Psychosocial indications

Indications relating to anxieties regarding dental treatment include:

Medical indications

Some conditions may be aggravated by the stress of undergoing dental treatment:

Many patients with these conditions can be treated quite ‘normally’ with local analgesic injections and tender loving care on the part of a sympathetic dentist. There are, however, a group of patients who, in addition to having a medical condition, also become quite anxious about dental treatment. A history of aggravation of the pre-existing condition in the dental environment may be the only clue as to the patient’s concerns.

Some conditions affect the patient’s ability to co-operate with dental treatment:

The use of sedation aids the management of these patients. The most important requirement is that the patient is able to understand what is being done. Lack of understanding will lead to failure of the technique. The assessment of a patient’s understanding is extremely difficult.

Dental indications

Sedation may be required for difficult or unpleasant procedures (e.g. extraction of wisdom teeth) or for orthodontic extractions, particularly in patients with limited previous dental care experience. The proper prescribing of sedation for these indications can help to prevent many patients having to suffer unpleasant experiences. It is well recognised that patients who have had a wisdom tooth surgically removed are more likely to fail than attend the appointment for the second surgical removal.

Psychosocial contraindications

Patients must be willing and co-operative. A failure to consent for treatment is an absolute contraindication to the provision of care under sedation. Similarly, patients must co-operate to allow the administration of the sedative agents by a given route. Failure to do so will prevent the dentist being able to treat the patient.

Medical contraindications

Dental contraindications

The dental contraindications to sedation fall into two groups:

All forms of dental treatment may be carried out under sedation. The judgement as to whether it is appropriate to carry out any particular treatment must be made on a patient-to-patient basis.

The assessment process

The assessment process follows similar lines to the history taking and examination of all dental patients.

1. The length of time it takes to eliminate the parent drug (the elimination half-life).

2. Whether the elimination process produces metabolites that are themselves pharmacologically active.

• anxiolysis

• anticonvulsive

• mild sedation

• decreased attention

• amnesia

• more profound sedation

• muscle relaxation

• anaesthesia or hypnosis.

Mechanism of action

Benzodiazepines have two distinct mechanisms of action. In higher centres of the brain, benzodiazepines bind to a receptor that controls sodium ion movement. The receptor is closely associated with a receptor for the endogenous, inhibitory neurotransmitter gamma-aminobutyric acid (GABA). The action of GABA allows chloride ions from the extracellular fluid to enter the cell. This makes the cell more negatively charged and, therefore, less likely to fire. The benzodiazepines increase the affinity of the GABA receptor for its transmitter and, thus, increase the inhibitory action of GABA. This action of the benzodiazepines is responsible for the sedative and anticonvulsant properties of this group of drugs.

The second mechanism of action is seen at lower centres in the brain stem and spinal cord. Here the benzodiazepines mimic the action of another inhibitory neurotransmitter, glycine. This action of the benzodiazepines is responsible for the anxiolytic and muscle relaxant actions.

Repeated administration of benzodiazepines (e.g. when used as oral anxiolytic agents) produces tolerance to the effects that are mediated via GABA. The effects produced by mimicking glycine are, however, largely unaltered.

The amnesic actions of benzodiazepines are poorly understood. The administration causes anterograde amnesia (i.e. from the point of administration forwards in time). Long-term memory is affected more than short-term memory, and therefore patients remember less the week after the appointment than at the point of discharge.

Side-effects of intravenous benzodiazepines

The principal side-effect of intravenous benzodiazepine administration is respiratory depression. This is produced by two mechanisms. First, the muscle relaxant actions of the drugs affect the respiratory muscles, namely the intercostal muscles and the diaphragm. This reduces the efficiency of the contractions. Second, as with all drugs that depress the central nervous system (CNS), the carbon dioxide receptors in the brain are affected, resulting in a lesser response to changes in blood carbon dioxide. Consequently, although the patient can breathe and will take deep breaths with suitable encouragement, they do not feel the need to breathe.

The second notable side-effect is that of sexual fantasy production. Such fantasies have been described in the literature, although again the mechanism is unclear. It is also unclear why patients may remember the fantasy but yet have no memory of any treatment that has been carried out. The incidence is unknown, but it appears to be dose related with a threshold for midazolam of 0.1 mg/kg body weight. No member of the dental team must ever be left alone with a sedated patient, in case this should result in an allegation being made.

Available benzodiazepines for sedation

Benzodiazepine antagonist drugs

Clinical effects of propofol

The action of propofol is to enhance the effect of GABA. This is accomplished via a different mechanism from the benzodiazepines, allowing its use in regular benzodiazepine users.

Sedative doses of propofol produce a different quality of sedation from benzodiazepines. The effect is closer to a pure anxiolysis. This can be associated with patients becoming more talkative.

The amnesic actions of propofol are less predictable than those of benzodiazepines.

Side-effects of propofol

Propofol causes depressant effects on the cardiovascular system. It will cause a fall in arterial blood pressure and heart rate. Falls of 25–35% in systolic blood pressure have been recorded, but are of little clinical significance to young, fit and healthy patients treated in the supine position.

Although propofol does produce profound respiratory depression in anaesthetic doses, it would appear that in sedative doses less respiratory depression is seen with propofol than with midazolam.

Pain on injection (especially when small veins are used) is the most common cause of complaint from patients. Mixing a small amount of plain lidocaine with the solution can prevent this.

As with the other sedatives described, sexual fantasies have been described by patients receiving propofol sedation.

The distribution and elimination of propofol

Propofol has an extremely short redistribution half-life. This accounts for the rapid patient recovery from sedation. The elimination from the body takes longer, and thus patients may have residual effects that they fail to appreciate.

Physical properties of nitrous oxide

Nitrous oxide is a gas at room temperature and pressure. It is colourless and is sometimes described as having a sweet odour. It is 1.5 times as heavy as air and tends to collect at floor level. Pressurised nitrous oxide will liquefy, as its critical temperature (the temperature above which it cannot exist as a liquid) is 36.5°C. Nitrous oxide cylinders contain a mixture of gaseous and liquid nitrous oxide at a pressure of approximately 640 psi.

Anaesthetic and analgesic properties

Nitrous oxide is a weak anaesthetic agent. The MAC₅₀ value (i.e. the theoretical value that would provide surgical anaesthesia for 50% of the population) is 110%. This can be contrasted with isoflurane at 1.15%. Nitrous oxide is insoluble in blood (blood:gas partition 0.47), which means that there is a rapid equilibration between the concentration of nitrous oxide in the alveoli and that in the blood, and induction of and recovery from sedation is extremely rapid.

The main effects of nitrous oxide are mood alteration, particularly euphoria, and analgesia. An inspired concentration of 50% nitrous oxide equates to approximately 15 mg morphine, particularly when considering ischaemic muscle pain.

Effects of chronic exposure to nitrous oxide

It should be emphasised that there are virtually no problems of acute exposure for patients, provided that physiological concentrations of oxygen are administered with the nitrous oxide. There are, however, a number of potential problems with chronic exposure:

All of these effects tend only to be seen when there is not active scavenging of waste gases.

Inhalation sedation

Techniques of inhalation sedation tend to fluctuate in popularity. It has also been described by a number of names such as relative analgesia, inhalational sedation or inhalation psychosedation. All the widely available techniques involve the use of mixtures of nitrous oxide and oxygen.