General anaesthesia is usually induced in an
operating theatre or in an anaesthetic room next to the theatre. It may also be induced in an
endoscopy suite,
intensive care unit,
radiology or
cardiology department,
emergency department, ambulance, or even at the site of a
disaster where extrication of the patient may be impractical. Anaesthetics can be administered by
inhalation,
injection (
intravenous,
intramuscular, or
subcutaneous),
oral, or
rectal routes. Once they enter the
circulatory system, the agents are transported to their biochemical
sites of action in the
central and
autonomic nervous systems. Most general anaesthetics are intravenous or inhaled. Commonly used intravenous induction agents include
propofol,
sodium thiopental,
etomidate,
methohexital, and
ketamine.
Inhalational anaesthesia may be chosen when intravenous access is difficult to obtain (e.g., children), when difficulty maintaining the airway is anticipated, or when the patient prefers it.
Sevoflurane is the most commonly used agent for inhalational induction, because it is less irritating to the
tracheobronchial tree than other agents. As an example sequence of induction drugs: • Pre-oxygenation or denitrogenation to fill lungs with 100% oxygen to permit a longer period of apnea during intubation without affecting blood oxygen levels •
Fentanyl for systemic analgesia during intubation •
Propofol for sedation for intubation • Switching from oxygen to a mixture of oxygen and
inhalational anesthetic once intubation is complete
Laryngoscopy and intubation are both very stimulating. The process of induction blunts the response to these manoeuvres while simultaneously inducing a near-coma state to prevent awareness.
Physiologic monitoring Several
monitoring technologies allow for a controlled induction of, maintenance of, and emergence from general anaesthesia. Standard for basic anesthetic monitoring is a guideline published by the ASA, which describes that the patient's oxygenation, ventilation, circulation and temperature should be continually evaluated during anesthetic. •
Continuous electrocardiography (ECG or EKG):
Electrodes are placed on the patient's skin to monitor heart rate and rhythm. This may also help the anaesthesiologist to identify early signs of heart
ischaemia. Typically lead II and V5 are monitored for arrhythmias and ischemia, respectively. •
Continuous pulse oximetry (SpO2): A device is placed, usually on a finger, to allow for early detection of a fall in a patient's
hemoglobin saturation with oxygen (
hypoxaemia). •
Blood pressure monitoring: There are two methods of measuring the patient's blood pressure. The first, and most common, is non-invasive blood pressure (NIBP) monitoring. This involves placing a
blood pressure cuff around the patient's arm, forearm, or leg. A machine takes blood pressure readings at regular, preset intervals throughout the surgery. The second method is invasive blood pressure (IBP) monitoring, which allows beat to beat monitoring of blood pressure. This method is reserved for patients with significant heart or lung disease, the critically ill, and those undergoing major procedures such as cardiac or transplant surgery, or when large blood loss is expected. It involves placing a special type of plastic
cannula in an artery, usually in the wrist (
radial artery) or groin (
femoral artery). •
Agent concentration measurement:
anaesthetic machines typically have monitors to measure the percentage of inhalational anaesthetic agents used as well as exhalation concentrations. These monitors include measuring
oxygen,
carbon dioxide, and
inhalational anaesthetics (e.g.,
nitrous oxide,
isoflurane). •
Oxygen measurement: Almost all circuits have an alarm in case oxygen delivery to the patient is compromised. The alarm goes off if the fraction of inspired oxygen drops below a set threshold. • A
circuit disconnect alarm or
low pressure alarm indicates failure of the circuit to achieve a given pressure during
mechanical ventilation. •
Capnography measures the amount of
carbon dioxide exhaled by the patient in percent or mmHg, allowing the anaesthesiologist to assess the adequacy of
ventilation; mmHg enables the provider to see more subtle changes. •
Temperature measurement to discern
hypothermia or fever, and to allow early detection of
malignant hyperthermia. •
Electroencephalography,
entropy monitoring, or other systems may be used to verify the depth of anaesthesia. This reduces the likelihood of
anaesthesia awareness and of overdose.
Airway management Anaesthetized patients lose protective airway reflexes (such as coughing),
airway patency, and sometimes a regular breathing pattern due to anaesthetics,
opioids, or
muscle relaxants. To maintain an open airway and regulate breathing, some form of
breathing tube is inserted after the patient is unconscious. To enable
mechanical ventilation, an
endotracheal tube is often used, although there are alternatives such as face masks or
laryngeal mask airways. Generally, full mechanical ventilation is only used if a very deep state of general anaesthesia is to be induced, and/or with a profoundly ill or injured patient. Induction of general anaesthesia usually results in
apnea and requires ventilation until the drugs wear off and spontaneous breathing starts. In other words, ventilation may be needed for induction and maintenance of general anaesthesia, or just during the induction. However, mechanical ventilation can provide ventilatory support during spontaneous breathing to ensure adequate gas exchange. General anaesthesia can also be induced with the patient spontaneously breathing and therefore maintaining their own oxygenation which can be beneficial in certain scenarios (e.g. difficult airway or tubeless surgery). Spontaneous ventilation has been traditionally maintained with inhalational agents (i.e. halothane or sevoflurane) which is called a gas or inhalational induction. Spontaneous ventilation can also be maintained using intravenous anaesthesia (e.g. propofol). Intravenous anaesthesia to maintain spontaneous respiration has certain advantages over inhalational agents (i.e. suppressed laryngeal reflexes) but requires careful titration. Spontaneous Respiration using Intravenous anaesthesia and High-flow nasal oxygen (STRIVE Hi) is a technique that has been used in difficult and obstructed airways.
Eye management General anaesthesia reduces the
tonic contraction of the
orbicularis oculi muscle, causing
lagophthalmos (incomplete eye closure) in 59% of people. In addition, tear production and tear-film stability are reduced, resulting in corneal epithelial drying and reduced
lysosomal protection. The protection afforded by
Bell's phenomenon (in which the eyeball turns upward during sleep, protecting the cornea) is also lost. Careful management is required to reduce the likelihood of
eye injuries during general anaesthesia. Some of the methods to prevent eye injury during general anesthesia includes taping the eyelids shut, use of eye ointments, and specially designed eye protective goggles.
Neuromuscular blockade s prepared with medications that are expected to be used during an operation under general anaesthesia maintained by
sevoflurane gas: -
Propofol, a hypnotic -
Ephedrine, in case of
hypotension -
Fentanyl, for
analgesia -
Atracurium, for
neuromuscular block -
Glycopyrronium bromide (here under trade name Robinul), reducing secretions Paralysis, or temporary muscle relaxation with a
neuromuscular blocker, is an integral part of modern anaesthesia. 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, such as the
abdomen and
thorax, without the need for very deep anaesthesia, and also facilitates
endotracheal intubation.
Acetylcholine, a natural
neurotransmitter found at the
neuromuscular junction, causes muscles to contract when it is released from nerve endings. Muscle paralytic drugs work by preventing acetylcholine from attaching to its receptor. Paralysis of the muscles of respiration—the
diaphragm and
intercostal muscles of the chest—requires that some form of artificial respiration be implemented. Because the muscles of the
larynx are also paralysed, the airway usually needs to be protected by means of an
endotracheal tube. == Maintenance ==