Products from Amazon.com
Price: $17.96Was: $19.95
Price: $65.87Was: $305.00
Price: Check on Amazon
Price: $8.31Was: $13.95
Price: Check on Amazon
A cardiac arrest, also known as cardiorespiratory arrest, cardiopulmonary arrest or circulatory arrest, is the abrupt cessation of normal circulation of the blood due to failure of the heart to contract effectively during systole.
“Arrested” blood circulation prevents delivery of oxygen to all parts of the body. Cerebral hypoxia, or lack of oxygen supply to the brain, causes victims to lose consciousness and to stop normal breathing. Brain injury is likely if cardiac arrest is untreated for more than 5 minutes, although new treatments such as induced hypothermia have begun to extend this time. To improve survival and neurological recovery immediate response is paramount.
Cardiac arrest is a medical emergency that, in certain groups of patients, is potentially reversible if treated early enough (See Reversible Causes, below). When unexpected cardiac arrest leads to death this is called sudden cardiac death (SCD). The primary first-aid treatment for cardiac arrest is cardiopulmonary resuscitation (commonly known as CPR) to provide circulatory support until availability of definitive medical treatment, which will vary dependant on the rhythm the heart is exhibiting, but often requires defibrillation.
During cardiac arrest, the heart stops pumping. as a result, the brain and other organs no longer receive oxygenated blood, without which they cannot function. Within 3 minutes of cardiac arrest, the brain will have sustained some damage. Death is likely to occur within 5 minutes if the pumping action of the heart is not restored by emergency treatment or if circulation is not maintained by external cardiac massage.
Causes of Cardiac Arrest:
Cardiac arrest is synonymous with Clinical death. All disease processes leading to death have a period of (potentially) reversible cardiac arrest: the causes of arrest are, therefore, numerous. However, many of these conditions, rather than causing an arrest themselves, promote one of the “reversible causes” (see below), which then triggers the arrest (e.g. Choking leads to Hypoxia which in turn leads to an arrest). In some cases, the underlying mechanism cannot be overcome, leading to an unsuccessful resuscitation.
Among adults, ischemic heart disease is the predominant cause of arrest. At autopsy 30% of victims show signs of recent myocardial infarction. Other cardiac conditions potentially leading to arrest include structural abnormalities, arrhythmias and cardiomyopathies. Non-cardiac causes include infections, overdoses, trauma and cancer, in addition to many others.
Cardiac arrest is commonly caused by one of two types of electrical problems in the heart: ventricular fibrillation, the more common type, and asystole. During ventricular fibrillation, the ventricles rapidly contract in an uncoordinated manner, preventing the heart from pumping out blood. Ventricular fibrillation may occur suddenly in people with coronary artery disease, for which lifestyle factors such as smoking and a high-fat diet increase the risk. It is also a frequent complication of a heart attack, usually occurring within minutes of the attack. Ventricular fibrillation may be caused by electrical injuries, drowning and dilated cardiomyopathy, in which a disease of the heart muscle reduces its pumping efficiency.
Asystole is an electrical problem of the heart in which there is a total failure of the heart muscle to contract, leading to cardiac arrest. Asystole may be due to suffocation or to disorders or injuries that cause massive bleeding.
Cardiopulmonary resuscitation (CPR), including adjunctive measures such as defibrillation, intubation and drug administration, is the standard of care for initial treatment of cardiac arrest. However, most cardiac arrests occur for a reason, and unless that reason can be found and overcome, CPR is often ineffective, or if it does result in a return of spontaneous circulation, this is short lived. . As highlighted above, a variety of disease processes can lead to a cardiac arrest, however they usually boil down to one or more of the “Hs and Ts” (see below).
Hypovolemia – A lack of circulating body fluids, principally blood volume. This is usually (though not exclusively) caused by some form of bleeding, anaphylaxis, or pregnancy with gravid uterus. Peri-arrest treatment includes giving IV fluids and blood transfusions, and controlling the source of any bleeding – by direct pressure for external bleeding, or emergency surgical techniques such as esophagogastroduodenoscopy (i.e. esophageal varices) and thoracotomy for internal bleeding.
Hypoxia – A lack of oxygen to the heart, brain and other vital organs. This can be identified through a careful assessment of breath sounds and tuble placement. Treatment may include providing oxygen, proper ventilation, and good CPR technique.
Hydrogen ions (Acidosis) – An abnormal pH in the body as a result of shock, Diabetic ketoacidosis, renal failure, or tricyclic antidepressant overdose. This can be treated with proper ventilation, good CPR technique, and buffers like sodium bicarbonate.
Hyperkalemia or Hypokalemia – The most life threatening electrolyte derangement is hyperkalemia (too much potassium). The classic presentation is the chronic renal failure patient who has missed a dialysis appointment and presents with weakness, nausea, and broad QRS complexes on the electrocardiogram. The most important initial therapy is the administration of calcium, either with calcium gluconate or calcium chloride. Other therapies may include nebulized albuterol, sodium bicarbonate, glucose, and insulin. The diagnosis of hypokalemia (not enough potassium) can be suspected when there is a history of diarrhoea or malnutrition. Loop diuretics may also contribute. The electrocardiogram may show depressed T waves and prominent U waves. Hypokalemia is an important cause of acquired long QT syndrome, and may predispose the patient to torsades de pointes. Digitalis use may increase the risk that hypokalemia will produce life threatening arrhythmias.
Hypothermia – A low core body temperature, defined clinically as a temperature of less than 35 degrees Celsius. The patient is re-warmed either by using a cardiac bypass or by irrigation of the body cavities (such as thorax, peritoneum, bladder) with warm fluids; or warmed IV fluids. CPR only is given until the core body temperature reached 30 degrees Celsius, as defibrillation is ineffective at lower temperatures. Patients have been known to be successfully resuscitated after periods of hours in hypothermia and cardiac arrest, and this has given rise to the often-quoted medical truism, “You’re not dead until you’re warm and dead.”
Hypoglycemia or Hyperglycemia – Low blood glucose from insulin reactions, DKA, nonketotic hyperosmolar coma. This condition can be suspected when the patient is known to be a diabetic. The treatment may include fluids, potassium, glucose (for hypoglycemia), and insulin (for hyperglycemia).
Tablets or Toxins – Tricyclic antidepressants, phenothiazines, beta blockers, calcium channel blockers, cocaine, digoxin, aspirin, acetominophen. This may be evidenced by items found on or around the patient, the patient’s medical history (i.e. drug abuse, medication) taken from family and friends, checking the medical records to make sure no interacting drugs were prescribed, or sending blood and urine samples to the toxicology lab for report. Treatment may include specific antidotes, fluids for volume expansion, vasopressors, sodium bicarbonate (for tricyclic antidepressants), glucagon or calcium (for calcium channel blockers), benzodiazepines (for cocaine), or cardiopulmonary bypass.
Cardiac Tamponade – Blood or other fluids building up in the pericardium can put pressure on the heart so that it is not able to beat. This condition can be recognized by the presence of a narrowing pulse pressure, muffled heart sounds, distended neck veins, electrical alternans on the electrocardiogram, or echocardiogram. This is treated in an emergency by inserting a needle into the pericardium to drain the fluid (pericardiocentesis), or if the fluid is too thick then an emergency thoracotomy is performed to cut the pericardium and release the fluid.
Tension pneumothorax – The build up of air into one of the pleural cavities, which causes a mediastinal shift. When this happens, the great vessels (particularly the superior vena cava) become kinked, which limits blood return to the heart. The condition can be recognized by severe air hunger, hypoxia, jugular venous distension, hyperressonance to percussion on the effected side, and a tracheal shift away from the effected side. The tracheal shift often requires a chest x-ray to appreciate. This is relieved in an emergency by a needle thoracotomy (inserting a needle catheter) into the 2nd intercostal space at the mid-clavicular line, which relieves the pressure in the pleural cavity.
Thrombosis (Myocardial infarction) – If the patient can be successfully resuscitated, there is a chance that the myocardial infarction can be treated, either with thrombolytic therapy or percutaneous coronary intervention.
Thromboembolism (Pulmonary embolism) – Usually diagnosed at autopsy. Patients in asystole or pulseless electrical activity have a poor prognosis. If this can be detected early, the patient may receive dopamine, heparin, and thrombolytics.
Trauma (Hypovolemia) – Reduced blood volume from acute injury or primary damage to the heart or great vessels. Cardiac arrest secondary to trauma, particularly blunt trauma, has a very poor prognosis.
Characteristics & Diagnosis:
Cardiac Arrest is an abrupt cessation of pump function (evidenced by absence of a palpable pulse) of the heart that with prompt intervention could be reversed, but without it will lead to death.
Due to inadequate cerebral perfusion, the patient will be unconscious and will have stopped breathing. The main diagnostic criterion to diagnose a cardiac arrest (as opposed to respiratory arrest, which shares many of the same features) is lack of circulation, however there are a number of ways of determining this.
In many cases, lack of carotid pulse is the gold standard for diagnosing cardiac arrest, but lack of a pulse (particularly in the peripheral pulses) may be a result of other conditions (e.g. shock), or simply an error on the part of the rescuer. Studies have shown that rescuers often make a mistake when checking the carotid pulse in an emergency, whether they are healthcare professionals or lay persons.
Owing to the inaccuracy in this method of diagnosis, some bodies such as the European Resuscitation Council (ERC) have de-emphasised its importance. The Resuscitation Council (UK), in line with the ERC’s recommendations and those of the American Heart Association, have suggested that the technique should be used only by healthcare professionals with specific training and expertise, and even then that it should be viewed in conjunction with other indicators such as agonal respiration.
Various other methods for detecting circulation have been proposed. Guidelines following the 2000 International Liaison Committee on Resusciation (ILCOR) recommendations were for rescuers to look for “signs of circulation”, but not specifically the pulse . These signs included coughing, gasping, colour, twitching and movement.However, in face of evidence that these guidelines were ineffective, the current recommendation of ILCOR is that cardiac arrest should be diagnosed in all casualties who are unconscious and not breathing normally.
Following initial diagnosis of cardiac arrest, healthcare professionals further categorise the diagnosis based on the ECG/EKG rhythm. There are 4 rhythms which result in a cardiac arrest. Ventricular fibrillation (VF/VFib) and Pulseless Ventricular tachycardia (VT) are both responsive to a defibrillator and so are colloquially referred to as “Shockable” rhythms, whereas Asystole and Pulseless Electrical Activity (PEA) are non-shockable. The nature of the presenting hearth rhythm suggests different causes and treatment, and is used to guide the rescuer as to what treatment may be appropriate.
Within seconds of a cardiac arrest, the following symptoms usually occur:
Â· loss of consciousness.
Â· blue coloration of the lips, fingers and toes.
An affected person has no pulse and has stopped breathing.
Out of hospital arrest:
Most out-of-hospital cardiac arrests occur following a Myocardial infarction (heart attack), and present initially with a heart rhythm of Ventricular fibrillation. The patient is therefore likely to be responsive to defibrillation, and this has become the focus of pre-hospital interventions. Several organisations promote the idea of a “chain of survival”, of which defibrillation is a key step.
The links are:
Early recognition – If possible, recognition of illness before the patient develops a cardiac arrest will allow the rescuer to prevent its occurrence. Early recognition that a cardiac arrest has occurred is key to survival – for every minute a patient is in cardiac arrest, their chances of survival drop by roughly 10%.
Early CPR – This buys time by keeping vital organs perfused with oxygen whilst waiting for equipment and trained personnel to reverse the arrest. In particular, by keeping the brain supplied with oxygenated blood, chances of neurological damage are decreased.
Early defibrillation – This is the only effective for Ventricular fibrillation, and also has benefit in Ventricular tachycardia. If defibrillation is delayed, then the rhythm is likely to degenerate into Asystole, for which outcomes are markedly worse.
Early post-resuscitation care – Treatment and rehabillitation in a hospital by specialist staff helps to prevent further complications, attempts to fully reverse the underlying cause, and promotes quality of life.
If one or more links in the chain are missing or delayed, then the chances of survival drop significantly. In particular, bystander CPR is an important indicator of survival: if it has not been carried out, then resuscitation is associated with very poor results. Paramedics in some jurisdictions are authorised to abandon resuscitation altogether if the early stages of the chain have not been carried out in a timely fashion prior to their arrival.
Because of this, considerable effort has been put into educating the public on the need for CPR. In addition, there is increasing use of public access defibrillation. This involves placing Automated external defibrillators in public places, and training key staff in these areas how to use them. This allows defibrillation to take place prior to the arrival of emergency services, and has been shown to lead to increased chances of survival. In addition, it has been shown that those who suffer arrests in remote locations have worse outcomes following cardiac arrest : these areas often have First responder schemes, whereby members of the community receive training in resuscitation and are given a defibrillator, and called by the emergency medical services in the case of a collapse in their local area.
Treatment within a hospital usually follows advanced life support protocols. Depending on the diagnosis, various treatments are offered, ranging from defibrillation (for ventricular fibrillation or ventricular tachycardia) to surgery (for cardiac arrest which can be reversed by surgery – see causes of arrest, above) to medication (for asystole and PEA). All will includeCPR.
The period (either before or after) surrounding a cardiac arrest is known as the peri-arrest period. During this period the patient is in a highly unstable condition and must be constantly monitored in order to halt the progression or repeat of a full cardiac arrest. The preventative treatment used during the peri-arrest period depends on the causes of the impending arrest and the likelihood such an event occurring.
The out-of-hospital cardiac arrest (OHCA) has a worse survival rate (2-8% at discharge and 8-22% on admission), than an in-hospital cardiac arrest (15% at discharge). The principal determining factor is the initially documented rhythm. Patients with VF/VT have 10-15 times more chance of surviving than those suffering from Pulseless electrical activity or Asystole (as they are sensitive to defibrillation, whereas asystole and PEA are not).
Since mortality in case of OHCA is high, programs were developed to improve survival rate. A study by Bunch et al showed that, although mortality in case of ventricular fibrillation is high, rapid intervention with a defibrillator increases survival rate to that of patients that did not have a cardiac arrest.
Survival is mostly related to the cause of the arrest (see above). In particular, patients who have suffered hypothermia have an increased survival rate, possibly because the cold protects the vital organs from the effects of tissue hypoxia. Survival rates following an arrest induced by toxins is very much dependent on identifying the toxin and administering an appropriate antidote. A patient who has suffered a myocardial infarction due to a blood clot in the Left coronary artery has a lower chance of survival as it cuts of the blood supply to most of the left ventricle (the chamber which must pump blood to the whole of the systemic circulation).
Cobbe et al (1996) conducted a study into survival rates from out of hospital cardiac arrest. 14.6% of those who had received resuscitation by ambulance staff survived as far as admission to an acute hospital ward. Of these, 59.3% died during that admission, half of these within the first 24 hours. 46.1% survived to hospital discharge (this is 6.75% of those who had been resuscitated by ambulance staff), however 97.5% suffered a mild to moderate neurological disability, and 2% suffered a major neurological disability. Of those who were successfully discharged from hospital, 70% were still alive 4 years after their discharge.
Ballew (1997) performed a review of 68 earlier studies into prognosis following in-hospital cardiac arrest. They found a survival to discharge rate of 14% (this roughly double the rate for out of hospital arrest found by Cobbe et al (see above)), although there was a wide range (0-28%).
Several high profile organisations (such as St John Ambulance and the British Heart Foundation) have promoted the “Chain of Survival”, which is made up of 4 links, as a way to maximise prognosis following arrest:
Early Access – Identifying patients at risk of cardiac arrest early is the best way of improving prognosis, as it is often possible to prevent the arrest. Similarly, if the arrest is witnessed there is a much greater chance of survival, as treatment can begin straight away before tissue hypoxia sets in.
Early CPR – CPR is unlikely to revive the patient, but it does buy some time by keeping a (limited) circulation going until it is possible to reverse the arrest, thereby increasing the chances of this reversal being successful, and minimising the risk of cerebral hypoxia (which can lead to neurological impairment following return of circulation).
Early defibrillation – Patients who present with VF/VT can be defibrillated, and the earlier this happens the better, as VF/VT often degenerate into asystole (which is unshockable).
Early hospital care – Many patients suffer further arrests within the first 24 hours of admission, so it is better that they are in hospital where their chances of survival are a little higher.
With positive outcomes following cardiac arrest so unlikely, a great deal of effort has been spent in finding effective strategies to prevent cardiac arrest.
As noted above, one of the prime causes of cardiac arrest outside of hospital is ischemic heart disease. Vast resources have been put into trying to reduce cardiovascular risks across much of the developed world. In particular schemes have been put in place to promote a healthy diet and exercise. For people considered to be particularly at risk of heart disease, measures such as blood pressure control, prescription of cholesterol lowering medications, and other medico-therapeutic interventions, have been widely used. A magnesium deficiency, or lower levels of magnesium, can contribute to heart disease and a healthy diet that contains adequte magnesium may help prevent heart disease. Magnesium can be used to enhance long term treatment, so it may be effective in long term prevention.
Patients in hospital are far less likely to have a cardiac arrest caused of primary cardiac origin, and hence present in Asystole or PEA, and have bleak outcomes . Extensive research has shown that patients in general wards often deteriorate for several hours or even days before a cardiac arrest occurs . This has been attributed to a lack of knowledge and skill amongst ward based staff, in particular a failure to carry out measurement of the Respiratory rate, which is often the major predictor of a deterioration and can often change up to 48 hours prior to a cardiac arrest. In response to this, many hospitals now have increased training for ward based staff. A number of “early warning” systems also exist which aim to quantify the risk which patients are at of deterioration based on their vital signs and thus provide a guide to staff. In addition, specialist staff are being utilised more effectively in order to augment the work already being done at ward level. These include:
Crash teams (also known as Code teams) – These are designated staff members who have particular expertise in resuscitation, who are called to the scene of all arrests within the hospital.
Medical Emergency Teams – These teams respond to all emergencies, with the aim of treating the patient in the acute phase of their illness in order to prevent a cardiac arrest.
Critical care outreach – As well as providing the services of the other two types of team, these teams are also responsible for educating non-specialist staff. In addition, they help to facilitate transfers between intensive care/high dependency units and the general hospital wards. This is particularly important, as many studies have shown that a significant percentage of patients discharged from critical care environments quickly deteriorate and are re-admitted – the outreach team offers support to ward staff to prevent this from happening.
Implantable cardioverter defibrillators
A technically based intervention to prevent further cardiac arrest episodes is the use of an implantable cardioverter-defibrillator (ICD). This device is implanted in to the patient and can offer a ‘pacemaker’ effect to the heart as well as acting as an instant defibrillator in the event of arrhythmia. A recent study by Birnie et al at the University of Ottawa Heart Institute has demonstrated that ICDs are underused in both the United States and Canada. An accompanying editorial by Simpson explores some of the economic, geographic, social and political reasons for this.
Disclaimer: This information is not meant to be a substitute for professional medical advise or help. It is always best to consult with a Physician about serious health concerns. This information is in no way intended to diagnose or prescribe remedies.This is purely for educational purpose.