about cooling that patient. Next, where are we going to take this kid? We need to take this child to a facility that can appropriately treat a post cardiac arrest pediatric patient.
Remember, when looking at the pediatric cardiac arrest algorithm, it didnโt start here. There was stuff that came before this. Before the cardiac arrest, there was a respiratory arrest. Before the respiratory arrest, there was respiratory failure. Before the respiratory failure, there was respiratory distress. Thatโs when this algorithm really started.
We have to remember the stress that pediatric arrests can cause everyone involved with the case. Two of my students, last week, while doing their clinical rotations in the ER had their first pediatric arrest. A 2-month-old presented in asystole. They worked this child, and the child expired. As educators, instructors, senior staff, we have to remember that this can be very stressful, especially for the new people. When they came down to my office and they were telling me about this, I put everything away. We had to talk about this for a minute and start our stress debriefing. We started with the emotional aspect of it. How did it make you feel? Believe me, there wasnโt a dry eye in the ER after this case. This was a wonderful family, an unexpected death. This was the worst thing that could possibly happen. So first, thereโs crying, thereโs hugging, and we talk about it, what happened. Then, as an instructor, I had them go through step-by-step everything that was performed on this child. At one point, the student told me that toward the end of the arrest, the doctor opened up and said, โDoes anybody have any other ideas?โ which is appropriate. Did he miss something? Did we all miss something? Is there something else we could have done? Does anybody else have any ideas? What ideas was he looking for? The cause of the arrest, the Hโs and the Tโs. When we got done with the emotional aspect of reviewing this, we moved over to the clinical aspect. I had the students review all the Hโs and Tโs. What could have been the possible cause of this? In an event like this, the best thing we can do is learn from it and then take what we learned to our next pediatric patient, because thereโs going to be one. Remember your critical stress debriefings, address the emotional aspect of the event and then look at the clinical aspect of it. What could we learn from it that we can take to our next patient?
Today we reviewed the pediatric cardiac arrest algorithm. Iโm Mark. Thanks for watching. I will see you in the next video.
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