In modern medical practice, general anesthesia (AmE: anesthesia) is a state of total unconsciousness resulting from general anesthetic drugs. A variety of drugs are given to the patient that have different effects with the overall aim of ensuring unconsciousness, amnesia and analgesia. The anesthetist selects the optimal technique for any given patient and procedure. The biological mechanism of action of general anesthetics is not well understood.
Contents |
General anesthesia is a complex procedure involving:
Prior to surgery, the anesthetist interviews the patient to determine the best combination of drugs and dosages and the degree to which monitoring is required to ensure a safe and effective procedure. Key factors of this determination are the patient's age, weight, medical history, current medications, previous anesthetics, and fasting time. Patients are typically required to fill out this information on a separate form during the pre-operative evaluation. Depending on the existing medical conditions reported, the anesthetist will review this information with the patient either during the pre-operative evaluation or on the day of the surgery.
Truthful and accurate answering of the questions is important so that the anesthetist can select the proper anesthetic drugs and procedures. For example, a heavy drinker or drug user who does not disclose their chemical uses could be undermedicated, which could then lead to anesthesia awareness or dangerously high blood pressure. Commonly used medications such as Viagra can interact with anesthesia drugs; failure to disclose such usage can endanger the patient.
An important aspect of this assessment is that of the patient's airway, involving inspection of the mouth opening and visualisation of the soft tissues of the pharynx. The condition of teeth and location of dental crowns and caps are checked, neck flexibility and head extension observed. If an endotracheal tube is indicated and airway management is deemed difficult, then alternative placement methods such as fibreoptic intubation may be required, after induction of anesthesia.
Anesthesiologists may prescribe or administer a sedative pre-medication by injection or by mouth anywhere from a couple of hours to a couple of minutes before induction.
The most common drugs used for pre-medication are narcotics (opioids such as fentanyl) and sedatives (most commonly benzodiazepines such as midazolam).
General anesthesia implies loss of consciousness and of protective reflexes. General anesthesia is traditionally described as comprising of 3 components: hypnosis, relaxation and analgesia.
Hypnosis or sleep refers to being deeply asleep, unconscious, and totally unaware of events.
Relaxation implies abolition of reflex muscle tone, or specific block of nerve/muscle function, causing immobility and allowing easy surgical access.
Analgesia refers to use of one or more of a wide range of pain reducing drugs from paracetamol to morphine, and perhaps local anesthetics to block pain impulse transmission along nerves, in the hope of reducing heart rate and blood pressure responses to surgery.
The general anesthetic is administered in either the operating theatre itself or a special ante-room.
General anesthesia can be induced by intravenous (IV) injection, or breathing a volatile anesthetic through a facemask (inhalational induction). Onset of anesthesia is faster with IV injection than with inhalation, taking about 10–20 seconds to induce total unconsciousness. This has the advantage of avoiding the excitatory phase of anesthesia (see below), and thus reduces complications related to induction of anesthesia. An inhalational induction may be chosen by the anesthesiologist where IV access is difficult to obtain, where difficulty maintaining the airway is anticipated, or due to patient preference (e.g. children). Commonly used IV induction agents include propofol, sodium thiopental, etomidate, and ketamine. The most commonly-used agent for inhalational induction is sevoflurane because it causes less irritation than other inhaled gases.
The duration of action of IV induction agents is generally 5 to 10 minutes, after which time spontaneous recovery of consciousness will occur. In order to prolong anesthesia for the required duration (usually the duration of surgery), anesthesia must be maintained. Usually this is achieved by allowing the patient to breathe a carefully controlled mixture of oxygen, nitrous oxide, and a volatile anesthetic agent or by having a carefully controlled infusion of medication, usually propofol, through an IV. The inhalation agents are transferred to the patient's brain via the lungs and the bloodstream, and the patient remains unconscious. Inhaled agents are frequently supplemented by intravenous anesthetics, such as opioids (usually fentanyl or a fentanyl derivative) and sedative-hypnotics (usually propofol or midazolam). Though for a propofol-based anesthetic, supplementation by inhalation agents is not required. At the end of surgery the volatile or intravenous anesthetic is discontinued. Recovery of consciousness occurs when the concentration of anesthetic in the brain drops below a certain level (usually within 1 to 30 minutes depending upon the duration of surgery).
In the 1990s a novel method of maintaining anesthesia was developed in Glasgow, UK. Called TCI (target controlled infusion), this involves using a computer controlled syringe driver (pump) to infuse propofol throughout the duration of surgery, removing the need for a volatile anesthetic, and allowing pharmacologic principles to more precisely guide amount of infusion of the drug. Purported advantages include faster recovery from anesthesia, reduced incidence of post-operative nausea and vomiting, and absence of a trigger for malignant hyperthermia. At present, TCI is not permitted in the United States.
Other medications will occasionally be given to anesthetized patients to treat side effects or prevent complications. These medications include antihypertensives to treat high blood pressure, drugs like ephedrine and phenylephrine to treat low blood pressure, drugs like albuterol to treat asthma or laryngospasm/bronchospasm, and drugs like epinephrine or diphenhydramine to treat allergic reactions. Sometimes glucocorticoids or antibiotics are given to prevent inflammation and infection, respectively.
"Paralysis" or temporary muscle relaxation with a neuromuscular blocker is an integral part of modern anesthesia. The first drug used for this purpose was curare, introduced in the 1940s, which has now been superseded by drugs with fewer side effects and generally shorter duration of action.
Muscle relaxation allows surgery within major body cavities, e.g. abdomen and thorax without the need for very deep anesthesia, and is also used to facilitate endotracheal intubation.
Acetylcholine, the natural neurotransmitter substance at the neuromuscular junction, causes muscles to contract when it is released from nerve endings. Muscle relaxants work by preventing acetylcholine from attaching to its receptor.
Paralysis of the muscles of respiration, i.e. the diaphragm and intercostal muscles of the chest requires that some form of artificial respiration be implemented. As the muscles of the larynx are also paralysed, the airway usually needs to be protected by means of an endotracheal tube.
Monitoring of paralysis is most easily provided by means of a peripheral nerve stimulator. This device intermittently sends short electrical pulses through the skin over a peripheral nerve while the contraction of a muscle supplied by that nerve is observed.
The effects of muscle relaxants are commonly reversed at the termination of surgery by anticholinesterase drugs.
Examples of skeletal muscle relaxants in use today are pancuronium, rocuronium, vecuronium, atracurium, mivacurium, and succinylcholine.
With the loss of consciousness caused by general anesthesia, there is loss of protective airway reflexes (such as coughing), loss of airway patency and sometimes loss of a regular breathing pattern due to the effect of anesthetics, opioids, or muscle relaxants. To maintain an open airway and regulate breathing within acceptable parameters, some form of "breathing tube" is inserted in the airway after the patient is unconscious. To enable mechanical ventilation, an endotracheal tube is often used (intubation), although there are alternative devices such as face masks or laryngeal mask airways.
Monitoring involves the use of several technologies to allow for a controlled induction of, maintenance of and emergence from general anesthesia.
1. Continuous Electrocardiography (ECG): The placement of electrodes which monitor heart rate and rhythm. This may also help the anesthetist to identify early signs of heart ischemia.
2. Continuous pulse oximetry (SpO2): The placement of this device (usually on one of the fingers) allows for early detection of a fall in a patient's haemoglobin saturation with oxygen (hypoxemia).
3. Blood Pressure Monitoring (NIBP or IBP): There are two methods of measuring the patient's blood pressure. The first, and most common, is called non-invasive blood pressure (NIBP) monitoring. This involves placing a blood pressure cuff around the patient's arm, forearm or leg. A blood pressure machine takes blood pressure readings at regular, preset intervals throughout the surgery. The second method is called invasive blood pressure (IBP) monitoring. This method is reserved for patients with significant heart or lung disease, the critically ill, major surgery such as cardiac or transplant surgery, or when large blood losses are expected. The invasive blood pressure monitoring technique involves placing a special type of plastic cannula in the patient's artery - usually at the wrist or in the groin.
4. Agent concentration measurement - Common anesthetic machines have meters to measure the percent of inhalational anesthetic agent used (e.g. sevoflurane, isoflurane, desflurane, halothane etc.).
5. Low oxygen alarm - Almost all circuits have a backup alarm in case the oxygen delivery to the patient becomes compromised. This warns if the fraction of inspired oxygen drops lower than room air (21%) and allows the anesthetist to take immediate remedial action.
6. Circuit disconnect alarm - indicates failure of circuit to achieve a given pressure during mechanical ventilation.
7. Carbon dioxide measurement (capnography)- measures the amount of carbon dioxide expired by the patient's lungs. It allows the anesthetist to assess the adequacy of ventilation
8. Temperature measurement to discern hypothermia or fever, and to aid early detection of malignant hyperthermia.
9. EEG or other system to verify depth of anesthesia may also be used. This reduces the likelihood that a patient will be mentally awake, although unable to move because of the paralytic agents. It also reduces the likelihood of a patient receiving significantly more amnesic drugs than actually necessary to do the job.
The four stages of anesthesia were described in 1937.[1] Despite newer anesthetic agents and delivery techniques, which have led to more rapid onset and recovery from anesthesia, with greater safety margins, the principles remain.
Stage 1 anesthesia, also known as the "induction", is the period between the initial administration of the induction medications and loss of consciousness. During this stage, the patient progresses from analgesia without amnesia to analgesia with amnesia. Patients can carry on a conversation at this time.
Stage 2 anesthesia, also known as the "excitement stage", is the period following loss of consciousness and marked by excited and delirious activity. During this stage, respirations and heart rate may become irregular. In addition, there may be uncontrolled movements, vomiting, breath holding, and pupillary dilation. Since the combination of spastic movements, vomiting, and irregular respirations may lead to airway compromise, rapidly acting drugs are used to minimize time in this stage and reach stage 3 as fast as possible.
Stage 3, "surgical anesthesia". During this stage, the skeletal muscles relax, and the patient's breathing becomes regular. Eye movements slow, then stop, and surgery can begin.
It has been divided into 4 planes:
Stage 4 anesthesia, also known as "overdose", is the stage where too much medication has been given and the patient has severe brain stem or medullary depression. This results in a cessation of respiration and potential cardiovascular collapse. This stage is lethal without cardiovascular and respiratory support. This can be fatal.
The anesthesia should conclude with a pain-free awakening and a management plan for postoperative pain relief. This may be in the form of regional analgesia, oral, transdermal or parenteral medication. Minor surgical procedures are amenable to oral pain relief medications such as paracetamol and NSAIDs such as ibuprofen. Moderate levels of pain require the addition of mild opiates such as tramadol.
Major surgical procedures may require a combination of modalities to confer adequate pain relief. Parenteral methods include patient-controlled analgesia (PCA) involving a strong opiate such as morphine, fentanyl or oxycodone. Here, to activate a syringe device, the patient presses a button and receives a preset dose or "bolus" of the drug (e.g. one milligram of morphine). The PCA device then "locks out" for a preset period, e.g. 5 minutes, to allow the drug to take effect. If the patient becomes too sleepy or sedated, they make no more morphine requests. This confers a fail safe aspect which is lacking in continuous opiate infusion techniques.
Shivering is a frequent occurrence in the post-operative period. Apart from causing discomfort and exacerbating post-operative pain, shivering has been shown to increase oxygen consumption, catecholamine release, cardiac output, heart rate, blood pressure and intra-ocular pressure. There are a number of techniques used to reduce this occurrence, such as increasing the ambient temperature in theatre, using conventional or forced warm air blankets and using warmed intravenous fluids.[2]
Perioperative mortality is most commonly related to surgical complications or pre-existing medical conditions. These include major haemorrhage, sepsis, and failure of vital organs (e.g. heart, lungs, kidneys, liver). Mortality directly related to anesthetic management may include such causes as aspiration of stomach contents, asphyxiation, anaphylaxis. These in turn may result from human error or malfunction of anesthesia-related equipment.
In a review of 599,548 surgical procedures at 10 hospitals in the United States between 1948-1952, 384 deaths were attributed to anesthesia, for an overall mortality rate of 0.64%.[3] After becoming something of a public scandal, an effort was made to understand the causes and improve the results.[4] It is generally believed that anesthesia is now at least ten times safer than it was then.[5] However, there is some controversy about this.[6] In the U.S., the data is not made public (in fact, the data are not even collected), so the truth is uncertain.[4] The death rate for dental anaesthesia is reported to be one out of 350,000.