Modern Dental Pain Control

Dentistry Today

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Local anesthetics are the most important drugs used in dentistry, forming the backbone of pain control techniques. They also represent the safest and most effective drugs in all of medicine for the control and prevention of pain.
The overwhelming majority of anesthetic drugs are central nervous system (CNS) depressants—drugs that do not prevent a painful nerve stimulus from reaching the brain where it is interpreted as pain by the patient. During general anesthesia these drugs depress the brain to the point where consciousness is lost. The nociceptive stimulus evoked by the surgeon travels to the brain where, because the patient is unconscious, they are unable to respond outwardly. However the autonomic nervous system reacts to the stimulus with a brief, hopefully insignificant, elevation in blood pressure, heart rate, and respiratory rate.

LOCAL ANESTHETICS: BACKGROUND

Local anesthetics, on the other hand, deposited near a nerve between the surgical site and the brain, set up a chemical roadblock that prevents the pain impulse from ever reaching the brain (Figure 1). The patient’s level of consciousness remains unaffected when local anesthetics are administered, unlike the CNS depressants used in general anesthesia. The safety of local anesthetics may be garnered from the following statement attributed to Dr. Leonard Monheim, an icon in the history of dental anesthesiology, “Nobody ever died in the conscious state.”

Table 1. Current Local Anesthetic Formulations in the United States and Canada.

Short duration – Plain
Proprietary names
Infiltration
Nerve block
Soft tissue anestheia
Mgs per cartridge
Lidocaine HCI 2% plain
Xylocaine
5 minutes
Not indicated
2 hrs
36
Medpivacaine HCI 3% plain
Carbocaine
Isocaine
Polocaine
Scandanest
20-30 min
34-45 min
2-3 hrs
54
Prilocaine HCI 4% plain
Citanest Plain
10-15 min
45-65 min
3-4 hrs
72
Intermediate duration – with vasoconstrictor
Proprietary names
Infiltration
Nerve block
Soft tissue anestheia
Mgs per cartridge
Articaine HCI 4% + epinephrine 1:100,000
Septocaine
Zorcaine
60 min
Up to 120 min
3-5 hrs
68
Articaine HCI 4% + epinephrine 1:200,000
Septocaine
60 min
Up to 120 min
3-5 hrs
68
Lidocaine HCI 2% + epinephrine 1:50,000
Lidocaine
Lignospan
Standard
Octocaine 50
Xylocaine
55-65 min
80-90 min
3-5 hrs
36
Lidocaine HCI 2% + epinephrine 1:100,000
Lidocaine
Lignospan
Standard
Octocaine 100
Xylocaine
55-65 min
80-90 min
3-5 hrs
36
Mepivacaine HCl 2% + levonordefrin 1:20,000
Carbocaine
Isocaine 2%
Polocaine
Scandanest 2%
40-60 min
60-90 min
3-5 hrs
36
Prilocaine HCI 4% + epinephrine 1:200,000
Citanest Forte
35-45 min
50-70 min
3-6 hrs
72
Long duration
Proprietary names
Infiltration
Nerve block
Soft tissue anestheia
Mgs per cartridge
Bupivacaine HCI 0.5% + epinephrine 1:200,000
Marcaine
Vivacaine
Bupivacaine
Up tp 7 hrs
Up to 7 hrs
Up to 12 hrs
9

A number of local anesthetics are available for administration in dentistry in the United States. The major difference between these formulations is their expected duration of clinical anesthesia. Drugs are categorized as “short-acting,” “intermediate-acting,” and “long-acting.” Table 1 presents the current local anesthetic formulations available in the United States.
According to the 2002 American Dental Association’s Survey of Dental Practice, the typical treatment period for a patient in a general dentistry office is approximately 47 minutes.1 “Plain” local anesthetics (LAs) provide neither the depth nor duration of anesthesia required for anything more than short, shallow procedures. In order to provide anesthesia of a depth and duration permitting completion of the dental treatment painlessly, LAs are commonly combined with a vasopressor drug, commonly epinephrine (or levonor-defrin in the United States). Vasopressors transiently decrease vascular perfusion at their site of deposition, permitting more LA to diffuse into the nerve thereby providing a longer duration and greater depth of pain control. The duration of soft tissue anesthesia (STA) greatly exceeds that noted for pulpal anesthesia (Table 1) with the patient being dismissed at the conclusion of their treatment with several hours of residual STA.

CHALLENGES WITH THE USE OF LOCAL ANESTHETICS

Table 2. Factors Modifying Expected Duration of Anesthesia.
TECHNIQUE – accuracy in deposition of drug
‘BELL-SHAPED” CURVE – individual variation in response to drugs
ANATOMY – anatomical differences between patients
STATUS OF TISSUE AT DEPOSITION SITE – infection, hyperemia decreaseexpected duration
TYPE OF INJECTION – Nerve block longer duration than infiltration
CHRONOBIOLOGY – Time of day influences effectiveness of drug

Table 3. Difficulty in Providing Clinically Adequate Pain Control.

Though local anesthetics represent the most effective drugs for preventing pain, situations do arise in which clinically effective pain control is frustratingly elusive. Factors modifying the expected duration of anesthesia, usually in a negative manner, are listed in Table 2. Probably the 2 most significant of these factors are local anesthetic technique and the normal distribution (bell-shaped) curve, while the mandibular molar region represents the area where the overwhelming majority of these problems in pain control develop.2 (See Table 3).

Figure 1a. Impulse from the tooth reaches the brain and the patient interprets it as pain.

Figure 1b. Local anesthetic blocks impulse conduction to the brain.

Figure 2. Summary of phentolamine mesylate clinical trials. Data is combined from references 25 and 26. (Courtesy of Suzete Brasil, Erica Dicterow, Fariba Neumann, Joan Ong, dental hygiene students at the University of Southern California School of Dentistry, 2008).

The inferior alveolar nerve block (IANB), the traditional injection used to anesthetize mandibular teeth and soft tissues has the greatest failure rate on any of the major nerve blocks administered in the human body. Yet, this injection represents the most used nerve block technique in dentistry. Innovative techniques, such as the Gow-Gates mandibular block,3,4 the Akinosi-Vazirani closed-mouth mandibular block,5 periodontal ligament injection (PDL),6 and intraosseous anesthesia7 have been de-veloped or reintroduced as means of improving upon the dismal success rate of the IANB.
Successful though these may be, occasional problems are still noted in providing pain-free dentistry for our patients. A collateral problem is that following the administration of a local anesthetic, STA persists for periods ranging from 2 to 12 hours, interfering with the patient’s life style, increasing the risk of self-inflicted injury, and potentially leading to urgent medical situations such as hypoglycemia.
The remainder of this paper will discuss two relatively new additions to the dental pain management armamentarium: the local anesthetic, articaine HCl and the local anesthetic reversal agent, phentolamine mesylate.

THE USE OF ARTICAINE HCL

Table 4. Success of Articaine HCl + Epinephrine 1:100,000
by Mandibular Infiltration Versus Lidocaine HCl + Epinephrine 1:100,000.
Tooth
%(#/total) with anesthetic success
P value
 
Articanie HCI
Lidocaine HCI
2nd molar
75 (45/60)
45 (27/60)
.0001*
1st molar
87 (52/60)
57 (34/60)
.0001*
1st molar
64.5 (20/31)
38.7 (12/31)
.008*
2nd premolar
92 (55/60)
67 (40/60)
.0001*
1st premolar
86 (59/57)
61 (35/57)
.0001*
  • There were significant differences (P<.05) between the articaine and lidocaine formulations as analyzed by means of logistic regression
  • Data compiled from references 13 and 14

Articaine HCl, synthesized in the early 1970s, was introduced to dentistry in Germany in 1976 as the proprietary drug Ultracain. Today articaine HCl is available worldwide in more than 135 countries as a 4% solution with epinephrine 1:100,000 and 1:200,000. Articaine HCl, introduced into the United States in 2000, provides approximately 60 minutes of pulpal anesthesia and between 3 to 5 hours of STA. (Table 1). Articaine HCl has been hailed (anecdotally) by many practicing dentists as a local anesthetic that, in their words: “worked faster,” “worked better,” “I don’t miss as often,” and “hard to get numb patients are easy to get numb with articaine.” Yet, double-blinded, randomized, controlled-clinical trials in the United States demonstrated that articaine HCL was as safe and as effective as lidocaine HCl, the drug to which it was compared.8-10 Indeed, the overwhelming majority of clinical trials comparing articaine HCl to other LAs (mepivacaine, prilocaine) showed similar results.11-12 It is only in recent years that several well-controlled clinical trials have demonstrated a superiority of articaine HCl to other LAs in certain clinical situations.
One such situation is in providing pulpal anesthesia in the mandible, specifically to mandibular molars, the most difficult teeth to anesthetize on a consistent basis. In the first study, a cartridge of either lidocaine HCl with epinephrine 1:100,000, or articaine HCl with epinephrine 1:100,000, was injected in the buccal fold adjacent to the first mandibular molar.13 An electronic pulp tester (EPT) was used to evaluate efficacy of anesthesia (EPT every 2 minutes until 30 minutes post injection. Success was measured as absence of pulp sensation on 2 consecutive maximal pulp tester stimulations (80 uA). Kanaa et al,13 found a 64.5 success with articaine HCl compared with 37.7% for lidocaine HCl (P = .008). A similar study by the Ohio State University Postdoctoral Endodontic group demonstrated remarkably similar results.14 Testing the second and first molars, and second and first premolars, with EPT every 3 minutes and using the same criteria for success as Kanaa et al; articaine HCl provided significantly greater degrees of pulpal anesthesia than lidocaine HCl for all teeth tested. (Table 2).
Another potential advantage possessed by articaine HCl is its 27 minute distribution half-life. Other amide local anesthetics possess half-lives of approximately 90 minutes.15 Blood levels of articaine HCl decrease significantly quicker than other LAs providing several potential benefits: decreased risk of overdose (toxic reaction) from overadministration (but not from rapid in-travascular injection), and increased utility in the nursing mother.
All local anesthetics are safe drugs when used properly, however drug overdose remains the most likely drug-related complication associated with their administration. A Medline search (August 3, 2008) dating back to 1975 did not find any reported death associated with the administration of articaine in either dentistry or medicine (272 cited papers).
The nursing mother in need of dental care that is potentially painful will require a local anesthetic. A common question from this patient is: “Will the drug be found in my milk?” The answer is yes. Before the doctor or hygienist can add, “But it is safe for your infant,” the mother will say, “Then I don’t want it.” Local anesthetics will be found in decreasing amounts in the blood (and therefore in the milk) for a period equal to approximately 6 times the elimination half-life of the drug. (At 6 half-lives the blood level of a drug has decreased by 98.5%). Lidocaine HCl, mepivacaine HCl and prilocaine HCl, with half-lives of about 90 minutes will be found in the blood and milk for approximately 9 hours following administration. Articaine HCl, with a half-life of 27 minutes will be in the blood and milk for about 162 minutes (2 hours and 42 minutes) making it easier to use in those situations where LAs are required. The nursing mother can pump and store milk prior to receiving the LA.
Though articaine HCl has become a popular LA in most countries, there exists a sense amongst some people that its use is associated with a higher risk of paresthesia. Haas and Lennon16 published results of voluntary reports to an insurance plan in Ontario, Canada indicating that 4% LAs have a greater reported incidence of paresthesia than 2% or 3% LAs. Though admittedly a preliminary survey, many have interpreted their results as the “gospel chipped in stone”—as definitive evidence that 4% LAs in general, and articaine HCl in particular, are associated with a greater risk of paresthesia. It has been recommended by some “experts” and agencies that articaine HCl not be administered by inferior alveolar nerve block (IANB) because of this increased risk.17-19
In response to the Hillerup paper,17 the Pharmacovigilance Committee of the European Union (the equivalent of the Food and Drug Administration in the United States) reviewed articaine HCl. They concluded that the “safety profile of the drug (articaine) has not significantly evolved since its initial launch (1998). Thus, no medical evidence exists to prohibit the use of articaine according to the current guidelines listed in the summary of product characteristics” (the drug package insert).20
In 2007, Pogrel21 reported on 53 cases of LA-related paresthesia referred to him in northern California for evaluation. Lidocaine HCl had been administered in 35% of the cases evaluated, articaine HCl in 30% and prilocaine HCl in 30%. When adjusted for the percentage of sales for each of the drugs, Pogrel concluded: “…based on the figures we have generated from our clinic we do not see any disproportionate nerve involvement from articaine.”

PHENTOLAMINE MESYLATE: AN LA REVERSAL AGENT

As noted above and in Table 1, the duration of soft tissue anesthesia (STA) is considerably longer than that of pulpal anesthesia and of the duration of the typical dental appointment. Residual STA can be of benefit to the patient in the post-treatment period when the dental procedure is traumatic and associated with postoperative pain. Examples include endodontic procedures, periodontal surgery, oral surgical procedures, implants, or other extensive dental interventions. However, the vast majority of dental procedures, though requiring pain prevention through LA administration, are not associated with any degree of postoperative pain. The continued presence of STA into the post-treatment period is oftentimes unwanted and even undesirable.
Reports in pediatric dentistry indicate that up to 13% of patients suffer traumatic injury to their still anesthetized soft tissues following LA administration in the dental office.22 More commonly, residual STA is simply more of an inconvenience or annoyance to the patient and doctor than a risk. Patients feel that residual STA interferes with their normal daily activities in 3 areas: perceptual (perception of altered physical appearance), sensory (lack of sensation), and functional (diminished ability to speak, smile, drink, and control drooling).23 Many dental patients complain to their doctors at subsequent appointments that they were unable to eat a meal, or to talk normally for many hours after their last dental visit, because their lip and/or tongue were still numb. The request of “Doctor, can’t you make the numbness go away faster?” has been uttered by patients to most doctors.