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S Afr Fam Pract
ISSN 2078-6190    EISSN 2078-6204 

© 2018 The Author(s)

NW REFRESHER COURSE

Anaesthesia and dentistry have a long mutual history, and have 

developed in parallel over a similar time period. The first sedation 

for dental extraction took place on 11 December 1844 when 

the dentist Horace Wells had his wisdom tooth removed under 

nitrous oxide sedation.1,2 This was 2 years before William Morton 

performed the first ether general anaesthetic.2

Since then, advances in anaesthesia have been mirrored by 

progress in the type of dental techniques possible. The discovery 

of local anaesthetic agents in particular enabled the advent of 

modern dentistry.1

Today the majority of dental work is performed under local 

anaesthesia alone. Patient satisfaction is certainly greatest when 

local anaesthesia alone is used. An old study by Jeffrey Camm 

and colleagues showed very elegantly that the incidence of 

paediatric patient behavioural changes as well as parental stress 

were both similar and much greater when children received 

either sedation or general anaesthesia as opposed to local 

anaesthesia only.3 There are still numerous instances where 

additional sedation or general anaesthesia is required, however. 

Most notably these include all children under 10 years of age. 

While the provision of general anaesthesia clearly falls within the 

realm of the anaesthetist, this distinction is not always so obvious 

with sedation, particularly in the minds of our dental colleagues. 

Dentists in the United States of America (USA) in particular have 

been extremely resistant to involve the anaesthetist in dental 

room sedation. Tragically, this has become topical because of 

the recent high number of adverse events including death in the 

USA. Typically these have been ASA 1 children.

Alarmingly the situation in South Africa is not that different.  

In 2015 Faizel Bham performed a study to audit dental chair 

sedation practice in Gauteng.4 Following random sampling,  

213 dentists were interviewed. Ninety-four (44.1%) of them 

routinely practised paediatric dental chair procedural sedation 

and analgesia (PSA). This group of 94 dentists was asked to 

complete an online survey, to which 52 (55.9%) responded. The 

results were as follows:

• The overall PSA rate offered is 44.1%.

• Most patients are 1–5 years old. (76.6% < 6 years).

• Minimal to moderate sedation endpoints are targeted.

• Midazolam is the most frequently used agent. This is 

occasionally supplemented with Nitrous Oxide (N2O).

• More than 3 agents are used in 28.1% of cases.

• A pre-sedation general medical assessment was only done in 

83% of cases.

• Informed consent was only obtained in 75.6% of cases.

• No monitoring was used at all in 41.3% of cases.

• The dentist was the sole operator surgeon and sedationist in 

41.3% of cases.

• No emergency drugs were available in 43.2% of cases.

• No emergency or resuscitation equipment was available in 

19.76% of cases.

These terrifying results show extreme non-compliance with the 

South African Society of Anaesthesiologists (SASA) sedation 

guidelines. In the words of Dr De Wet of the Society of Sedation 

Practitioners of South Africa (SOSPOSA), “This is exactly how 

sedation should not be done”.5

Where do problems arise? In 2000, Charles Cote analysed the 

contributing factors to adverse critical incidents in paediatric 

sedation.6 He used data from 3 sources:

1. The Food and Drug Administration (FDA) voluntary reports 

between 1969 and 1996.

2. The United States Pharmacopoeia (USP) drug events reports 

from a similar period.

3. Voluntary survey results obtained from a group of over 1300 

USA practitioners.

Adverse critical events were divided according to where they 

occurred, i.e. hospital based vs non-hospital based settings. 

Under-reporting did likely influence their results. However, a 

total of 118 cases of adverse events involving sedation for any 

procedures in children were identified. In 95 of these cases 

the adverse event was purely due to the sedation. This is a 

low number but of these 95; 51 were deaths and 9 suffered 

permanent neurological damage, showing that when adverse 

events do occur they are catastrophic. 

While the incidence of respiratory depression was equal in the 

hospital vs the non-hospital group, all other events were more 

common in the non-hospital setting: 

South African Family Practice 2018; 60(4):S2-S6
 
Open Access article distributed under the terms of the 
Creative Commons License [CC BY-NC-ND 4.0] 
http://creativecommons.org/licenses/by-nc-nd/4.0

Anaesthesia for dentistry in children
Gardner BM 

Department of Anaesthesia, Chris Hani Baragwanath Academic Hospital, University of the Witwatersrand
*Corresponding author, email: Brian.Gardner@wits.ac.za



Anaesthesia for dentistry in children 3

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Non-hospital setting Hospital setting

Respiratory events ≈ 80% ≈ 80%

Cardiovascular events 
(as 2nd complication)

53.6% 14%

Cardiovascular events 
(as 3rd complication)

25% 7%

Inadequate resuscitation 57.1% 2.3%

Death or permanent 
neurological injury

92.8% 37.2%

Interestingly, the 35 patients who did not die or suffer from 
permanent neurological injury had all been monitored with pulse 
oximetry as opposed to the other cases, where no documented 
monitoring could be ascertained.

Of these 95 patients, 32 (33.7%) had received sedation for dental 
procedures, pointing to the fact that across the full array of 
patients receiving sedation, dental procedures carry the highest 
risk.

Cote et al. reached the following conclusions:

1. The non-hospital setting carries a higher risk and is associated 
with poorer resuscitation and rescue chances.

2. Poor monitoring and poor responses to abnormal monitor 
readings are associated with poorer outcomes.

3. Pre-sedation assessments were often inadequately done or 
omitted.

4. Poorer outcomes correlate more frequently with single 
operator sedationists and where an independent observer 
was not present.

5. Medication errors in paediatric dosing were common.

6. Inadequate recovery procedures were associated with poorer 
outcomes.

Charles Cote and colleagues also looked at the medications 
involved when these adverse events occurred.7 Looking at the 
60 patients who suffered death or permanent neurological injury 
they found the following relationships: 

Incidence of death or 
permanent neurological injury

Type of drug used. No difference

Route of drug administration. No difference.

Drug overdose. ⇑ (28/ 60 cases)

Drug combinations. ⇑ (Especially if ≥ 3 drugs used)

N2O added to other sedative 
agents.

⇑

Giving sedative to parent to 
administer at home or en route 
to the clinic.

⇑

Non-medical sedationist or single 
operator sedationist.

⇑

Discharging patients home too 
early before sedative(s) had worn 
off.

⇑

Chicka et al. did a review of the closed malpractice insurance 
claims for dental related anaesthesia and PSA events, during 
the period 1993–2007 of two liability carriers. They discovered  

17 claims.8 Of these, one patient had received a general 
anaesthetic and three received local anaesthesia alone. The 
remaining 13 had all received sedation. 53.6% of patients 
suffered death or permanent neurological damage. The average 
patient age was 3.6 years old. The dentist had been the sole 
operator sedationist and dentist in 6 of the 13 sedation cases. 
71% of the sedation mishaps occurred in dental rooms. In  
12 of the 13 sedation related incidents no monitoring had been 
used. Again, it was poor monitoring, single operator sedationist/
dentists and office-based sedation that stood out as risk factors.

Following all the media attention on deaths related to paediatric 
dental sedation or general anaesthesia, Lee et al. looked at 
media reports from 2 databases for the period 1980–2011.9 The 
databases used were the Lexis-Nexis Academic search engine 
and the Raven Maria Blanco foundation website. They specifically 
did not look at any outcome other than death (i.e. neurological 
damage or other adverse outcomes were excluded) and admit 
that under-reporting probably affected the accuracy of their 
numbers. A total of 44 deaths were found in these media reports. 
Forty-one of the patients were completely healthy prior to the 
event and all the deaths were believed to have been largely 
preventable. Three patients had pre-existing medical conditions 
which were not picked up during a pre-sedation assessment. 

Lee found that:

• 21/44 (47.7%) of the patients were in the 2 to 5-year age group.

• 21/44 (47.7%) of the cases occurred in dental rooms.

• In 25/44 (56.8%) of the cases the dentist had been a sole 
operator. In most of these cases moderate sedation had been 
targeted.

• Most patients initially suffered a respiratory arrest which was 
subsequently followed by a cardiac arrest.

• Sources of error were found to have been: 

 ▪ An inadequate or no pre-sedation assessment was done.

 ▪ Medication errors.

 ▪ Inadequate or no monitoring was used during sedation.

 ▪ Inadequate resuscitation equipment was available and poor 
staff training in resuscitation skills.

Looking at dentistry itself, Nathan Reuter and his colleagues 
from the Department of Oral Health practice at the University of 
Kentucky, USA published a systematic review of death related to 
dental treatment in general in 201610. They found dentistry itself 
to be very safe, with the mortality rate for pure, non-sedated 
dentistry to be less than 1 death per 10 million patients. However, 
as soon as PSA is added to the picture, this mortality rate jumps 
to around 1 death per 350 000 patients. In fact, Reuter et al found 
94% of all dentistry related deaths to be anaesthesia, sedation or 
medication error linked. They found the following associations:

• A strong association between death and when single service 
providers did the sedation as well as the dentistry. 

• If a sedationist was present, then a strong link between the 
levels of training which the sedationist possessed and the type 
of outcome.



S Afr Fam Pract 2018;60(4):S2-S64

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• A strong association between death and deeper levels of 
sedation being used.

• Inadequate monitoring was a causal risk factor in most deaths.

• Poor emergency procedure implementation was common in 
the lethal cases.

• Children under 5 years were most at risk (most were normal, 
healthy children pre-procedure).

• Causes of respiratory related deaths were predominantly from 
airway obstruction due to:

 ▪ Foreign body aspiration.

 ▪ Angioedema.

 ▪ Hypersensitivity reactions.

 ▪ Spasm and asphyxia.

Looking at sedation in particular, Bellolio et al. did a systematic 
review and meta-analysis of 13 883 PSA sedations done 
for children requiring minor procedures in the emergency 
department in 2016.11 These were all specifically non-dental 
cases. In contrast to studies which involve dental procedures, 
where death or permanent neurological damage are common, 
this meta-analysis revealed no deaths at all. In fact, respiratory 
complications were found to be very rare. These included  
34 cases of laryngospasm, of which only one required intubation. 
This re-emphasizes the particular risk which PSA for dental 
procedures does carry.

The combination of PSA and dental procedures is particularly 
fraught. The greatest challenge is the shared airway. Minimal to 
moderate sedation is generally planned for, but there is always 
the risk of accidental over-sedation. The level of stimulation 
will fluctuate, making it difficult to maintain the sedation level 
constant without inadvertently slipping too far into the next 
level of sedation. Applying topical anaesthesia prior to inserting 
intravenous lines and dental local anaesthesia injections will 
help to avoid requiring a deeper sedation plane during these 
interventions. The use of N2O alone may be sufficient when 
there is no stimulation, but generally fails as soon as any painful 
or deep stimulation is given. The dentist must understand 
that having the patient in the correct plane of sedation means 
that the patient should still move. This will probably happen 
unexpectedly, either spontaneously but especially to painful 
stimuli. Aspiration of foreign bodies, blood or irrigation water 
is also a real danger and apart from Mendelsohn’s syndrome, 
this may provoke laryngospasm and bronchospasm. The dentist 
must use the minimum amount of water to cool their drill and 
suction pedantically. Even with minimal to moderate PSA, most 
young children are still not able to tolerate sitting in the dental 
chair for very long. Often, only short, limited procedures are 
possible for these patients under PSA.

SASA has published updated guidelines for paediatric PSA 
in 2016.12 These guidelines cover the full ambit of PSA for all 
procedures in children, not only those presenting for dental 
procedures. SOSPOSA fully endorses these guidelines and is 
lobbying for the implementation of training and accreditation 
for sedationists in South Africa.

Sedation end-points are described as follows12:

1. Minimal sedation (Anxiolysis)

Cognitive function is impaired but the patient responds 
normally to verbal commands. Ventilatory and cardiovascular 
function is unaffected.

2. Moderate sedation 

The patient has a depressed level of consciousness but still 
responds purposefully to verbal commands or light touch. The 
patient maintains their own airway and breathing.

3. Deep Sedation 
This forms part of the spectrum of general anaesthesia and 
may only be practised by practitioners with anaesthesia 
training. 
Deep sedation is also known as “monitored anaesthesia care”.
The patient has a depressed level of consciousness but 
responds purposefully to repeated or painful stimuli (i.e. not 
merely a reflex withdrawal to pain).
The patient may not be able to maintain their own airway or 
breathing, which may require intervention by the sedationist.

4. General anaesthesia

The patient has a depressed level of consciousness from which 
they cannot be roused, even with painful stimuli.
The patient may not be able to maintain their own airway or 
breathing.

While minimal to moderate sedation is generally aimed for 
during PSA, it is important that the sedationist is always capable 
of rescuing a patient who inadvertently progresses to a deeper 
level of sedation.

In the SASA sedation guidelines a further distinction is made 
between simple or standard sedation and advanced sedation. 
SASA endorses single operator sedationist/dentists for the use of 
simple or standard sedation but requires a separate sedationist 
as soon as the use of advanced sedation is planned. Even 
with single-operator sedation, however, a separate observer 
must be present to monitor the patient. Simple sedation does 
also require that all safety equipment, monitoring and rescue 
protocols are in place. Non-fasted patients may be offered simple 
or standard sedation. Patients presenting for advanced sedation 
must all be fasted according to standard anaesthesia fasting 
guidelines. Fasting guidelines are currently a topic of debate in 
the literature.13 For now, however, the SASA guidelines remain  
6 hours for solids and formula feeds, 4 hours for breast milk and 
2 hours for clear fluids.

Simple or standard sedation

A single agent is used. 

• This may be administered by an oral or transmucosal route. 

• A single titrated intravenous dose of midazolam alone is 
permitted if Midazolam is used.

• Inhaled N2O in 50% oxygen only if N2O  is used.

Advanced sedation

Comprises one or more of:



Anaesthesia for dentistry in children 5

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• Any drug combination using more than one agent.

• An intravenous bolus injection or continued transfusions.

• Inhaled N2O in < 50% oxygen or any other inhaled agents used 
in oxygen instead of N2O.

The SASA guidelines emphasize the importance of careful 
patient selection prior to performing PSA12:

1. Only ASA I and II patients should be offered PSA. It is important 
to remember that an ASA II patient may deteriorate acutely 
and be ASA III on the day of the procedure, so a thorough pre-
sedation assessment is warranted.

2. All patients < 5 years of age must be sedated by practitioners 
trained specifically in PSA for young children.

3. All PSA practitioners must have completed life support 
training.

4. Children suffering from an acute upper respiratory tract 
infection should be postponed until after this has resolved.

5. Children < 1 year of age and all ASA III or higher patients should 
be referred to a specialist anaesthetist or highly experienced 
and trained paediatric sedationist. These patients should 
probably undergo their procedure in a hospital setting and 
not undergo an office-based procedure.

The importance of a thorough pre-sedation assessment 
cannot be overemphasised. Apart from identifying underlying 
medical conditions, a thorough focussed airway assessment 
must be done and the ability to communicate with the patient 
ascertained. It is important to ensure that the child will be able 
to cooperate and tolerate minimal to moderate sedation for the 
procedure.

Documentation collected must include: 

• Informed consent;

• The pre-sedation assessment;

• The sedation chart outlining drugs administered and observed 
vital signs;

• Post-procedure observations;

• Home instructions.

Examples of all these documents are included in the SASA 
guidelines document.12 All the conditions required for safe day 
case procedures must also be adhered to.

Short-acting sedative agents are generally recommended and 
where applicable, antidotes must be available in the emergency 
drug armamentarium. Supplemental analgesia should not be 
forgotten. Most paediatric dentistry can be adequately managed 
with paracetamol and non-steroidal anti-inflammatory agents. 
Opioids are seldom required. The SASA guideline document 
includes a full description of suitable agents for PSA.12

Before office-based PSA is commenced, a clear plan for emergency 
management and transfer to a hospital setting must be in place. 
Emergency equipment and drugs required for rescuing a patient 
who proceeds to a deeper level of sedation, or who suffers an 
unanticipated complication, must be immediately available.  
A full list of these is available in the SASA guidelines document.12

The SASA guidelines for monitoring of minimal and moderate 
sedation include the following parameters:

1. Level of consciousness (University of Michigan Sedation Scale);

2. Breathing, ventilation and airway patency;

3. Heart rate and rhythm;

4. Blood pressure;

5. Oxygen saturation.

In patients with an underlying cardiovascular disease undergoing 
moderate sedation, the additional use of an electrocardiogram 
(ECG) is advised. 

Capnography is not mandatory for moderate sedation but 
is recommended for deep sedation according to the SASA 
guidelines. There is always the risk of moderate sedation 
inadvertently progressing to deep sedation however, which is 
why recent lobbyists are advocating the use of capnography in 
all sedation cases. It is important to remember that the pulse 
oximeter is a lag monitor. Lightdale et al. of Children’s Hospital in 
Boston, Massachusetts, did a randomised, controlled trial of the 
use of microstream capnography during moderate sedation in 
2005, challenging the guideline to monitor with pulse oximetry 
alone.14 They looked at the incidence of hypopnoea and apnoea 
diagnosed by observing chest movement and pulse oximetry 
vs capnography and their results were as follows for patients 
sedated with identical sedation protocols:

Hypopnoea 
detection rate

Apnoea detection 
rate

Chest wall 
observation and 
pulse oximetry only.

3% detected 0% detected

Capnography added. 56% detected 24% detected

Clearly we are simply not seeing the apnoea or hypopnoea 
episodes with our current observation methods if capnography 
is not used.

The addition of supplemental oxygen in particular may mask the 
desaturation required to register apnoea in a patient monitored 
by pulse oximetry alone.

While today paediatric dental PSA remains controversial, unlike 
in the 1970s and 1980s, the use of general anaesthesia for dental 
work in children is much more standardised, routine and safe.2 
The main concerns are12:

• Shared airway;

• Use of a throat pack;

• Emergence delirium;

• Outpatient setting considerations.

In conclusion, local anaesthesia used alone where possible 
remains the first choice for managing paediatric dental work. 
The use of general anaesthesia is safe, but costly and not always 
widely available. As an alternative, paediatric PSA for dental 
procedures is already being widely done, unfortunately, as 
can be seen from the Bham et al. study, often to poor safety 
standards in our country. Paediatric dental PSA is potentially 



S Afr Fam Pract 2018;60(4):S2-S66

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extremely dangerous but the pitfalls and practice guidelines are 
quite clear. Education, accreditation and implementation of the 
SOSPOSA and SASA guidelines will hopefully go a long way to 
enhance safety for a practice which will likely remain popular, 
given the resource constraints we face. 

References:
1. Cantlay K, Williamson S, Hawkings J. Anaesthesia for dentistry. Continuing 

Education in Anaesthesia, Crit Care Pain. 2005;5(3):71-5.

2. Mortazavi H, Baharvand M, Safi Y. Death Rate of Dental Anaesthesia. J Clin Diagn 
Res. 2017;11(6):7-9.

3. Camm JH, Mourino AP, Cobb EJ, et al. Behavioural changes of children 
undergoing dental treatment using sedation versus general anaesthesia. Pediatr 
Dent. 1987;9(2):111-7.

4. Bham F, Perrie H, Scribante J, et al. Paediatric dental chair sedation: An audit of 
current practice in Gauteng, South Africa. SAMJ. 2015;105(6):461-4.

5. De Wet. SASA refresher course lecture March 2017.

6. Cote CJ, Notterman DA, Karl HW, et al. Adverse Sedation Events in Pediatrics: A 
Critical Incident Analysis of Contributing Factors. Pediatrics. 2000;105(4):805-14.

7. Cote CJ, Karl HW, Notterman D, et al. Adverse Sedation Events in Pediatrics: 
Analysis of Medications Used for Sedation. Pediatrics. 2000;106(4):633-44.

8. Chicka MC, Dembo JB, Mathu-Muju KR, et al. Adverse events during pediatric 
dental anesthesia and sedation: a review of closed malpractice insurance claims. 
Pediatr Dent. 2012;34(3):231-8.

9. Lee HH, Milgrom P, Starks H, et al. Trends in death associated with pediatric 
dental sedation and general anesthesia. Paediatr Anaesth. 2013;23(8):741-6.

10. Reuter NG, Westgate PM, Ingram M, et al. Death related to dental treatment: a 
systematic review. Oral Med. 2017;123(2):194-204.

11. Bellolio MF, Puls HA, Anderson JL, et al. Incidence of adverse events in paediatric 
procedural sedation in the emergency department: a systematic review and 
meta-analysis. BMJ Open. 2016 [accessed 12/04/2017];6:e011384:1-16. Available 
from: http://bmjopen.bmj.com/. 

12. South African Society of Anaesthesiologists. Paediatric Sedation Guidelines for 
Procedural Sedation and Analgesia. SAJAA. 2016;22(1) Suppl 5:S1-33.

13. Green SM, Mason KP, Krauss BS. Pulmonary aspiration during procedural 
sedation: a comprehensive systematic review. BJA. 2017;118(3):344-54.

14. Lightdale JR, Goldmann DA, Feldman HA, et al. Microstream Capnography 
Improves Patient Monitoring During Moderate Sedation: A Randomized, 
Controlled Trial. Pediatrics. 2006;117(6):e1170-e1178.

15. Adewale L. Anaesthesia for paediatric dentistry. Continuing Education in 
Anaesthesia. Crit Care Pain. 2012;12(6):288-94.