Clinical Policy CLN 14-001 Treatment of Cardiac Arrest Patients with Confirmed Renal Failure
May 25, 2015
Clinical Policy CLN 14-001
Treatment of Cardiac Arrest Patients with Confirmed Renal
Failure
Purpose:
This self learning program has been developed to in service CPHM EMS personnel on the new clinical policy in which goes into effect June 17, 2014.
Dr Janikas has noted the need for CPHM EMS staff to be able to readily access Dialysis Patient’s dialysis catheters in cardiac arrest.
It has also been recognized that many of these patients are in cardiac arrest directly due to Hyperkalemia and this policy allows for Paramedic level staff to administer Sodium Bicarbonate and Calcium Gluconate on standing orders.
Objectives
1. Review of Hyperkalemia
2 Accessing a Dialysis Catheter
3. Review of Policy CLN 14-001
Hyperkalemia
Hyperkalemia occurs when the extracellular potassium ion [K+] concentration is above the normal value. It is a potentially life-threatening emergency that can be corrected with treatment.
Potassium
It is essential for the normal functioning of the muscles, heart, and nerves. Potassium helps the body regulate activity of muscle, including the:
Smooth muscles
Skeletal muscles
Cardiac muscle
Potassium is very important for maintaining normal heart electrical rhythm as well as conduction for normal electrical signals in the nervous system.
Potassium levels
The normal potassium level in the blood is 3.5-5.0 milliEquivalents per liter (mEq/L).
Potassium levels between 5.1 mEq/L to 6.0 mEq/L are considered to be mild hyperkalemia.
Potassium levels of 6.1 mEq/L to 7.0 mEq/L are moderate hyperkalemia, and levels above 7 mEq/L reflect severe hyperkalemia.
Hyperkalemia
Excess potassium in the bloodstream can result from diseases of the kidneys or adrenal glands as well as from certain medications.
Hyperkalemia can also be the result of potassium moving out of its usual location within cells into the bloodstream.
Generally 98% of the body’s Potassium is in the cells, with 2% in the circulation.
There are many causes that can move the intracellular Potassium into the circulation.
Hyperkalemia Causes Chronically recurring hyperkalemia is most commonly
seen in patients with chronic kidney disease (CKD), as the decline of renal function compromises the kidney's ability to properly excrete K+.
Additionally, renin-angiotensin-aldosterone inhibitor therapy, the current standard of care for CKD and heart failure that has been proven to delay progression to end-stage renal disease, often exacerbates Hyperkalemia (Angiotension II receptor blockers).
Medications such as: NSAIDS, ACE inhibitors, and Succinylcholine.
Hyperkalemia Causes
Any condition which there is massive tissue destruction can result in elevated levels of Potassium.
Trauma, burns, rhabdomyolysis, and destruction of red blood cells.
Hyperkalemia Symptoms
Clinical presentation of hyperkalemia is highly variable with some pt’s with acute illness, and other who are aysmptomatic.
Symptoms do not become apparent until levels are very high, 6.5 and greater. Most symptoms are nonspecific:
Muscle weakness, tiredness, tingling sensations, or nausea.
Hyperkalemia does have an effect on the pt’s EKG.
Hyperkalemia and the EKG
Hyperkalemia causes rapid reduction in the resting membrane potential leading to increased cardiac depolarization & muscle excitability.
The classic criteria has been “Peaked T waves”.
Peaked T waves are best seen in the precordial leads, shortened QT interval, and sometimes ST segment depression.
Widening of the QRS complex (usually potassium level is 6.5 or greater). This frequently appears as in "non-specific intraventricular conduction delay" or IVCD which is characterized by a widened QRS complex of > 120 ms that does not meet the criteria for a left or right bundle branch block.
Hyperkalemia
Hyperkalemia and the EKG
Decreased amplitude of the P waves, an increase in the PR interval, and bradycardia in the form of AV blocks occur as the potassium level exceeds 7.0.
Absence of the P waves and eventually a "sine wave" pattern (see below) which is frequently a fatal rhythm.
Hyperkalemia Symptoms
CLINICAL PEARLS:
Supportive measurements like fluids, pacing, and pressors do not work in the setting of hyperkalemia. You must treat the hyperkalemia first.
The ECG changes with hyperkalaemia do not consistently follow a stepwise, dose-dependent pattern. In reality, many patients have rapid changes in their ECG. The risk of arrhythmias increase with K+ values > 6.5 mmol/L and even small elevations in K+ above this concentration can lead to rapid progression from peaked T waves to ventricular fibrillation. The longer a patient has high K+ concentrations, the greater the risk of sudden deterioration.
Giving intravenous calcium is "cardioprotective" in the setting of hyperkalemia. Frequently instant reversal of all hyperkalemic ECG changes within seconds of administration (see example 4 below). Calcium does not decrease the potassium levels, so other therapy like bicarbonate or insulin is needed to do this. Calcium administration can be fatal when digoxin toxicity is causing the hyperkalemia and should be avoided.
Dialysis Catheters
Dialysis catheters are typically placed in the neck or upper chest.
Access ONLY one port.
Use strict aseptic technique (all connectors should be cleaned with Betadine or Chlorahexadine swabs).
Catheters are filled with a Heparin solution. You must withdraw 5-10cc of fluid/blood prior to attaching IV tubing. Then gently flush with normal saline bolus to confirm patency.

Dialysis Catheters
Catheters come in various shapes, sizes, and number of ports.
Remember access only one port at a time.
Only infuse through one port.
If Dialysis staff is present consider asking staff to access port for you.
Dialysis Catheters
Remember these catheters are directly into the great vessels. AVOID AIR EMBOLI at all costs. Clamp catheter (using only the clamp on the catheter) prior to taking caps off and attaching IV tubing.
Do not allow air to enter the central circulation due to any air in the IV tubing.
Don’t forget to unclamp the catheter once everything is attached!
Policy CLN 14-001
ON STANDING ORDER PER MD 420
Cardiac Monitor Defibrillate as appropriate
Access dialysis catheter if available If dialysis catheter is not available, initiate IV
access
Calcium Chloride 1 gram IV Bolus
Sodium Bi-Carbonate 50 mEq IV Bolus
Continue to appropriate cardiac arrest protocol based on patient’s underlying rhythm.
Policy CLN 14-001
This policy may ONLY be used while working as a Paramedic with Clifton Park Halfmoon EMS. It is not valid when working with any other agency.
Calcium and Bicarb may take time to have an effect on the patient. The most useful tools are Insulin and Dialysis.
Be prepared for an extended code, and transport your patient to an appropriate Emergency Room.
Advise the ED you suspect this cardiac arrest is related to hyperkalemia.
Please review attached policy CLN 14-001.
Please complete quiz attached to this LearnEMS module.
Any questions can be directed to Clinical Services or Dr. Janikas.
Thank You.