Recent Advances In Local Anesthesia PDF

Summary

This chapter details recent advances in local anesthesia, focusing on complications and risks relating to the use of articaine, including cases of lingual nerve involvement as a result of its usage. It examines associated risk factors and potential mechanisms through in-depth analysis and references.

Full Transcript

CHAPTER 20

45

Recent Advances in Local Anesthesia

377

1,800,000

40

1,600,000

Hillerup paper

35

1,400,000

30

1,200,000

25

1,000,000

20

800,000
EU report

15

600,000

10

09

Use

20

20

07

08
20

20

20

20

20

20

20

20

06

-

05

0

04

200,000

03

5

02

400,000

01

10

Adverse
reactions

The number of suspected adverse reactions reported to the Danish Medicines
Agency for articaine. The chart shows which year a reported adverse reaction
began. It also shows the use of articaine in dental practices in mL.

• Fig. 20.9

Articaine use and reports of paresthesia (Denmark).

TABLE Lingual Nerve Involvement in Reported
20.9
Cases of Paresthesia

Authors

Country

Year

Lingual Nerve
Involvement (%)

Haas and
Lennon43

Canada

1995

70.6

Hillerup and
Jensen44

Denmark

2006

77.0

Garisto et al.45

United
States

2010

92.7

Kingon et al.46

Australia

2011

80.0

to 1946 involve the maxilla).70 Considering the mandible,
paresthesia has rarely been reported following alternative
nerve blocks, such as the Gow-Gates mandibular nerve
block.70 Articaine has been used increasingly in medicine,
primarily dermatology, plastic and reconstructive surgery,
ophthalmology, and orthopedic surgery. There are no
reported cases of paresthesia following the nondental use
of articaine.21-22,71
Is it possible for a drug be so specifically neurotoxic that
it only damages nerves in the oral cavity, specifically in the
mandible and more specifically the lingual nerve? Possible,
yes, but highly improbable.␣

The Lingual Nerve
following dental treatment.68,69 Informed consent, specifically with discussion of the risk of paresthesia, is required
before these procedures.
Given that most dental treatment is nonsurgical (e.g.,
restorative, periodontal), the primary risk of paresthesia
would involve local anesthetic administration.
In a MEDLINE search for reported cases of paresthesia in dentistry dating to 1946, more than 95% of all cases
occurred in the mandible.70 The overwhelming proportion
involve the lingual nerve. Table 20.9 shows lingual nerve
involvement in four published articles.
We have been told that 4% articaine appears to be
more neurotoxic than other local anesthetics, and that its
administration by IANB should be avoided.43-48,53 The
following needs to be considered: if 4% articaine is more
neurotoxic than other local anesthetics, then how do we
explain that paresthesia is rarely reported in the maxilla
when half of all dental treatment involves maxillary teeth
(less than 5% of all cases in the dental literature dating

The lingual nerve appears to be involved in reports of dentally
related paresthesia in a disproportionate percentage of cases
(see Table 20.9). Pogrel has studied paresthesia, with publications dating from the early 1990s.51,52 In a 2000 article
(before the introduction of articaine in the United States),
Pogrel and Thamby51 estimated the risk of permanent nerve
damage following IANB at 1 in 26,762 injections. They
stated that “it is reasonable to suggest that during a career,
each dentist may encounter at least one patient with an
inferior alveolar nerve block resulting in permanent nerve
involvement. The mechanisms are unknown and there is no
known prevention or treatment.”51 In the course of a 20- to
30-year dental career, it is estimated that more than 30,000
IANBs will be administered.52
Why is it that the lingual nerve is primarily involved in
cases of paresthesia? Considering that when one is administering the IANB the vast majority of local anesthetic volume is deposited close to the inferior alveolar nerve (e.g.,
1.3 to 1.5 mL), not the lingual nerve (e.g., 0.2 to 0.3 mL), if

378 PART IV

Complications, Legal Considerations, Questions, and the Future

TABLE Risk of Paresthesia From Local Anesthetic
20.10 Drugs55,56

2007

2012 Result

Lidocaine

0.64

0.5

<1.0, less than expected

Articaine

1.19

0.97

∼1.0, expected

Mepivacaine

NA

2.2

>1.5, higher than expected

Prilocaine

4.96

3.25

>3.0, higher than expected

The ratio derived from the percentage of reported cases of paresthesia
divided the percent market share of the drug.

• Fig. 20.10

Fascicles within a nerve. (From McGill Physiology Virtual
Laboratory. http://www.medicine.mcgill.ca/physio/vlab/.)

paresthesia were a local anesthetic neurotoxic phenomenon,
we would expect the inferior alveolar nerve to be affected
much more often than the lingual nerve.
The fact that the lingual nerve is stretched when the
patient opens the mouth for an IANB probably prevents the
lingual nerve from “getting out of the way” of the needle.
The resulting injury is more likely than not to be a result of
mechanical trauma to the lingual nerve from the metal needle. Stated in another way: “the lingual nerve is in the way.”
In 2003 Pogrel et al.72 attempted to explain why lingual
nerve damage was commonly seen as more profound. At the
level at which the IANB is administered, the inferior alveolar nerve had five to seven fascicles, whereas the lingual nerve
in that area usually had around three, but in one-third of the
cases was actually unifascicular in the area where the IANB was
given (Fig. 20.10). If a nerve with many fascicles (e.g., inferior
alveolar nerve) is damaged, only a small portion of the sensory
distribution would be affected. When a nerve with one to three
fascicles (e.g., lingual nerve) is damaged, the resulting area of
sensory involvement will be considerably larger.
It is this author’s opinion that if paresthesia involves the
distribution of the lingual nerve—and especially when an
“electric shock” (e.g., “zap”) is experienced during injection,
the likely cause is mechanical trauma secondary to contact of
the metal needle with the nerve. If paresthesia involves the distribution of the inferior alveolar nerve (e.g., chin, lip, mucous
membrane), then possible causes include (1) neurotoxicity of
the local anesthetic, (2) mechanical contact of the needle to the
inferior alveolar nerve, (3) edema, and (4) hemorrhage.␣

Local Anesthetics Are Neurotoxins
All local anesthetics are neurotoxic.54 If all local anesthetics were
equally neurotoxic, then the percentage of reported cases of
paresthesia for that drug should approximate its market share.
The resulting fraction ideally should be 1.0 (Table 20.10).

In 2007 Pogrel55 reported on 52 patients with paresthesia. Lidocaine produced the greatest number (20) and
percentage (35%) of cases of paresthesia. However, with a
market share of 54% at that time, the ratio was 0.64, lower
than expected (Table 20.10). Prilocaine, on the other
hand, with a 6% market share was involved in 29.8% (17)
of the cases of paresthesia (ratio of 4.96). Articaine, with a
market share of 25%, was also involved in 29.8% (17) of
the cases, for a ratio of 1.19. Pogrel concluded55: “Therefore, using our previous assumption that approximately
half of all local anesthetic used is for inferior alveolar nerve
blocks, then on the figures we have generated from our
clinic we do not see a disproportionate nerve involvement
from articaine.”
In a 2012 update reporting on a subsequent 38 patients
with paresthesia evaluated in his clinic between 2006 and
2011, Pogrel56 stated that “articaine is still causing permanent inferior alveolar and lingual nerve damage (36%)
which is proportionate to its market share (37%) .... The
number of cases caused by lidocaine, on the other hand,
appears to be only around 50% of its market share. Prilocaine however by causing 26% of all cases seen since 2005
with a market share of only 8% is somewhat disproportionate to its market share” (see Table 20.10).␣

Is Articaine a More Effective Local Anesthetic
and Does It Have a Greater Risk of
Paresthesia?
Meta-analyses comparing articaine with lidocaine have concluded “that articaine as compared with lignocaine provides
a higher rate of anaesthetic success, with comparable safety
to lignocaine when used as infiltration or blocks for routine
dental treatments” and “this meta-analysis thus supports
a recommendation for 4% articaine (1:100,000 epinephrine) in routine dental practice over and above 2% lidocaine
(1:100,000 epinephrine).”73,74
A 2012 article reporting on a histologic analysis of the
neurotoxicity of lidocaine, articaine, and epinephrine on
the mental nerve in rats, concluded that “articaine is not
toxic to the nervous structure and (that) further studies are
necessary to explain the possible relation between articaine
injection and paresthesia.”75

CHAPTER 20

In a 2013 laboratory study, human neuroblastoma cells
were exposed to various concentrations of articaine, lidocaine, and prilocaine to determine neurotoxicity at six different drug concentrations.76 The results of this in vitro
study revealed that 2% lidocaine had a lower neurotoxicity profile than 4% prilocaine and that 4% articaine had
a lower neurotoxicity profile than 2% lidocaine. In vitro
studies are accurate, sensitive, and reproducible because
they are conducted in a controlled environment. However,
in vitro studies do not consider other factors, such as (1)
local pharmacokinetics (concentration in tissues, local diffusion, absorption), (2) potential influence of other drugs
on local pharmacokinetics (e.g., epinephrine), (3) systemic
behavior of the drug after absorption (distribution, elimination, metabolism), and (4) all other variables, such as differences between patients.
In 2018 Albalawi et al.77 tested the neurotoxicity of lidocaine and articaine in SH-SY5Y cells. They reported that
“articaine did not produce a prolonged block of neuronal
responsiveness or an increased toxicity as compared with
lidocaine in SH-SY5Y cells. The corollary that articaine
does not produce a prolonged loss of responsiveness or cell
death as compared with lidocaine under these reductionist
conditions is perhaps the most relevant conclusion.”␣

So, What Should You Do?
Doctors must always consider the benefit to be gained from
use of a procedure or drug versus the risk involved in the
use of the procedure or drug. Only when, in the opinion of
the treating doctor, the benefit to be gained by the patient
clearly outweighs the risk should the procedure be undertaken or the drug administered.
All reports claiming an increased risk of paresthesia with
articaine are anecdotal, consisting of case reports. No scientific evidence has demonstrated an increased risk of paresthesia following the administration of articaine compared
with other local anesthetics.
In a discussion of current controversies in dentistry,
Christenson78 stated: “There have been allegations of more
patients having lingering paresthesia and anesthesia when
articaine is used for mandibular block than lidocaine. Studies have not shown this to be true. Also, the observations
of practitioners show about the same quantities of paresthesia with articaine versus lidocaine. The controversy is
unfounded.”
The choices for IANB include (1) continuing with
the use of 4% articaine with epinephrine 1:100,000 or
1:200,000 or (2) if you are unconvinced or still concerned,
use of either 2% lidocaine with epinephrine 1:100,000
or 2% mepivacaine with levonordefrin 1:20,000 (United
States) or epinephrine 1:100,000 (Canada) for IANB, followed immediately by a buccal infiltration of 0.6 to 0.9 mL
of articaine (preferably buffered) at the apex of each tooth
to be treated.
The administration of 4% prilocaine with epinephrine
appears to be associated with a considerably greater risk of

TABLE
20.11

Recent Advances in Local Anesthesia

379

Comparison of Plain Local Anesthetic Versus
Vasoconstrictor-Containing Local Anesthetic
Plain Local
Anesthetic

Local
Anesthetic +
Vasoconstrictor

Onset of pulpal
anesthesia

Somewhat faster

Slower

Duration of pulpal
anesthesia

Shorter

Longer

Depth of pulpal
anesthesia

Not as profound

More profound

Peak blood level

Higher

Lower

paresthesia to the lingual and/or inferior alveolar nerves
when administered by IANB. Its use for IANB is not recommended by this author.␣

Conclusions
Articaine hydrochloride has become a very popular local
anesthetic in dentistry. It provides the same depth and
duration of pulpal and soft tissue anesthesia as the other
intermediate-acting dental local anesthetics—lidocaine,
mepivacaine, and prilocaine. Because the elimination halflife of articaine is considerably shorter than that of other
amide local anesthetics, it is the preferred drug in special
patient populations, including children, pregnant women,
and nursing mothers. Because of the greater lipid solubility
of articaine, the buccal infiltration of articaine in the adult
mandible has a clinically significant rate of success in providing pulpal anesthesia compared with other amide local
anesthetics. Several meta-analyses have concluded that articaine is a preferred dental local anesthetic. Regarding paresthesia, there is no scientific basis for stating that articaine
is more neurotoxic than other commonly used dental local
anesthetics.␣

Phentolamine Mesylate: The Local
Anesthesia “Off” Switch
All currently used injectable local anesthetics are vasodilators. Three local anesthetics formulations without a
vasoconstrictor are available for use in dental cartridges
worldwide: 2% lidocaine HCl (not available in dental
cartridges in North America); 3% mepivacaine HCl; and
4% prilocaine HCl. These drugs provide—compared
with their formulations containing a vasoconstrictor—a
short duration of not as profound anesthesia (see Table
4.17). Additionally, vasodilators increase blood flow in
the area in which the drug was deposited as arterioles and
capillaries dilate, leading to (1) a more “bloody” surgical
field and (2) higher blood levels of the local anesthetic
(see Table 20.11).

380 PART IV

Complications, Legal Considerations, Questions, and the Future

A vasoconstrictor (e.g., epinephrine) is added to the local
anesthetic to (1) increase the depth and duration of pulpal
and soft tissue anesthesia, (2) provide a “cleaner” surgical
field, and (3) decrease the blood level of the local anesthetic
drug, thereby increasing its safety (decreasing the risk of
overdose caused by overadministration of the local anesthetic) (see Table 20.11).
For dental procedures on teeth (e.g., restorations, endodontic procedures, extractions, implants) pulpal anesthesia
is necessary until such time as the procedure is completed.
Soft tissue anesthesia, although necessary for some procedures (e.g., scaling and root planing, periodontal surgery,
exodontia) is always of considerably longer duration than
pulpal anesthesia.
When one is preparing teeth for placement of restorations—the most common procedure in dentistry79—pulpal
anesthesia is a necessity for the duration of the preparation
(e.g., cutting) of the tooth. Once this is complete, there is no
longer a need for continued anesthesia of the tissues, either
hard or soft. However, the need for effective intraoperative
pain control normally mandates the use of a local anesthetic
containing a vasoconstrictor such as epinephrine or levonordefrin, which has become a routine part of dentistry.80,81
Patients are commonly discharged from the dental office with
residual numbness of their lips and tongue, typically persisting for an additional 3 to 5 hours.82
Residual soft tissue anesthesia is a possible inconvenience
or embarrassment to the patient, who is unable to function
normally for many hours after leaving the dental appointment. In a survey of patients receiving intraoral local anesthetic, Rafique et al.83 reported that there were several
aspects of the post–local anesthetic experience that were
disliked by patients, including three major areas: functional,
sensory, and perceptual.
Functionally, patients disliked their diminished ability to
speak (lisping), to smile (asymmetric), and to drink (liquid
runs from the mouth), and the inability to control drooling while still numb. Sensorially, the lack of sensation was
described as quite discomfiting, while the perception that their
body was distorted (e.g., swollen lips) was equally unpleasant. For many patients these sequelae become a significant
detriment to their quality of life, making it difficult for them
to return to their usual activities for hours after treatment.
When the dental appointment concludes at a time approaching the time for a meal, either lunch or dinner, patients must
consider whether to eat while numb or postpone their dining
until the residual soft tissue anesthesia resolves.
Although not normally a significant problem, residual
soft tissue anesthesia may occasionally lead to self-inflicted
soft tissue injury in any patient. Self-inflicted soft tissue
injury—most commonly of the lip or tongue—is more
likely to be noted in younger children and in mentally disabled adult and pediatric patients.84
A study of pediatric patients by College et al.85 revealed
that a significant percentage of IANBs were associated with
inadvertent biting of the lips. By age group, the frequency
of trauma to the lips was 18% for younger than 4 years,
16% for 4 to 7 years, 13% for 8 to 11 years, and 7% for

TABLE Incidence of Self-Inflicted Soft Tissue Injury
20.12 in Pediatric Populations85

Age (Years)

Percentage With Self-Inflicted Soft
Tissue Injury

<4

18

4–7

16

8–11

13

≥12

7

OH

N
N

CH3SO3H
N
H

H3C

• Fig. 20.11

Phentolamine mesylate.

12 years or older (Table 20.12). This can be explained by
the fact that the younger patient will test (by biting) their
unnumb lip—which hurts—and then test the still-numb
side—which does not hurt. Where the adult would normally not proceed beyond this point, the younger child may
“play” with this “feeling” and continue to bite ever harder,
not realizing the damage being inflicted. Mentally handicapped adults are just as likely to incur self-inflicted soft tissue injury. This author was surprised to learn from dentists
who treat geriatric patients that another group—the geriatric patient with dementia—presents a risk of soft tissue
injury following local anesthetic injection equal to or greater
than that of children and mentally challenged adults.
So, can the numbness produced by local anesthetics be
made to resolve more quickly?
The injection of a vasodilating drug into the area of prior
local anesthetic administration should accomplish this goal
by hastening the redistribution of local anesthetic from the
nerve into the cardiovascular system, thereby decreasing the
duration of residual soft tissue anesthesia.

Phentolamine Mesylate
Phentolamine mesylate is an α-adrenergic receptor antagonist
approved by the FDA in 1952 (Fig. 20.11). Approved uses of
phentolamine include diagnosis of pheochromocytoma and
treatment of hypertension in pheochromocytoma,86,87 prevention of tissue necrosis after norepinephrine extravasation,
88,89 and reversal of soft tissue anesthesia.86 Phentolamine
has also been used to treat hypertensive crisis associated with
monoamine oxidase inhibitor therapy86,89 and in combination with papaverine to treat erectile dysfunction.86,90, 91
Phentolamine is a short-acting, competitive antagonist
at peripheral α-adrenergic receptors. It antagonizes both
α1 and α2 receptors, thus blocking the actions of the circulating catecholamines epinephrine and norepinephrine.

CHAPTER 20

Phentolamine also stimulates β-adrenergic receptors in the
heart and lungs.
The clinical effects of phentolamine include peripheral
vasodilation and tachycardia. Vasodilation is a result of both
direct relaxation of vascular smooth muscle and α blockade. The drug produces positive inotropic and chronotropic
effects, leading to an increase in cardiac output. In smaller
doses the positive inotropic effect can predominate and raise
blood pressure; in larger doses, peripheral vasodilation can
mask the inotropic effect and lower blood pressure. These
actions make phentolamine useful in treating hypertension
caused by increased circulating levels of epinephrine and
norepinephrine, as occurs in pheochromocytoma.86
For prevention or treatment of dermal necrosis or sloughing following extravasation of catecholamines (e.g., epinephrine, norepinephrine), 5 to 10 mg of phentolamine
(diluted with 10 to 15 mL of normal saline) is injected into
the affected area within 12 hours of extravasation. Visible
hyperemia and increased tissue warmth at the site are signs
of effective treatment.86,92
For the treatment of hypertensive emergency related to any
catecholamine excess, such as interactions between monoamine oxidase inhibitors and sympathomimetic amines,
phentolamine is administered intravenously as a bolus in a
dose of 5 to 15 mg.86,93

Pregnancy and Lactation
As presently used in medicine, phentolamine is categorized by the FDA as a pregnancy category C drug and as
“safety unknown” for nursing mothers.39,40 (Pregnancy category C—animal studies show adverse fetal effect(s) but no
controlled human studies or no animal or human studies;
weigh possible fetal risk versus maternal benefit. Lactation
category “safety unknown”—inadequate literature available
to assess risk; caution advised.)
Phentolamine is available as a 5 mg/mL solution for parenteral administration.␣

Clinical Trials: Adults and Adolescents
In May 2008 the FDA approved phentolamine mesylate
(OraVerse) for dental use to reverse anesthesia following
dental injections. Marketed in 1.7-mL dental cartridges,
the formulation contains 0.4 mg of phentolamine mesylate
(0.235 mg/mL).94 The dental formulation of phentolamine
is approximately 1/20 the concentration of that used in
medicine. In phase 3 randomized, controlled, double-blind
clinical trials, patients received a vasoconstrictor-containing
local anesthetic on one side of their mouths before a restorative or periodontal maintenance procedure. The primary
end point was the elapsed time to the return of normal
lip sensation as measured by patient-reported responses to
lip palpation. Secondary end points included the patients’
perception of altered function, sensation, and appearance,
and functional deficits in smiling, speaking, drinking, and
drooling, as assessed by both the patient and an observer
blinded to the treatment.95-98
Patients were randomized to receive one of four local
anesthetics: 2% lidocaine with epinephrine 1:100,000; 2%

Recent Advances in Local Anesthesia

381

mepivacaine with levonordefrin 1:20,000; 4% articaine
with epinephrine 1:100,000; or 4% prilocaine with epinephrine 1:200,000.
At the conclusion of the procedure, the patient received
either phentolamine mesylate or a control injection. Both
patients and all investigators were blinded to the treatment
assigned. The study drug was administered at the same site,
and in the case of phentolamine mesylate, the same number
of cartridges (one or two) as for the previous local anesthetic
injection(s). The control was a sham injection in which the
plastic needle cap attached to the dental syringe containing
an empty cartridge was pushed against, but did not penetrate, the intraoral soft tissue at the site of the previous local
anesthetic injection. After receiving phentolamine mesylate
or the sham injection, all patients were observed for 5 hours
to collect efficacy and safety data, and were then monitored
for up to 48 hours.
The 5-hour observation and testing period was a primary
determinant in the lower age limit (4 years) for patients.
It was felt (correctly, it turned out) that younger patients
would be unable to cooperate fully with the assessments
required over the 5-hour period of observation.
All patients were trained in assessing the numbness of
their lips. Those in the mandibular protocol group were also
trained to tap their tongues. The procedure involved a light
tapping of these soft tissues with their index or middle finger. Assessments were made every 5 minutes.
The functional assessment battery included measurements of smiling, speaking, and drooling, and drinking 3
ounces of water at various time points during the study.97,98
Each functional assessment was rated as normal or abnormal by a research assistant and the patient.␣

Efficacy of Phentolamine Mesylate: Adolescents
and Adults
In the maxillary trial, the median time to recovery of normal
sensation in the upper lip was 50 minutes for phentolamine
mesylate patients and 132.5 minutes for control patients, a
reduction in upper lip anesthesia of 82.5 minutes (P < .0001).95
In the mandibular trial, the median time to recovery of
normal sensation in the lower lip was 70 minutes for phentolamine mesylate patients and 155 minutes for control
patients, a reduction in lower lip anesthesia of 85 minutes
(P < .0001).95
Within 30 minutes of phentolamine mesylate administration, 26.7% of maxillary patients reported return of
normal lip sensation as compared with 1.7% in the control
group. At 1 hour, 59.2% had normal upper lip sensation
versus 11.7% for sham patients. At 90 minutes the proportions were 75% and 25%, respectively. Upper lip anesthesia persisting beyond 2 hours occurred in 54.2% of sham
patients versus 11.6% of phentolamine mesylate patients.95
In the mandible, within 30 minutes of phentolamine
mesylate administration, 17.2% of patients reported normal lower lip sensation as compared with 0.8% in the
control group. At 1 hour, 41% had normal lower lip sensation versus 7.4% for sham patients. At 90 minutes the
proportions were 70.5% and 13.1%, respectively. Lower

382 PART IV

Complications, Legal Considerations, Questions, and the Future

lip anesthesia persisting beyond 2 hours occurred in 70.5%
of sham patients versus 18.9% of phentolamine mesylate
patients.95
The median time to return of normal sensation to the
tongue was 60 minutes for phentolamine mesylate patients
and 125 minutes for sham patients, a statistically significant
(P < .0001) difference of 65 minutes.95␣

TABLE
20.13 Indications for Local Anesthesia Reversal
Conservative dental treatment
Nonsurgical periodontal treatment (e.g., scaling and root
planing)
Pediatric dentistry

Safety of Phentolamine Mesylate: Adolescents
and Adults

Medically compromised patients (e.g., type 1 diabetic
patients)

The overall frequency and the nature of adverse events
reported in both the maxillary study and the mandibular
study appeared similar in nature and frequency. None of the
adverse events in either study was serious or rated severe,
and no patient discontinued participation in the study
because of an adverse event.94,95␣

Geriatric patients

Safety and Efficacy of Phentolamine Mesylate:
Children
In a phase 2, double-blinded, randomized, multicenter
(N = 11), controlled study, pediatric patients between the
ages of 4 and 11 years received 2% lidocaine with epinephrine 1:100,000 and either phentolamine mesylate or sham
injection. One hundred fifty-two patients were enrolled
and completed the study. There were 96 in the phentolamine mesylate group and 56 in the sham injection group.
The median time to normal lip sensation was evaluated in
patients aged 6 to 11 years who were trainable for lip palpation procedures (see earlier). The reduction in the median
time to normal lip sensation for phentolamine mesylate
patients (N = 60) was 60 minutes compared with 135 minutes in the control group (N = 43), representing a reduction of residual soft tissue anesthesia of 75 minutes (55.6%)
for both maxillary and mandibular arches. Within 1 hour
following administration of phentolamine mesylate, 61%
of patients reported normal lip sensation, while only 21%
of patients in the sham injection group reported normal lip
sensation (P < .0001).96␣

Clinical Indications for Reversal of Local
Anesthesia
Reversal of local anesthesia should be a treatment option
whenever prolonged soft tissue anesthesia presents a potential risk (soft tissue injury) or will negatively impact the
patient’s lifestyle (e.g., inability to speak or eat) (Table
20.13). Froum et al.99 administered phentolamine mesylate
following insertion of mandibular implants in an attempt
to minimize the risk of postimplant paresthesia along the
distribution of the inferior alveolar nerve.
A situation that does not usually represent an indication for soft tissue anesthesia reversal includes postsurgical
patients, where prolonged soft tissue anesthesia is desirable
as a means of preventing breakthrough pain (see the discussion of postsurgical pain management in Chapter 16).
Further, following local anesthetic administration via the
periodontal ligament, intraseptal, or intraosseous injection, the localized area of soft tissue anesthesia associated

Special needs patients
Post mandibular implant patients
Persons with a need to “return to normal” quickly:
Business people
Social gatherings
Lunch or dinner engagements

with these injections obviates the use of phentolamine
mesylate.␣

Clinical Use of Phentolamine Mesylate in
Dentistry
Phentolamine mesylate is indicated for the reversal of soft
tissue anesthesia (e.g., anesthesia of the lip and tongue) and
the associated functional deficits resulting from an intraoral
submucosal injection of a local anesthetic containing a vasoconstrictor. Phentolamine mesylate is not recommended for
use in children younger than 3 years or weighing less than 15
kg (33 lb).94
The recommended dose of phentolamine mesylate is
based on the number of cartridges of local anesthetic with
vasoconstrictor administered. It is administered in an equal
volume, up to a maximum of two cartridges. Phentolamine
mesylate is administered at the same location(s) and by the
same technique(s) (nerve block or infiltration) used earlier
for the local anesthetic administration.94
Adverse reactions associated with the administration of
phentolamine mesylate were discussed earlier (safety and
adverse reaction discussion).94,95 Other potential complications are trismus and paresthesia, both of which are related
to the act of injection rather than to the drug itself.␣

Conclusion
Phentolamine mesylate enables the dentist or dental hygienist to significantly decrease the duration of residual soft tissue anesthesia in patients where such numbness may prove
to be potentially injurious (children, geriatric, and special
needs patients) or may have a negative influence on their
quality of life (speaking, eating, negative body image).
Although many patients might not be receptive to the
concept of “making it go away faster,” the availability in a
dental office gives each patient an option to be considered.␣

CHAPTER 20

TABLE
20.14 Expected Duration of Pulpal Anesthesia

Local Anesthetic
Formulation

Approximate Expected
Duration of Pulpal
Anesthesia by Nerve
Block (min)

3% mepivacaine

40

4% prilocaine

40–60

2% lidocaine with a
vasoconstrictor

60

4% articaine with a
vasoconstrictor

60

2% mepivacaine with a
vasoconstrictor

60

4% prilocaine with a
vasoconstrictor

60

0.5% bupivacaine with a
vasoconstrictor

240–300

Buffering (Alkalinizing) of Local
Anesthetics: The Local Anesthetic “On”
Switch
The dental profession depends on local anesthetics to provide patients with comfortable and pain-free treatment.
Deposit a local anesthetic near to a nerve and it will provide
anesthesia. Table 20.14 lists the local anesthetic formulations available with their expected onset of pulpal anesthesia.
Despite the effectiveness of these drugs in providing
pain control, there remain a number of vexing “problems”
that dentists must cope with, primarily associated with the
acidity of the local anesthetic solution itself. These include:
(1) pain during the actual administration (injection) of the
anesthetic solution, (2) a slower than desired onset of profound (pulpal) anesthesia, and (3) less than optimal effectiveness when one is seeking to anesthetize infected teeth.

Issue 1: Acidity Causes Pain During Injection
of Local Anesthetics
Fear of pain is the most common anxiety for dental
patients.1 As effective as local anesthetics can be in preventing pain during treatment, patients fear the act of receiving the anesthetic as much as or more than they fear the
dental procedure itself. The dental anesthetic injection also
provokes more emergencies than actual dental treatment.
Syncope (fainting) was the most common, accounting for
50.3% of all emergencies in a survey of 4307 dentists in
North America.100 Asked for the location and timing of
these emergencies, the respondents said that more than half
(54.9%) occurred either during or immediately following
local anesthetic administration.101,102

Recent Advances in Local Anesthesia

383

Some injection pain can be minimized or eliminated through
use of drugs and techniques discussed in previous chapters
including: injecting anesthetic slowly,103,104 using topical anesthetic, and stretching the tissue before needle penetration.105
Yet many patients still complain of a burning or stinging
sensation as the first drops of anesthetic are injected. This “bee
sting effect” is caused by the acidity of the anesthetic solution.
On the pH scale, 7.0 is neutral, above 7.0 is basic, and below
7.0 is acidic. Human physiologic pH is 7.4. All injectable local
anesthetics (plain drugs with no vasoconstrictor) are slightly
acidic. The pH of a plain drug (e.g., 3% mepivacaine HCl, 4%
prilocaine HCl) is approximately 6.4, which is closer to physiologic than local anesthetics containing a vasoconstrictor.106
Vasoconstrictors increase the depth and duration of anesthesia as well as the safety of the local anesthetic. Addition
of epinephrine to local anesthetics increases pulpal anesthesia
to approximately 60 minutes, with soft tissue anesthesia lasting between 3 and 5 hours or more. However, epinephrine is
rapidly oxidized at near physiologic pH values, so the antioxidant sodium bisulfite (NaHSO3) is added to the solution.107
The addition of NaHSO3 lowers the pH of vasoconstrictorcontaining solutions to approximately 3.5. Clinical studies
have shown pH values ranging between 2.86107 and 4.16.108
Alkalinizing (buffering) of local anesthetics has been
practiced by the medical profession for more than 100
years.109 Medical professionals do not used sealed cartridges
of local anesthetic solution. Rather, they use plastic syringes
and multidose vials of local anesthetic. As the dental profession uses standardized sealed cartridges designed for use in
dental syringes, until recently there was no practical means
of buffering dental local anesthetics.␣

Issue 2: Low pH of Local Anesthetic Solutions
Slows the Onset of Pulpal Anesthesia
The amide anesthetics are generally stated to have an onset
of between 3 and 5 minutes110-112; however, these figures
represent the onset of soft tissue anesthesia. Pulpal, or surgical depth, anesthesia develops more slowly.
Following completion of the local anesthetic injection,
most dentists report that they wait between 10 and 15 minutes before returning to the treatment room. This is usually
long enough for most patients to have achieved sufficient
anesthesia for the dentist to start the procedure (the exception
being missed blocks, which will require additional injections).
As is known by all practicing dentists (clinical experience),
and from the results of well-designed clinical trials, there exists
a significant practical and clinical distinction between the onset
of soft tissue anesthesia and the onset of pulpal anesthesia.105 Lai
et al.112 found that at 4 minutes after IANB with 2% lidocaine
with epinephrine 1:100,000, 70% of patients achieved soft tissue anesthesia (as determined with a sharp dental explorer), yet
only 25% had pulpal anesthesia (determined with an EPT). At
6 minutes the proportions were 85% for soft tissue anesthesia
and 40% for pulpal anesthesia. Kanaa et al.104 found that at 8
minutes following IANB with 2% lidocaine with epinephrine
1:80,000, 100% of patients had lingual anesthesia, 93% had