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- Nonsteroidal anti-inflammatory drugs (NSAIDs) can prevent dysmenorrhea, unlike other agents that simply relieve symptoms.
- Although NSAIDs in one form or another have been used for centuries, agents introduced in the past 50 years have significantly improved efficacy and safety profiles.
- A greater understanding of the role of prostaglandins in physiologic and pathophysiologic processes can enhance the selection of appropriate therapeutic agents.
- Some drugs can selectively block the cyclooxygenase-2 (COX-2) isoform of the enzyme instrumental in the production of prostaglandins.
A major shift in the way menstrual pain is viewed and treated took place in the 1970s and ’80s, with a greater understanding of the role of prostaglandins and more effective nonsteroidal anti-inflammatory drugs (NSAIDs). Subjective studies of pain and objective studies of uterine activity established a firm connection between the two. These studies also amply demonstrated the ability of NSAIDs to alter the physiology of dysmenorrhea, making it possible to prevent—rather than simply relieve—pain.
Yet, these agents still are not universally used in the treatment of dysmenorrhea, despite more than 20 years of experience with them. Moreover, the introduction of new NSAIDs has clouded rather than clarified the issue of their relative efficacy. Drugs that are welldesigned for the suppression of chronic inflammation (e.g., arthritis therapies) are not very effective for dysmenorrhea, and vice versa. Even so, it is possible to apply the findings of published studies and an understanding of the pathophysiology of dysmenorrhea to demystify the range of options.
The therapeutic effects of NSAIDs come from their ability to inhibit the production of prostaglandin.
A brief history
The term “dysmenorrhea” is derived from a Greek root meaning “difficult monthly flow,” but it did not make its appearance in the English language until about 1810. Therapies for dysmenorrhea ranged from the plausible and somewhat effective to the outlandish and useless. Everything from cauterizing the middle turbinate of the nose,1 exercise programs,2 and presacral sympathectomy3,4 to uterine-relaxing factor,5 vasodilators,6,7 tranquilizers,8 and hormones9-11 have been tried. Today’s effective therapies against primary dysmenorrhea are an outgrowth of earlier observations of uterine activity and the presence of a menstrual “toxin.” That toxin was later identified as prostaglandin.
Endometrial prostaglandin production is tied to changes throughout the menstrual cycle. Prostaglandin is stored in the endometrium as it thickens in preparation for implantation or menstruation. With the onset of menstruation, preformed prostaglandins are liberated and large amounts of arachidonic acid are released from the cell walls of sloughed endometrial cells. This large increase in arachidonic acid substrate results in a tremendous rise in prostaglandin production, which augments the supplies of preformed prostaglandins liberated from the sloughed endometrial cells.
The causative role of prostaglandin F2α in dysmenorrhea was confirmed when researchers triggered dysmenorrhea-like pain and uterine activity after intravenous (IV) injection of prostaglandins.12 (Current evidence indicates that women with primary dysmenorrhea make 2 to 7 times the normal amount of prostaglandin F2α.) Excess prostaglandins also may be responsible for the smooth-muscle activity noted in the gastrointestinal (GI) tracts of these women. Hypermobility of the gut may be responsible for the frequent coexistence of nausea, vomiting, and diarrhea in these patients. In addition, prostaglandins appear to act as initiators and potentiators of nociceptive pain signals, further contributing to the symptoms of dysmenorrhea.
In 1967, Pickles demonstrated that prostaglandin levels were lower during anovulatory cycles, prompting the use of oral contraceptives (OCs) to suppress ovulation and relieve menstrual pain.13,14 Although this approach is usually successful, not all women want to—or can—use OCs. NSAIDs more directly alter the physiologic sequence leading to discomfort by inhibiting the production and/or action of prostaglandins. Moreover, NSAIDs generally are well-tolerated and need only be taken at the time of menstruation. While OCs act to reduce the substrate available to the reaction, NSAIDs act to block the pathway at 2 later enzymatic steps.
In 1979, Jacobson et al reported successful pain relief in 64% to 100% of patients from 16 studies of NSAIDs in dysmenorrhea.15 Unfortunately, few of those studies were double-blinded, and many failed to report the incidence of side effects. Dingfelder evaluated 23 trials published from 1970 to 1980 and found a 67% to 86% rate of pain relief.16 In a more thorough review, Owen presented data from 51 reports and attempted to analyze the diverse methods, designs, and outcomes.17 She found an 87% rate of “excellent” pain relief for the fenamates versus 56%, 68%, and 56% for ibuprofen, indomethacin, and naproxen, respectively. Unfortunately, she lumped together 2 different drugs (tolfenamic and mefenamic acids) and misinterpreted some primarily methodological reports. More recent attempts to analyze existing studies have failed to further clarify the issue.18,19
Prostaglandins are made throughout the body and are important autocrine and paracrine regulators of cellular and organ function. As depicted below, the main substrate for their production is arachidonic acid, a major constituent of cell walls. Under some circumstances, phospholipase A2 also can be used as a substrate for prostaglandin production.
Cyclooxygenase, also called prostaglandin H synthase, is the first enzymatic step in the conversion of arachidonic acid into prostaglandins. This enzyme folds the arachidonic acid molecule (cyclization) and oxygenates it to produce prostaglandin H2 (PGH2).
All other members of the prostaglandin family are then formed from PGH2. Arachidonic acid also is the substrate for the production of leukotrienes and 5-hydroxyeicosatetraenoic acid (5-HETE) through the 5-lipooxygenase pathway. Like prostaglandins F2α and E2, the products of the lipooxygenase pathway are potent vasoconstrictors and stimulators of uterine contractions.—Roger P. Smith, MD, and Jeffrey Ellis, MD
Increased uterine activity was first hypothesized as a cause of dysmenorrhea in 1932. By the late 1930s, objective findings began to support that hypothesis.1 The correlation between uterine activity and menstrual pain was strengthened when Jacobson et al studied simultaneous electrical and mechanical changes within the uterus.2,3 Using an intrauterine air-filled balloon system, Wilson and Kurzrok also noted the relationship between maximal uterine activity and pain.4,5 Despite the strength of these investigations, few changes occurred in the way dysmenorrhea was viewed or treated.
In the late 1940s, Liessé demonstrated that women with dysmenorrhea not only had a greater degree of uterine electrical and mechanical activity, but that this activity correlated with the pain of menstruation.6 Liessé found minimal activity between pains and as many as 30 irregular electrical discharges per second during pain, suggesting a cause (electrical) for dysmenorrhea but offering no clue to the underlying physiologic disturbance that might account for it.
The most detailed and influential studies of dysmenorrhea and uterine activity came in 1947 in a trial conducted by Woodbury.7 His findings of a direct correlation between pressure, pattern of contractions, resting tone, and pain became a standard reference.
After Woodbury, the stage was set for a connection to be made between uterine activity and prostaglandins. That happened in 1965, when Pickles reported elevated levels of prostaglandin F2αin the menstrual fluid of dysmenorrheic women.8
During the past 2 decades, more sophisticated analytic techniques have been applied to intrauterine pressure data,9,10 and strong correlations between uterine activity and pain have been reported.11,12 The basic assertion that menstrual pain is caused by increased intrauterine pressure, poor relaxation, and more frequent, irregular contractions appears to be valid.—Roger P. Smith, MD, and Jeffrey Ellis, MD
REFERENCES
1. Novac E, Reynolds SRM. The cause of primary dysmenorrhea. JAMA. 1932;99:1466.-
2. Jacobson E, Lackner JE, Sinykin MB. Electrical and mechanical activity of the human non-pregnant uterus. Am J Obstet Gynecol. 1939;38:1008.-
3. Jacobson E, Lackner JE, Sinykin MB. Activity of the human non-pregnant uterus. Am J Physiol. 1940;53:407.-
4. Wilson L, Kurzrok R. Studies on the motility of the human uterus in vivo. Endocrinology. 1938;23:79.-
5. Wilson L, Kurzrok R. Uterine contractility in functional dysmenorrhea. Endocrinology. 1940;27:23.-
6. Liessé A. L’Activité électrique de l’uterus dans la dysmenorrhee functionnelle. Gynec et Obstet. 1948;47:850.-
7. Woodbury RA, Torpin R, Child GP, Watson H, Jarboe M. Myometrial physiology and its relation to pelvic pain. JAMA. 1947;134:1081-1085.
8. Pickles VR, Hall WJ, Best FA, Smith GN. Prostaglandins in endometrium and menstrual fluid from normal and dysmenorrheic subjects. J Obstet Gynaecol Br Comm. 1965;72:185.-
9. Smith RP. Intrauterine pressure analysis in nonpregnant dysmenorrheic women. Med Instr. 1984;185:137-139.
10. Smith RP. Distribution analysis of intrauterine pressure in nonpregnant dysmenorrheic women. Am J Obstet Gynecol. 1984;150:271-273.
11. Smith RP. The dynamics of nonsteroidal anti-inflammatory therapy for primary dysmenorrhea. Obstet Gynecol. 1987;70:785-788.
12. Smith RP, Powell JR. Simultaneous objective and subjective evaluation of meclofenamate sodium in the treatment of primary dysmenorrhea. Am J Obstet Gynecol. 1987;157:611-616.
Classes of NSAIDs
Although aspirin was synthesized in 1853 and incorporated into medical practice in 1899, its history goes back even farther. That fact—along with the introduction of newer agents—ensured that NSAIDs became the mainstays of medical therapy for fever, pain, and inflammation. In the United States, NSAIDs are among the most widely prescribed drugs, with more than 70 million prescriptions and more than 30 billion over-the-counter tablets sold each year.20 Most of their therapeutic effects come from their ability to inhibit the production of prostaglandins.21
Interestingly, some drugs with the ability to inhibit prostaglandin synthesis have little clinical usefulness. Some have weak antiprostaglandin activity, require metabolic transformation to become active, or have side effects that limit their usefulness. While these drugs can be used to treat dysmenorrhea, they generally have been replaced by more effective agents.
There are 2 broad classes of NSAIDs: enolic acids and carboxylic acids. Each class can be further subcategorized (Table 1).
Enolic acids. With the exception of the newer cyclooxygenase-2 (COX-2) selective agents, drugs of the enolic-acid type are primarily type II inhibitors of prostaglandin synthesis. That means they impede the isomerase/reductase step in the formation of prostaglandins E2 (PGE2) and F2α (PGF2α). The most frequently used agents in the enolic-acid group are phenylbutazone and piroxicam.
Phenylbutazone was discovered in the 19th century during a search for a substitute for quinine. (Quinine had become popular for the treatment of fever; however, uncontrolled cutting of the Peruvian cinchona tree dramatically increased its cost.) While phenylbutazone is an effective shortterm analgesic for musculoskeletal pain (through antiprostaglandin activity), its relative toxicity has limited its use in dysmenorrhea and general therapy.
Piroxicam has a long half-life (50 hours), making once-daily dosing possible. Its action as an anti-inflammatory drug for the treatment of arthritis is well-established, but its use as an analgesic for acute pain therapy or for dysmenorrhea has not been fully evaluated. Based on the pharmacodynamics of drug absorption and action, one would anticipate its efficacy in that regard to be poor. In general, drugs in the pyrazolone group have a higher incidence of blood dyscrasias, limiting their broad utility.
Celecoxib is structurally similar to phenylbutazone and was the first selective COX-2 inhibitor approved by the Food and Drug Administration (FDA). It has been studied in dental pain models and the treatment of osteoarthritis. In these trials, celecoxib performed as well as naproxen and slow-release diclofenac, but with fewer GI side effects. No data on its use in dysmenorrhea is available.
Chemically related but less similar to the enolic acids is refecoxib. Like celecoxib, it has been studied in the treatment of osteoarthritis, where it was comparable in efficacy to ibuprofen and diclofenac, but with side-effect rates similar to placebo therapy. In studies of women with primary dysmenorrhea, rofecoxib has proved to be statistically superior to placebo but indistinguishable from naproxen (Figure 1).22 Peak blood levels are achieved in 2 to 3 hours (delayed by 1 to 2 hours by a fatty meal), but a steady state is not achieved until day 4 of continuous therapy. When the drug is used to treat women who have a rapid onset of symptoms, the significance of this delay is unclear but is a potential drawback. In addition, the dosage of rofecoxib for the treatment of pain or dysmenorrhea is generally much larger than that required for the treatment of arthritis. Thus, the risk of side effects may be increased.
A third selective COX-2 inhibitor, meloxicam, was introduced into the US market solely for the treatment of osteoarthritis. This drug is marketed on the basis of its more favorable side-effect profile rather than its selectivity in blocking the COX-2 isoform.
Carboxylic acids. The first of the carboxylic acid subgroups are the salicylic acids. The use of salicylates derived from the bark or leaves of the Salic alba or S. fragilis dates back to Biblical times. Salicylates were formally introduced into medical use in 1763 by the Reverend Edmund Stone.23
The relatively low potency of aspirin for reducing prostaglandin synthesis in the uterus limits its clinical utility in preventing moderate or severe dysmenorrhea. In contrast, diflunisal has a long half-life, making twice-daily dosing possible. However, its slow onset of action limits use for most patients with menstrual pain.
The indoleacetic acid subgroup offers increased potency against dysmenorrhea. Most of these drugs have a direct effect rather than requiring metabolism into an active form.
Indomethacin was one of the first NSAIDs widely used to treat dysmenorrhea, but a moderate incidence of side effects limits its use—and that of most of the other drugs in this family.
No NSAID completely eliminates gastric cyclooxygenase activity.
The most commonly used drugs for dysmenorrhea come from the 2 remaining carboxylate groups: arylalkanoic acids (propionic acid derivatives) and anthranilic acids (fenamates). Of the propionic acid derivatives currently available, ibuprofen and naproxen are commonly used for dysmenorrhea. Other drugs of this class have been used for pain relief or arthritis therapy, but are not currently FDA-approved for dysmenorrhea. The subset of drugs that are phenylpropionic acid derivatives are associated with a higher incidence of GI side effects and skin reactions.
Mefenamic acid was the first alternative synthesized in an effort to reduce the gastric irritation caused by acetylsalicylic acid.24 Mefenamic acid and meclofenamate sodium—both fenamates—are potent prostaglandin synthetase inhibitors. In addition, they have been shown to antagonize already formed prostaglandins, providing a dual mode of action.25-28 This ability to block the action of existing prostaglandins produces a more rapid onset of uterine relaxation. Some of the first studies of NSAIDs in dysmenorrhea used these agents.29,30 In fact, they are some of the most thoroughly investigated drugs for the treatment of dysmenorrhea, shown to be consistently effective in reducing its subjective discomfort.31-35
In the U.S., mefenamic acid was one of the first drugs approved for dysmenorrhea, and clinical studies have shown meclofenamate to be very effective in improving symptoms and altering the underlying pathophysiology.36,37 The dual mechanism of action likely gives these agents an edge in efficacy, although no clinical trials have been initiated to evaluate this presumed advantage. Intrauterine pressure changes have been documented as soon as 15 minutes after administration of the medications, suggesting a very rapid onset of action (obviating the need for preloading). In addition, in vitro studies have demonstrated meclofenamate’s ability to inhibit the activity of 5-lipooxygenase, unlike members of the propionic acid group, which have little or no inhibitory ability.38,39 The clinical significance of inhibiting the production of the extremely potent leukotrienes has yet to be fully explored.
TABLE 1
Families of NSAIDs
Family | Example |
---|---|
ENOLIC ACIDS | |
PYRAZOLONES | |
Oxyphenbutazone | Azolid** |
Phenylbutazone | Butazolidin** |
Nabumetone | Relafen |
Celecoxib | Celebrex |
Rofecoxib* | Vioxx |
OXICAMS | |
Piroxicam | Feldene, Piroxicam |
Meloxicam | Mobic |
CARBOXYLIC ACIDS | |
SALICYLIC ACIDS | |
Acetylsalicylic acid | Aspirin (various) |
Diflunisal | Dolobid |
Salicylate | Disalcid, Trilisate |
INDOLEACETIC ACIDS | |
Diclofenac potassium | Cataflam |
Diclofenac sodium | Voltaren, Arthrotec (combined with misoprostol) |
Etodolac | Lodine |
Indomethacin | Indocin |
Ketorolac tromethamine | Acular, Toradol |
Sulindac | Clinoril, Sulindac |
Tolmetin | Tolectin, Tolmetin |
PROPIONIC ACIDS | |
Fenoprofen calcium | Fenoprofen |
Flurbiprofen | Flurbiprofen |
Ibuprofen* | Motrin |
Ketoprofen | Orudis, Oruvail, Ketoprofen |
Naproxen sodium* | Aleve, Anaprox, Naprelan |
Naproxen* | Naprosyn |
FENAMATES | |
Meclofenamate sodium* | Meclofenamate |
Mefenamic acid | Ponstel |
*FDA-approved for primary dysmenorrhea | |
**No longer available | |
Adapted from: Smith RP.Gynecology in Primary Care. Baltimore, Md: Williams and Wilkins; 1996:399. |
FIGURE 1 Comparison of rofecoxib, naproxen, and placebo in treatment of primary dysmenorrhea
Reprinted with permission from The American College of Obstetricians and Gynecologists. Morrison BW, Daniels SE, Kotey P, Cantu N, Seidenberg B. Rofecoxib, a specific cyclooxygenase-2 inhibitor, in primary dysmenorrhea: a randomized-controlled trial. Obstet Gynecol. 1999;94:504-508.
COX-2 inhibitors
Although the short-term efficacy and safety of new selective COX-2 inhibitors appear to be good, several concerns remain. Despite a decrease in the incidence of GI side effects with these agents, their use by patients with active GI ulceration, infection with Helicobacter pylori, or inflammatory bowel disease has not been adequately studied. Indeed, recent studies suggest that, at therapeutic concentrations, no NSAID—not even the selective COX-2 inhibitors—completely eliminates gastric cyclooxygenase activity.40
In addition, questions have been raised about the speed and efficacy of the selective COX-2 inhibitors for the management of acute pain, compared with conventional NSAIDs.41 When used for postoperative analgesia, these agents theoretically could retard wound healing because of the role that COX-2 plays in healing and neovascularization. As more data emerge about the physiologic functions of COX-1 and -2 (Table 2), there are growing concerns that COX-2 is not restricted to inflammation and pathology, suggesting the possibility of unanticipated adverse effects associated with its use. For example, there is evidence of constitutive expression of COX-2 in the kidney and brain, and essential physiological functions in ovulation and implantation.42 In the treatment of dysmenorrhea, the increased cost of these drugs over the more commonly used agents, along with the lack of clinical efficacy studies, suggests a second-line role.
Like most NSAIDs, COX-2 inhibitors fall into pregnancy category C. Because of the risk of premature closure of the ductus arteriosus, they should not be used in the third trimester of pregnancy. In addition, drug levels in human milk mimic those in serum, so the decision to use these agents in nursing mothers must be made carefully.
Studies over the past 10 years have revealed that the cyclooxygenase enzyme (COX) is found in 2 isomeric forms, known as COX-1 and COX-2.1 Initial investigations suggested that COX-1 was present in most tissues and responsible for the homeostatic production of arachidonic acid metabolites. The COX-2 enzyme was thought to be induced in response to inflammatory stimuli such as cytokines and bacterial lipopolysaccharides, rather than expressed under normal cellular function. Thus, the COX-2 form was thought to be responsible for the large amounts of prostaglandins associated with inflammation. It was further hypothesized that COX-2 used intracellular arachidonic acid as a substrate almost exclusively, while COX-1 could use phospholipase A2 as an extracellular substrate under some conditions.2
Recent data suggest that COX-1 and -2 are more complex than originally assumed. There is increasing evidence that COX-2 is constitutively expressed in the brain, kidneys, and pancreatic islet cells and plays a role in intestinal tolerance to dietary antigens, ulcer healing, ovulation, and implantation. Transgenic mice with deletions of the COX-2 enzyme maintain the inflammatory response when only COX-1 is present.3
In the reproductive tract, COX-2 expression increases substantially in midcycle because of the surge in luteinizing hormone (LH). COX-2 and the resulting prostaglandins (released from granulosa cells) are thought to play an important role in rupture of the follicle.4,5 With fertilization, COX-2 expression increases in the endometrium surrounding the implantation site.6 The resultant prostaglandins are important for successful implantation and angiogenesis. Interestingly, transgenic mice that lack the COX-2 enzyme are infertile, while those missing only the COX-1 enzyme have normal reproduction.7,8
Studies also have demonstrated a rapid increase in COX-2 expression in the placenta and amnion immediately before and during labor.9 It is well established that prostaglandins have a pivotal role in myometrial contraction10 and inhibition of COX-2 has been shown to delay labor.11
The COX-1 and -2 enzymes share approximately 60% homology.12 Both have a long, narrow channel that is the active site of arachidonic acid folding and oxygenation. The critical difference between the 2 isoenzymes occurs at position 523, where the COX-1 enzyme has an isoleucine while COX-2 has a valine.13 This substitution causes the channel in the COX-2 form to be 17% wider; it also provides a side pocket that increases the volume of the active site by 8%. Drugs that are designed to block the COX-2 enzyme take advantage of this difference in channel size—they are too large to fit the normal channel. Nonselective NSAIDs are small enough to block the channel in both isoenzymes while, at least in theory, the selective agents can block only the larger channel.14 Most COX-2 inhibitors also exhibit some action against the COX-1 isoform.—Roger P. Smith, MD, and Jeffrey Ellis, MD
REFERENCES
1. Smith WL, Garavito RM, DeWitt DL. Prostaglandin endoperoxide H synthase (cyclooxygenase)-1 and -2. J Biol Chem. 1996;271:33157.-
2. Herschman HR. Prostaglandin synthase 2. Biochem Biophys Acta. 1996;1299:125-140.
3. Wallace JL, Bak A, McKnight W, Asfaha S, Sharkey KA, MacNaughton WK. Cyclooxygenase 1 contributes to inflammatory responses in rats and mice: implications for gastrointestinal toxicity. Gastroenterology. 1998;115:101-109.
4. Richards JS, Fitzpatrick SL, Clemens JW, Morris JK, Alliston T, Sirois J. Ovarian cell differentiation: a cascade of multiple hormones, cellular signals, and regulated genes. Recent Prog Horm Res. 1995;50:223-254.
5. Akil M, Amos RS, Stewart P. Infertility may sometimes be associated with NSAID consumption. Br J Rheumatol. 1996;35:76-78.
6. Chakraborty I, Das SK, Wang J, Dey SK. Developmental expression of the cyclo-oxygenase-1 and cyclooxygenase-2 genes in the peri-implantation mouse uterus and their differential regulation by the blastocyst and ovarian steroids. J Mol Endocrinol. 1996;16:107-122.
7. Lim H, Paria BC, Das SK, Dinchuk JE, Langenbach R, Trzaskos JM, et al. Multiple female reproductive failures in cyclooxygenase 2-deficient mice. Cell. 1997;91:197-208.
8. Langenbach R, Loftin C, Lee C, Tiano H. Cyclooxygenase knockout mice: models for elucidating isoform-specific functions. Biochem Pharmacol. 1999;58:1237-1246.
9. Gibb W, Sun M. Localization of prostaglandin H synthase type 2 protein and mRNA in term human fetal membranes and decidua. J Endocrinol. 1996;150:497-503.
10. O’Brien WF. The role of prostaglandins in labor and delivery. Clin Perinatol. 1995;22:973-984.
11. Mitchell MD, Romero RJ, Edwin SS, Trautman MS. Prostaglandins and parturition. Reprod Fertil Dev. 1995;7:623-632.
12. Kurumbail RG, Stevens AM, Gierse JK, et al. Structural basis for selective inhibition of cyclooxygenase-2 by anti-inflammatory agents. Nature. 1996;384:644-4.(Published correction appears in Nature. 1997;385:555.)
13. Gierse JK, McDonald JJ, Hauser SD, Rangwala SH, Koboldt CM, Seibert K. A single amino acid difference between cyclooxygenase-1 (COX-1) and -2 (COX-2) reverses the selectivity of COX-2 specific inhibitors. J Biol Chem. 1996;271:15810.-
14. Lanzo CA, Beechem JM, Talley J, Marnett LJ. Investigation of the binding of isoform-selective inhibitors to prostaglandin endoperoxide synthases using fluorescence spectroscopy. Biochemistry. 1998;37:217-226.
TABLE 2
Comparison of COX-1 and COX-2 in human tissues
Characteristic | COX-1 | COX-2 |
---|---|---|
Tonic expression | High | Low |
Inducibility | Low | High |
Predominant location | All (stomach, kidney, platelets, vasculature) | Sites of inflammation (neoplastic tissue, small intestine, ovary, uterus, brain) |
Function | Homeostasis | Inflammation and repair, neoplasia, modulation of immune response |
Conclusion
It is apparent from the multitude of published studies and the breadth of clinical experience with NSAID therapy for primary dysmenorrhea that most of these drugs provide relief for the majority of dysmenorrheic women. The success rates reported from both subjective and objective studies of the use of mefenamic acid in dysmenorrhea support its potential superiority. The physiology of primary dysmenorrhea would suggest that the ability of the fenamates to block the action of preformed prostaglandins—as well as the 5-lipooxygenase pathway—gives them a therapeutic edge. Interestingly, one investigation of the level of selectivity of multiple NSAIDs found that mefenamic acid had a selectivity (preferential COX-2 inhibition) comparable to some of the newest selective COX-2 inhibitors.43 This may account for the low incidence of GI and other side effects reported with mefenamic acid.
The history of NSAIDs has involved the sequential introduction of agents designed to reduce side effects or increase efficacy, often through the modification of existing compounds. Many of these products have failed to meet expectations and have been withdrawn from the market. Notable recent examples include benoxaprofen, suprofen, oxyphenbutazone, and zomepirac.
Thus, it is ironic that mefenamic acid, the first agent introduced to overcome the drawbacks of aspirin, has proved to be so robust in efficacy and tolerability. In addition, it is one of the only agents objectively shown to reduce menstrual blood loss in women with menorrhagia,44-47 and to ease menstrual migraine48 and the physical and emotional symptoms of premenstrual syndrome.49-51 In fact, the combination of dysmenorrhea, premenstrual syndrome, and menorrhagia experienced by many women would seem to support the use of mefenamic acid over other agents.
Unfortunately, no direct comparisons of various drugs have definitively resolved the question of which agent is “best” for the treatment of dysmenorrhea. Until there is further refinement of our knowledge of uterine prostaglandins, menstrual function, and the physiology of dysmenorrhea, it would seem wise to rely on agents that have been studied most extensively.
Dr. Smith reports no financial relationship with any companies whose products are mentioned in this article. Dr. Ellis reports that he is on the speakers’ bureau for First Horizon Pharmaceutical Company.
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29. Schwartz A, Zor U, Lindner HR, Naor S. Primary dysmenorrhea. Alleviation by an inhibitor of prostaglandin synthesis and action. Obstet Gynecol. 1974;44:709.-
30. Kauppila A, Ylikorkala O. Indomethacin and tolfenamic acid in primary dysmenorrhea. Eur J Obstet Gynecol Reprod Biol. 1977;7:59.-
31. Anderson ABM, Haynes PJ, Fraser IS, Turnbull AC. Trial of prostaglandin-synthetase inhibitors in primary dysmenorrhea. Lancet. 1978;1:345.-
32. Kapadia L, Elder MG. Flufenamic acid in treatment of primary spasmodic dysmenorrhea. Lancet. 1978;1:348.-
33. Budoff PW. Use of mefenamic acid in the treatment of primary dysmenorrhea. JAMA. 1979;241:2713.-
34. Powell JR, Smith RP. Mefenamic acid (Ponstel) for treating primary spasmodic dysmenorrhea. Curr Ther Res. 1981;29:544.-
35. Roy S. A double-blind comparison of a propionic acid derivative (ibuprofen) and a fenamate (mefenamic acid) in the treatment of dysmenorrhea. Obstet Gynecol. 1983;61:628.-
36. Smith RP, Powell JR. Simultaneous objective and subjective evaluation of meclofenamate sodium in the treatment of primary dysmenorrhea. Am J Obstet Gynecol. 1987;157:611.-
37. Smith RP. The dynamics of nonsteroidal anti-inflammatory therapy for primary dysmenorrhea. Obstet Gynecol. 1987;70:785.-
38. Boctor AM, Eickholt M, Pugsley TA. Meclofenamate sodium is an inhibitor of both the 5-lipooxygenase and cyclooxygenase pathways of the arachidonic acid cascade in vitro. Prostaglandins, Leukotrienes & Med. 1986;23:229.-
39. Myers RF, Siegel MI. Differential effects of anti-inflammatory drugs on lipooxygenase and cyclooxygenase activities of neutrophils from a reverse passive Arthus reaction. Biochemical Biophysical Res Comm. 1983;112:586.-
40. Feldman M, McMahon AT. Do cyclooxygenase-2 inhibitors provide benefits similar to those of traditional nonsteroidal anti-inflammatory drugs, with less gastrointestinal toxicity? Ann Intern Med. 2000;132:134-143.
41. Bannwarth B. Are COX-2 inhibitors as effective as conventional NSAIDs in acute pain states? [letter] Arch Intern Med. 2001;161:127-128.
42. Lipsky PE, Brooks P, Crofford LJ, DuBois R, Graham D, Simon LS, van de Putte LBA, Abramson SB, et al. Unresolved issues in the role of cyclooxygenase-2 in normal physiologic processes and disease. Arch Intern Med. 2000;160(7):913-920.
43. Cryer B, Feldman M. Cyclooxygenase-1 and cyclooxygenase-2 selectivity of widely used nonsteroidal anti-inflammatory drugs. Am J Med. 1998;104(5):413-421.
44. Fraser IS, Pearse C, Shearman RP, Elliott PM, McIlveen J, Markham R. Efficacy of mefenamic acid in patients with a complaint of menorrhagia. Obstet Gynecol. 1981;58:543-551.
45. Fraser IS, McCarron G, Markham R, Robinson M, Smyth E. Long-term treatment of menorrhagia with mefenamic acid. Obstet Gynecol. 1983;61:109-112.
46. Vargyas JM, Campeau JD, Mishell DR Jr. Treatment of menorrhagia with meclofenamate sodium. Am J Obstet Gynecol. 1987;157:944-950.
47. Van Eijkeren MA, Christiaens GCML, Geuze HJ, Haspels AA, Sixma JJ. Effects of mefenamic acid on menstrual hemostasis in essential menorrhagia. Am J Obstet Gynecol. 1992;166:1419-1428.
48. Al-Waili NS. Treatment of menstrual migraine with prostaglandin synthesis inhibitor mefenamic acid: double-blind study with placebo. Eur J Med Res. 2000;5:176-182.
49. Wood C, Jakubowicz D. The treatment of premenstrual symptoms with mefenamic acid. Br J Obstet Gynaecol. 1980;87:627-630.
50. Jakubowicz DL, Godard E, Dewhurst J. The treatment of premenstrual tension with mefenamic acid: analysis of prostaglandin concentrations. Br J Obstet Gynaecol. 1984;91:78-84.
51. Mira M, McNeil D, Fraser IS, Vizzard J, Abraham S. Mefenamic acid in the treatment of premenstrual syndrome. Obstet Gynecol. 1986;68:395-398.
- Nonsteroidal anti-inflammatory drugs (NSAIDs) can prevent dysmenorrhea, unlike other agents that simply relieve symptoms.
- Although NSAIDs in one form or another have been used for centuries, agents introduced in the past 50 years have significantly improved efficacy and safety profiles.
- A greater understanding of the role of prostaglandins in physiologic and pathophysiologic processes can enhance the selection of appropriate therapeutic agents.
- Some drugs can selectively block the cyclooxygenase-2 (COX-2) isoform of the enzyme instrumental in the production of prostaglandins.
A major shift in the way menstrual pain is viewed and treated took place in the 1970s and ’80s, with a greater understanding of the role of prostaglandins and more effective nonsteroidal anti-inflammatory drugs (NSAIDs). Subjective studies of pain and objective studies of uterine activity established a firm connection between the two. These studies also amply demonstrated the ability of NSAIDs to alter the physiology of dysmenorrhea, making it possible to prevent—rather than simply relieve—pain.
Yet, these agents still are not universally used in the treatment of dysmenorrhea, despite more than 20 years of experience with them. Moreover, the introduction of new NSAIDs has clouded rather than clarified the issue of their relative efficacy. Drugs that are welldesigned for the suppression of chronic inflammation (e.g., arthritis therapies) are not very effective for dysmenorrhea, and vice versa. Even so, it is possible to apply the findings of published studies and an understanding of the pathophysiology of dysmenorrhea to demystify the range of options.
The therapeutic effects of NSAIDs come from their ability to inhibit the production of prostaglandin.
A brief history
The term “dysmenorrhea” is derived from a Greek root meaning “difficult monthly flow,” but it did not make its appearance in the English language until about 1810. Therapies for dysmenorrhea ranged from the plausible and somewhat effective to the outlandish and useless. Everything from cauterizing the middle turbinate of the nose,1 exercise programs,2 and presacral sympathectomy3,4 to uterine-relaxing factor,5 vasodilators,6,7 tranquilizers,8 and hormones9-11 have been tried. Today’s effective therapies against primary dysmenorrhea are an outgrowth of earlier observations of uterine activity and the presence of a menstrual “toxin.” That toxin was later identified as prostaglandin.
Endometrial prostaglandin production is tied to changes throughout the menstrual cycle. Prostaglandin is stored in the endometrium as it thickens in preparation for implantation or menstruation. With the onset of menstruation, preformed prostaglandins are liberated and large amounts of arachidonic acid are released from the cell walls of sloughed endometrial cells. This large increase in arachidonic acid substrate results in a tremendous rise in prostaglandin production, which augments the supplies of preformed prostaglandins liberated from the sloughed endometrial cells.
The causative role of prostaglandin F2α in dysmenorrhea was confirmed when researchers triggered dysmenorrhea-like pain and uterine activity after intravenous (IV) injection of prostaglandins.12 (Current evidence indicates that women with primary dysmenorrhea make 2 to 7 times the normal amount of prostaglandin F2α.) Excess prostaglandins also may be responsible for the smooth-muscle activity noted in the gastrointestinal (GI) tracts of these women. Hypermobility of the gut may be responsible for the frequent coexistence of nausea, vomiting, and diarrhea in these patients. In addition, prostaglandins appear to act as initiators and potentiators of nociceptive pain signals, further contributing to the symptoms of dysmenorrhea.
In 1967, Pickles demonstrated that prostaglandin levels were lower during anovulatory cycles, prompting the use of oral contraceptives (OCs) to suppress ovulation and relieve menstrual pain.13,14 Although this approach is usually successful, not all women want to—or can—use OCs. NSAIDs more directly alter the physiologic sequence leading to discomfort by inhibiting the production and/or action of prostaglandins. Moreover, NSAIDs generally are well-tolerated and need only be taken at the time of menstruation. While OCs act to reduce the substrate available to the reaction, NSAIDs act to block the pathway at 2 later enzymatic steps.
In 1979, Jacobson et al reported successful pain relief in 64% to 100% of patients from 16 studies of NSAIDs in dysmenorrhea.15 Unfortunately, few of those studies were double-blinded, and many failed to report the incidence of side effects. Dingfelder evaluated 23 trials published from 1970 to 1980 and found a 67% to 86% rate of pain relief.16 In a more thorough review, Owen presented data from 51 reports and attempted to analyze the diverse methods, designs, and outcomes.17 She found an 87% rate of “excellent” pain relief for the fenamates versus 56%, 68%, and 56% for ibuprofen, indomethacin, and naproxen, respectively. Unfortunately, she lumped together 2 different drugs (tolfenamic and mefenamic acids) and misinterpreted some primarily methodological reports. More recent attempts to analyze existing studies have failed to further clarify the issue.18,19
Prostaglandins are made throughout the body and are important autocrine and paracrine regulators of cellular and organ function. As depicted below, the main substrate for their production is arachidonic acid, a major constituent of cell walls. Under some circumstances, phospholipase A2 also can be used as a substrate for prostaglandin production.
Cyclooxygenase, also called prostaglandin H synthase, is the first enzymatic step in the conversion of arachidonic acid into prostaglandins. This enzyme folds the arachidonic acid molecule (cyclization) and oxygenates it to produce prostaglandin H2 (PGH2).
All other members of the prostaglandin family are then formed from PGH2. Arachidonic acid also is the substrate for the production of leukotrienes and 5-hydroxyeicosatetraenoic acid (5-HETE) through the 5-lipooxygenase pathway. Like prostaglandins F2α and E2, the products of the lipooxygenase pathway are potent vasoconstrictors and stimulators of uterine contractions.—Roger P. Smith, MD, and Jeffrey Ellis, MD
Increased uterine activity was first hypothesized as a cause of dysmenorrhea in 1932. By the late 1930s, objective findings began to support that hypothesis.1 The correlation between uterine activity and menstrual pain was strengthened when Jacobson et al studied simultaneous electrical and mechanical changes within the uterus.2,3 Using an intrauterine air-filled balloon system, Wilson and Kurzrok also noted the relationship between maximal uterine activity and pain.4,5 Despite the strength of these investigations, few changes occurred in the way dysmenorrhea was viewed or treated.
In the late 1940s, Liessé demonstrated that women with dysmenorrhea not only had a greater degree of uterine electrical and mechanical activity, but that this activity correlated with the pain of menstruation.6 Liessé found minimal activity between pains and as many as 30 irregular electrical discharges per second during pain, suggesting a cause (electrical) for dysmenorrhea but offering no clue to the underlying physiologic disturbance that might account for it.
The most detailed and influential studies of dysmenorrhea and uterine activity came in 1947 in a trial conducted by Woodbury.7 His findings of a direct correlation between pressure, pattern of contractions, resting tone, and pain became a standard reference.
After Woodbury, the stage was set for a connection to be made between uterine activity and prostaglandins. That happened in 1965, when Pickles reported elevated levels of prostaglandin F2αin the menstrual fluid of dysmenorrheic women.8
During the past 2 decades, more sophisticated analytic techniques have been applied to intrauterine pressure data,9,10 and strong correlations between uterine activity and pain have been reported.11,12 The basic assertion that menstrual pain is caused by increased intrauterine pressure, poor relaxation, and more frequent, irregular contractions appears to be valid.—Roger P. Smith, MD, and Jeffrey Ellis, MD
REFERENCES
1. Novac E, Reynolds SRM. The cause of primary dysmenorrhea. JAMA. 1932;99:1466.-
2. Jacobson E, Lackner JE, Sinykin MB. Electrical and mechanical activity of the human non-pregnant uterus. Am J Obstet Gynecol. 1939;38:1008.-
3. Jacobson E, Lackner JE, Sinykin MB. Activity of the human non-pregnant uterus. Am J Physiol. 1940;53:407.-
4. Wilson L, Kurzrok R. Studies on the motility of the human uterus in vivo. Endocrinology. 1938;23:79.-
5. Wilson L, Kurzrok R. Uterine contractility in functional dysmenorrhea. Endocrinology. 1940;27:23.-
6. Liessé A. L’Activité électrique de l’uterus dans la dysmenorrhee functionnelle. Gynec et Obstet. 1948;47:850.-
7. Woodbury RA, Torpin R, Child GP, Watson H, Jarboe M. Myometrial physiology and its relation to pelvic pain. JAMA. 1947;134:1081-1085.
8. Pickles VR, Hall WJ, Best FA, Smith GN. Prostaglandins in endometrium and menstrual fluid from normal and dysmenorrheic subjects. J Obstet Gynaecol Br Comm. 1965;72:185.-
9. Smith RP. Intrauterine pressure analysis in nonpregnant dysmenorrheic women. Med Instr. 1984;185:137-139.
10. Smith RP. Distribution analysis of intrauterine pressure in nonpregnant dysmenorrheic women. Am J Obstet Gynecol. 1984;150:271-273.
11. Smith RP. The dynamics of nonsteroidal anti-inflammatory therapy for primary dysmenorrhea. Obstet Gynecol. 1987;70:785-788.
12. Smith RP, Powell JR. Simultaneous objective and subjective evaluation of meclofenamate sodium in the treatment of primary dysmenorrhea. Am J Obstet Gynecol. 1987;157:611-616.
Classes of NSAIDs
Although aspirin was synthesized in 1853 and incorporated into medical practice in 1899, its history goes back even farther. That fact—along with the introduction of newer agents—ensured that NSAIDs became the mainstays of medical therapy for fever, pain, and inflammation. In the United States, NSAIDs are among the most widely prescribed drugs, with more than 70 million prescriptions and more than 30 billion over-the-counter tablets sold each year.20 Most of their therapeutic effects come from their ability to inhibit the production of prostaglandins.21
Interestingly, some drugs with the ability to inhibit prostaglandin synthesis have little clinical usefulness. Some have weak antiprostaglandin activity, require metabolic transformation to become active, or have side effects that limit their usefulness. While these drugs can be used to treat dysmenorrhea, they generally have been replaced by more effective agents.
There are 2 broad classes of NSAIDs: enolic acids and carboxylic acids. Each class can be further subcategorized (Table 1).
Enolic acids. With the exception of the newer cyclooxygenase-2 (COX-2) selective agents, drugs of the enolic-acid type are primarily type II inhibitors of prostaglandin synthesis. That means they impede the isomerase/reductase step in the formation of prostaglandins E2 (PGE2) and F2α (PGF2α). The most frequently used agents in the enolic-acid group are phenylbutazone and piroxicam.
Phenylbutazone was discovered in the 19th century during a search for a substitute for quinine. (Quinine had become popular for the treatment of fever; however, uncontrolled cutting of the Peruvian cinchona tree dramatically increased its cost.) While phenylbutazone is an effective shortterm analgesic for musculoskeletal pain (through antiprostaglandin activity), its relative toxicity has limited its use in dysmenorrhea and general therapy.
Piroxicam has a long half-life (50 hours), making once-daily dosing possible. Its action as an anti-inflammatory drug for the treatment of arthritis is well-established, but its use as an analgesic for acute pain therapy or for dysmenorrhea has not been fully evaluated. Based on the pharmacodynamics of drug absorption and action, one would anticipate its efficacy in that regard to be poor. In general, drugs in the pyrazolone group have a higher incidence of blood dyscrasias, limiting their broad utility.
Celecoxib is structurally similar to phenylbutazone and was the first selective COX-2 inhibitor approved by the Food and Drug Administration (FDA). It has been studied in dental pain models and the treatment of osteoarthritis. In these trials, celecoxib performed as well as naproxen and slow-release diclofenac, but with fewer GI side effects. No data on its use in dysmenorrhea is available.
Chemically related but less similar to the enolic acids is refecoxib. Like celecoxib, it has been studied in the treatment of osteoarthritis, where it was comparable in efficacy to ibuprofen and diclofenac, but with side-effect rates similar to placebo therapy. In studies of women with primary dysmenorrhea, rofecoxib has proved to be statistically superior to placebo but indistinguishable from naproxen (Figure 1).22 Peak blood levels are achieved in 2 to 3 hours (delayed by 1 to 2 hours by a fatty meal), but a steady state is not achieved until day 4 of continuous therapy. When the drug is used to treat women who have a rapid onset of symptoms, the significance of this delay is unclear but is a potential drawback. In addition, the dosage of rofecoxib for the treatment of pain or dysmenorrhea is generally much larger than that required for the treatment of arthritis. Thus, the risk of side effects may be increased.
A third selective COX-2 inhibitor, meloxicam, was introduced into the US market solely for the treatment of osteoarthritis. This drug is marketed on the basis of its more favorable side-effect profile rather than its selectivity in blocking the COX-2 isoform.
Carboxylic acids. The first of the carboxylic acid subgroups are the salicylic acids. The use of salicylates derived from the bark or leaves of the Salic alba or S. fragilis dates back to Biblical times. Salicylates were formally introduced into medical use in 1763 by the Reverend Edmund Stone.23
The relatively low potency of aspirin for reducing prostaglandin synthesis in the uterus limits its clinical utility in preventing moderate or severe dysmenorrhea. In contrast, diflunisal has a long half-life, making twice-daily dosing possible. However, its slow onset of action limits use for most patients with menstrual pain.
The indoleacetic acid subgroup offers increased potency against dysmenorrhea. Most of these drugs have a direct effect rather than requiring metabolism into an active form.
Indomethacin was one of the first NSAIDs widely used to treat dysmenorrhea, but a moderate incidence of side effects limits its use—and that of most of the other drugs in this family.
No NSAID completely eliminates gastric cyclooxygenase activity.
The most commonly used drugs for dysmenorrhea come from the 2 remaining carboxylate groups: arylalkanoic acids (propionic acid derivatives) and anthranilic acids (fenamates). Of the propionic acid derivatives currently available, ibuprofen and naproxen are commonly used for dysmenorrhea. Other drugs of this class have been used for pain relief or arthritis therapy, but are not currently FDA-approved for dysmenorrhea. The subset of drugs that are phenylpropionic acid derivatives are associated with a higher incidence of GI side effects and skin reactions.
Mefenamic acid was the first alternative synthesized in an effort to reduce the gastric irritation caused by acetylsalicylic acid.24 Mefenamic acid and meclofenamate sodium—both fenamates—are potent prostaglandin synthetase inhibitors. In addition, they have been shown to antagonize already formed prostaglandins, providing a dual mode of action.25-28 This ability to block the action of existing prostaglandins produces a more rapid onset of uterine relaxation. Some of the first studies of NSAIDs in dysmenorrhea used these agents.29,30 In fact, they are some of the most thoroughly investigated drugs for the treatment of dysmenorrhea, shown to be consistently effective in reducing its subjective discomfort.31-35
In the U.S., mefenamic acid was one of the first drugs approved for dysmenorrhea, and clinical studies have shown meclofenamate to be very effective in improving symptoms and altering the underlying pathophysiology.36,37 The dual mechanism of action likely gives these agents an edge in efficacy, although no clinical trials have been initiated to evaluate this presumed advantage. Intrauterine pressure changes have been documented as soon as 15 minutes after administration of the medications, suggesting a very rapid onset of action (obviating the need for preloading). In addition, in vitro studies have demonstrated meclofenamate’s ability to inhibit the activity of 5-lipooxygenase, unlike members of the propionic acid group, which have little or no inhibitory ability.38,39 The clinical significance of inhibiting the production of the extremely potent leukotrienes has yet to be fully explored.
TABLE 1
Families of NSAIDs
Family | Example |
---|---|
ENOLIC ACIDS | |
PYRAZOLONES | |
Oxyphenbutazone | Azolid** |
Phenylbutazone | Butazolidin** |
Nabumetone | Relafen |
Celecoxib | Celebrex |
Rofecoxib* | Vioxx |
OXICAMS | |
Piroxicam | Feldene, Piroxicam |
Meloxicam | Mobic |
CARBOXYLIC ACIDS | |
SALICYLIC ACIDS | |
Acetylsalicylic acid | Aspirin (various) |
Diflunisal | Dolobid |
Salicylate | Disalcid, Trilisate |
INDOLEACETIC ACIDS | |
Diclofenac potassium | Cataflam |
Diclofenac sodium | Voltaren, Arthrotec (combined with misoprostol) |
Etodolac | Lodine |
Indomethacin | Indocin |
Ketorolac tromethamine | Acular, Toradol |
Sulindac | Clinoril, Sulindac |
Tolmetin | Tolectin, Tolmetin |
PROPIONIC ACIDS | |
Fenoprofen calcium | Fenoprofen |
Flurbiprofen | Flurbiprofen |
Ibuprofen* | Motrin |
Ketoprofen | Orudis, Oruvail, Ketoprofen |
Naproxen sodium* | Aleve, Anaprox, Naprelan |
Naproxen* | Naprosyn |
FENAMATES | |
Meclofenamate sodium* | Meclofenamate |
Mefenamic acid | Ponstel |
*FDA-approved for primary dysmenorrhea | |
**No longer available | |
Adapted from: Smith RP.Gynecology in Primary Care. Baltimore, Md: Williams and Wilkins; 1996:399. |
FIGURE 1 Comparison of rofecoxib, naproxen, and placebo in treatment of primary dysmenorrhea
Reprinted with permission from The American College of Obstetricians and Gynecologists. Morrison BW, Daniels SE, Kotey P, Cantu N, Seidenberg B. Rofecoxib, a specific cyclooxygenase-2 inhibitor, in primary dysmenorrhea: a randomized-controlled trial. Obstet Gynecol. 1999;94:504-508.
COX-2 inhibitors
Although the short-term efficacy and safety of new selective COX-2 inhibitors appear to be good, several concerns remain. Despite a decrease in the incidence of GI side effects with these agents, their use by patients with active GI ulceration, infection with Helicobacter pylori, or inflammatory bowel disease has not been adequately studied. Indeed, recent studies suggest that, at therapeutic concentrations, no NSAID—not even the selective COX-2 inhibitors—completely eliminates gastric cyclooxygenase activity.40
In addition, questions have been raised about the speed and efficacy of the selective COX-2 inhibitors for the management of acute pain, compared with conventional NSAIDs.41 When used for postoperative analgesia, these agents theoretically could retard wound healing because of the role that COX-2 plays in healing and neovascularization. As more data emerge about the physiologic functions of COX-1 and -2 (Table 2), there are growing concerns that COX-2 is not restricted to inflammation and pathology, suggesting the possibility of unanticipated adverse effects associated with its use. For example, there is evidence of constitutive expression of COX-2 in the kidney and brain, and essential physiological functions in ovulation and implantation.42 In the treatment of dysmenorrhea, the increased cost of these drugs over the more commonly used agents, along with the lack of clinical efficacy studies, suggests a second-line role.
Like most NSAIDs, COX-2 inhibitors fall into pregnancy category C. Because of the risk of premature closure of the ductus arteriosus, they should not be used in the third trimester of pregnancy. In addition, drug levels in human milk mimic those in serum, so the decision to use these agents in nursing mothers must be made carefully.
Studies over the past 10 years have revealed that the cyclooxygenase enzyme (COX) is found in 2 isomeric forms, known as COX-1 and COX-2.1 Initial investigations suggested that COX-1 was present in most tissues and responsible for the homeostatic production of arachidonic acid metabolites. The COX-2 enzyme was thought to be induced in response to inflammatory stimuli such as cytokines and bacterial lipopolysaccharides, rather than expressed under normal cellular function. Thus, the COX-2 form was thought to be responsible for the large amounts of prostaglandins associated with inflammation. It was further hypothesized that COX-2 used intracellular arachidonic acid as a substrate almost exclusively, while COX-1 could use phospholipase A2 as an extracellular substrate under some conditions.2
Recent data suggest that COX-1 and -2 are more complex than originally assumed. There is increasing evidence that COX-2 is constitutively expressed in the brain, kidneys, and pancreatic islet cells and plays a role in intestinal tolerance to dietary antigens, ulcer healing, ovulation, and implantation. Transgenic mice with deletions of the COX-2 enzyme maintain the inflammatory response when only COX-1 is present.3
In the reproductive tract, COX-2 expression increases substantially in midcycle because of the surge in luteinizing hormone (LH). COX-2 and the resulting prostaglandins (released from granulosa cells) are thought to play an important role in rupture of the follicle.4,5 With fertilization, COX-2 expression increases in the endometrium surrounding the implantation site.6 The resultant prostaglandins are important for successful implantation and angiogenesis. Interestingly, transgenic mice that lack the COX-2 enzyme are infertile, while those missing only the COX-1 enzyme have normal reproduction.7,8
Studies also have demonstrated a rapid increase in COX-2 expression in the placenta and amnion immediately before and during labor.9 It is well established that prostaglandins have a pivotal role in myometrial contraction10 and inhibition of COX-2 has been shown to delay labor.11
The COX-1 and -2 enzymes share approximately 60% homology.12 Both have a long, narrow channel that is the active site of arachidonic acid folding and oxygenation. The critical difference between the 2 isoenzymes occurs at position 523, where the COX-1 enzyme has an isoleucine while COX-2 has a valine.13 This substitution causes the channel in the COX-2 form to be 17% wider; it also provides a side pocket that increases the volume of the active site by 8%. Drugs that are designed to block the COX-2 enzyme take advantage of this difference in channel size—they are too large to fit the normal channel. Nonselective NSAIDs are small enough to block the channel in both isoenzymes while, at least in theory, the selective agents can block only the larger channel.14 Most COX-2 inhibitors also exhibit some action against the COX-1 isoform.—Roger P. Smith, MD, and Jeffrey Ellis, MD
REFERENCES
1. Smith WL, Garavito RM, DeWitt DL. Prostaglandin endoperoxide H synthase (cyclooxygenase)-1 and -2. J Biol Chem. 1996;271:33157.-
2. Herschman HR. Prostaglandin synthase 2. Biochem Biophys Acta. 1996;1299:125-140.
3. Wallace JL, Bak A, McKnight W, Asfaha S, Sharkey KA, MacNaughton WK. Cyclooxygenase 1 contributes to inflammatory responses in rats and mice: implications for gastrointestinal toxicity. Gastroenterology. 1998;115:101-109.
4. Richards JS, Fitzpatrick SL, Clemens JW, Morris JK, Alliston T, Sirois J. Ovarian cell differentiation: a cascade of multiple hormones, cellular signals, and regulated genes. Recent Prog Horm Res. 1995;50:223-254.
5. Akil M, Amos RS, Stewart P. Infertility may sometimes be associated with NSAID consumption. Br J Rheumatol. 1996;35:76-78.
6. Chakraborty I, Das SK, Wang J, Dey SK. Developmental expression of the cyclo-oxygenase-1 and cyclooxygenase-2 genes in the peri-implantation mouse uterus and their differential regulation by the blastocyst and ovarian steroids. J Mol Endocrinol. 1996;16:107-122.
7. Lim H, Paria BC, Das SK, Dinchuk JE, Langenbach R, Trzaskos JM, et al. Multiple female reproductive failures in cyclooxygenase 2-deficient mice. Cell. 1997;91:197-208.
8. Langenbach R, Loftin C, Lee C, Tiano H. Cyclooxygenase knockout mice: models for elucidating isoform-specific functions. Biochem Pharmacol. 1999;58:1237-1246.
9. Gibb W, Sun M. Localization of prostaglandin H synthase type 2 protein and mRNA in term human fetal membranes and decidua. J Endocrinol. 1996;150:497-503.
10. O’Brien WF. The role of prostaglandins in labor and delivery. Clin Perinatol. 1995;22:973-984.
11. Mitchell MD, Romero RJ, Edwin SS, Trautman MS. Prostaglandins and parturition. Reprod Fertil Dev. 1995;7:623-632.
12. Kurumbail RG, Stevens AM, Gierse JK, et al. Structural basis for selective inhibition of cyclooxygenase-2 by anti-inflammatory agents. Nature. 1996;384:644-4.(Published correction appears in Nature. 1997;385:555.)
13. Gierse JK, McDonald JJ, Hauser SD, Rangwala SH, Koboldt CM, Seibert K. A single amino acid difference between cyclooxygenase-1 (COX-1) and -2 (COX-2) reverses the selectivity of COX-2 specific inhibitors. J Biol Chem. 1996;271:15810.-
14. Lanzo CA, Beechem JM, Talley J, Marnett LJ. Investigation of the binding of isoform-selective inhibitors to prostaglandin endoperoxide synthases using fluorescence spectroscopy. Biochemistry. 1998;37:217-226.
TABLE 2
Comparison of COX-1 and COX-2 in human tissues
Characteristic | COX-1 | COX-2 |
---|---|---|
Tonic expression | High | Low |
Inducibility | Low | High |
Predominant location | All (stomach, kidney, platelets, vasculature) | Sites of inflammation (neoplastic tissue, small intestine, ovary, uterus, brain) |
Function | Homeostasis | Inflammation and repair, neoplasia, modulation of immune response |
Conclusion
It is apparent from the multitude of published studies and the breadth of clinical experience with NSAID therapy for primary dysmenorrhea that most of these drugs provide relief for the majority of dysmenorrheic women. The success rates reported from both subjective and objective studies of the use of mefenamic acid in dysmenorrhea support its potential superiority. The physiology of primary dysmenorrhea would suggest that the ability of the fenamates to block the action of preformed prostaglandins—as well as the 5-lipooxygenase pathway—gives them a therapeutic edge. Interestingly, one investigation of the level of selectivity of multiple NSAIDs found that mefenamic acid had a selectivity (preferential COX-2 inhibition) comparable to some of the newest selective COX-2 inhibitors.43 This may account for the low incidence of GI and other side effects reported with mefenamic acid.
The history of NSAIDs has involved the sequential introduction of agents designed to reduce side effects or increase efficacy, often through the modification of existing compounds. Many of these products have failed to meet expectations and have been withdrawn from the market. Notable recent examples include benoxaprofen, suprofen, oxyphenbutazone, and zomepirac.
Thus, it is ironic that mefenamic acid, the first agent introduced to overcome the drawbacks of aspirin, has proved to be so robust in efficacy and tolerability. In addition, it is one of the only agents objectively shown to reduce menstrual blood loss in women with menorrhagia,44-47 and to ease menstrual migraine48 and the physical and emotional symptoms of premenstrual syndrome.49-51 In fact, the combination of dysmenorrhea, premenstrual syndrome, and menorrhagia experienced by many women would seem to support the use of mefenamic acid over other agents.
Unfortunately, no direct comparisons of various drugs have definitively resolved the question of which agent is “best” for the treatment of dysmenorrhea. Until there is further refinement of our knowledge of uterine prostaglandins, menstrual function, and the physiology of dysmenorrhea, it would seem wise to rely on agents that have been studied most extensively.
Dr. Smith reports no financial relationship with any companies whose products are mentioned in this article. Dr. Ellis reports that he is on the speakers’ bureau for First Horizon Pharmaceutical Company.
- Nonsteroidal anti-inflammatory drugs (NSAIDs) can prevent dysmenorrhea, unlike other agents that simply relieve symptoms.
- Although NSAIDs in one form or another have been used for centuries, agents introduced in the past 50 years have significantly improved efficacy and safety profiles.
- A greater understanding of the role of prostaglandins in physiologic and pathophysiologic processes can enhance the selection of appropriate therapeutic agents.
- Some drugs can selectively block the cyclooxygenase-2 (COX-2) isoform of the enzyme instrumental in the production of prostaglandins.
A major shift in the way menstrual pain is viewed and treated took place in the 1970s and ’80s, with a greater understanding of the role of prostaglandins and more effective nonsteroidal anti-inflammatory drugs (NSAIDs). Subjective studies of pain and objective studies of uterine activity established a firm connection between the two. These studies also amply demonstrated the ability of NSAIDs to alter the physiology of dysmenorrhea, making it possible to prevent—rather than simply relieve—pain.
Yet, these agents still are not universally used in the treatment of dysmenorrhea, despite more than 20 years of experience with them. Moreover, the introduction of new NSAIDs has clouded rather than clarified the issue of their relative efficacy. Drugs that are welldesigned for the suppression of chronic inflammation (e.g., arthritis therapies) are not very effective for dysmenorrhea, and vice versa. Even so, it is possible to apply the findings of published studies and an understanding of the pathophysiology of dysmenorrhea to demystify the range of options.
The therapeutic effects of NSAIDs come from their ability to inhibit the production of prostaglandin.
A brief history
The term “dysmenorrhea” is derived from a Greek root meaning “difficult monthly flow,” but it did not make its appearance in the English language until about 1810. Therapies for dysmenorrhea ranged from the plausible and somewhat effective to the outlandish and useless. Everything from cauterizing the middle turbinate of the nose,1 exercise programs,2 and presacral sympathectomy3,4 to uterine-relaxing factor,5 vasodilators,6,7 tranquilizers,8 and hormones9-11 have been tried. Today’s effective therapies against primary dysmenorrhea are an outgrowth of earlier observations of uterine activity and the presence of a menstrual “toxin.” That toxin was later identified as prostaglandin.
Endometrial prostaglandin production is tied to changes throughout the menstrual cycle. Prostaglandin is stored in the endometrium as it thickens in preparation for implantation or menstruation. With the onset of menstruation, preformed prostaglandins are liberated and large amounts of arachidonic acid are released from the cell walls of sloughed endometrial cells. This large increase in arachidonic acid substrate results in a tremendous rise in prostaglandin production, which augments the supplies of preformed prostaglandins liberated from the sloughed endometrial cells.
The causative role of prostaglandin F2α in dysmenorrhea was confirmed when researchers triggered dysmenorrhea-like pain and uterine activity after intravenous (IV) injection of prostaglandins.12 (Current evidence indicates that women with primary dysmenorrhea make 2 to 7 times the normal amount of prostaglandin F2α.) Excess prostaglandins also may be responsible for the smooth-muscle activity noted in the gastrointestinal (GI) tracts of these women. Hypermobility of the gut may be responsible for the frequent coexistence of nausea, vomiting, and diarrhea in these patients. In addition, prostaglandins appear to act as initiators and potentiators of nociceptive pain signals, further contributing to the symptoms of dysmenorrhea.
In 1967, Pickles demonstrated that prostaglandin levels were lower during anovulatory cycles, prompting the use of oral contraceptives (OCs) to suppress ovulation and relieve menstrual pain.13,14 Although this approach is usually successful, not all women want to—or can—use OCs. NSAIDs more directly alter the physiologic sequence leading to discomfort by inhibiting the production and/or action of prostaglandins. Moreover, NSAIDs generally are well-tolerated and need only be taken at the time of menstruation. While OCs act to reduce the substrate available to the reaction, NSAIDs act to block the pathway at 2 later enzymatic steps.
In 1979, Jacobson et al reported successful pain relief in 64% to 100% of patients from 16 studies of NSAIDs in dysmenorrhea.15 Unfortunately, few of those studies were double-blinded, and many failed to report the incidence of side effects. Dingfelder evaluated 23 trials published from 1970 to 1980 and found a 67% to 86% rate of pain relief.16 In a more thorough review, Owen presented data from 51 reports and attempted to analyze the diverse methods, designs, and outcomes.17 She found an 87% rate of “excellent” pain relief for the fenamates versus 56%, 68%, and 56% for ibuprofen, indomethacin, and naproxen, respectively. Unfortunately, she lumped together 2 different drugs (tolfenamic and mefenamic acids) and misinterpreted some primarily methodological reports. More recent attempts to analyze existing studies have failed to further clarify the issue.18,19
Prostaglandins are made throughout the body and are important autocrine and paracrine regulators of cellular and organ function. As depicted below, the main substrate for their production is arachidonic acid, a major constituent of cell walls. Under some circumstances, phospholipase A2 also can be used as a substrate for prostaglandin production.
Cyclooxygenase, also called prostaglandin H synthase, is the first enzymatic step in the conversion of arachidonic acid into prostaglandins. This enzyme folds the arachidonic acid molecule (cyclization) and oxygenates it to produce prostaglandin H2 (PGH2).
All other members of the prostaglandin family are then formed from PGH2. Arachidonic acid also is the substrate for the production of leukotrienes and 5-hydroxyeicosatetraenoic acid (5-HETE) through the 5-lipooxygenase pathway. Like prostaglandins F2α and E2, the products of the lipooxygenase pathway are potent vasoconstrictors and stimulators of uterine contractions.—Roger P. Smith, MD, and Jeffrey Ellis, MD
Increased uterine activity was first hypothesized as a cause of dysmenorrhea in 1932. By the late 1930s, objective findings began to support that hypothesis.1 The correlation between uterine activity and menstrual pain was strengthened when Jacobson et al studied simultaneous electrical and mechanical changes within the uterus.2,3 Using an intrauterine air-filled balloon system, Wilson and Kurzrok also noted the relationship between maximal uterine activity and pain.4,5 Despite the strength of these investigations, few changes occurred in the way dysmenorrhea was viewed or treated.
In the late 1940s, Liessé demonstrated that women with dysmenorrhea not only had a greater degree of uterine electrical and mechanical activity, but that this activity correlated with the pain of menstruation.6 Liessé found minimal activity between pains and as many as 30 irregular electrical discharges per second during pain, suggesting a cause (electrical) for dysmenorrhea but offering no clue to the underlying physiologic disturbance that might account for it.
The most detailed and influential studies of dysmenorrhea and uterine activity came in 1947 in a trial conducted by Woodbury.7 His findings of a direct correlation between pressure, pattern of contractions, resting tone, and pain became a standard reference.
After Woodbury, the stage was set for a connection to be made between uterine activity and prostaglandins. That happened in 1965, when Pickles reported elevated levels of prostaglandin F2αin the menstrual fluid of dysmenorrheic women.8
During the past 2 decades, more sophisticated analytic techniques have been applied to intrauterine pressure data,9,10 and strong correlations between uterine activity and pain have been reported.11,12 The basic assertion that menstrual pain is caused by increased intrauterine pressure, poor relaxation, and more frequent, irregular contractions appears to be valid.—Roger P. Smith, MD, and Jeffrey Ellis, MD
REFERENCES
1. Novac E, Reynolds SRM. The cause of primary dysmenorrhea. JAMA. 1932;99:1466.-
2. Jacobson E, Lackner JE, Sinykin MB. Electrical and mechanical activity of the human non-pregnant uterus. Am J Obstet Gynecol. 1939;38:1008.-
3. Jacobson E, Lackner JE, Sinykin MB. Activity of the human non-pregnant uterus. Am J Physiol. 1940;53:407.-
4. Wilson L, Kurzrok R. Studies on the motility of the human uterus in vivo. Endocrinology. 1938;23:79.-
5. Wilson L, Kurzrok R. Uterine contractility in functional dysmenorrhea. Endocrinology. 1940;27:23.-
6. Liessé A. L’Activité électrique de l’uterus dans la dysmenorrhee functionnelle. Gynec et Obstet. 1948;47:850.-
7. Woodbury RA, Torpin R, Child GP, Watson H, Jarboe M. Myometrial physiology and its relation to pelvic pain. JAMA. 1947;134:1081-1085.
8. Pickles VR, Hall WJ, Best FA, Smith GN. Prostaglandins in endometrium and menstrual fluid from normal and dysmenorrheic subjects. J Obstet Gynaecol Br Comm. 1965;72:185.-
9. Smith RP. Intrauterine pressure analysis in nonpregnant dysmenorrheic women. Med Instr. 1984;185:137-139.
10. Smith RP. Distribution analysis of intrauterine pressure in nonpregnant dysmenorrheic women. Am J Obstet Gynecol. 1984;150:271-273.
11. Smith RP. The dynamics of nonsteroidal anti-inflammatory therapy for primary dysmenorrhea. Obstet Gynecol. 1987;70:785-788.
12. Smith RP, Powell JR. Simultaneous objective and subjective evaluation of meclofenamate sodium in the treatment of primary dysmenorrhea. Am J Obstet Gynecol. 1987;157:611-616.
Classes of NSAIDs
Although aspirin was synthesized in 1853 and incorporated into medical practice in 1899, its history goes back even farther. That fact—along with the introduction of newer agents—ensured that NSAIDs became the mainstays of medical therapy for fever, pain, and inflammation. In the United States, NSAIDs are among the most widely prescribed drugs, with more than 70 million prescriptions and more than 30 billion over-the-counter tablets sold each year.20 Most of their therapeutic effects come from their ability to inhibit the production of prostaglandins.21
Interestingly, some drugs with the ability to inhibit prostaglandin synthesis have little clinical usefulness. Some have weak antiprostaglandin activity, require metabolic transformation to become active, or have side effects that limit their usefulness. While these drugs can be used to treat dysmenorrhea, they generally have been replaced by more effective agents.
There are 2 broad classes of NSAIDs: enolic acids and carboxylic acids. Each class can be further subcategorized (Table 1).
Enolic acids. With the exception of the newer cyclooxygenase-2 (COX-2) selective agents, drugs of the enolic-acid type are primarily type II inhibitors of prostaglandin synthesis. That means they impede the isomerase/reductase step in the formation of prostaglandins E2 (PGE2) and F2α (PGF2α). The most frequently used agents in the enolic-acid group are phenylbutazone and piroxicam.
Phenylbutazone was discovered in the 19th century during a search for a substitute for quinine. (Quinine had become popular for the treatment of fever; however, uncontrolled cutting of the Peruvian cinchona tree dramatically increased its cost.) While phenylbutazone is an effective shortterm analgesic for musculoskeletal pain (through antiprostaglandin activity), its relative toxicity has limited its use in dysmenorrhea and general therapy.
Piroxicam has a long half-life (50 hours), making once-daily dosing possible. Its action as an anti-inflammatory drug for the treatment of arthritis is well-established, but its use as an analgesic for acute pain therapy or for dysmenorrhea has not been fully evaluated. Based on the pharmacodynamics of drug absorption and action, one would anticipate its efficacy in that regard to be poor. In general, drugs in the pyrazolone group have a higher incidence of blood dyscrasias, limiting their broad utility.
Celecoxib is structurally similar to phenylbutazone and was the first selective COX-2 inhibitor approved by the Food and Drug Administration (FDA). It has been studied in dental pain models and the treatment of osteoarthritis. In these trials, celecoxib performed as well as naproxen and slow-release diclofenac, but with fewer GI side effects. No data on its use in dysmenorrhea is available.
Chemically related but less similar to the enolic acids is refecoxib. Like celecoxib, it has been studied in the treatment of osteoarthritis, where it was comparable in efficacy to ibuprofen and diclofenac, but with side-effect rates similar to placebo therapy. In studies of women with primary dysmenorrhea, rofecoxib has proved to be statistically superior to placebo but indistinguishable from naproxen (Figure 1).22 Peak blood levels are achieved in 2 to 3 hours (delayed by 1 to 2 hours by a fatty meal), but a steady state is not achieved until day 4 of continuous therapy. When the drug is used to treat women who have a rapid onset of symptoms, the significance of this delay is unclear but is a potential drawback. In addition, the dosage of rofecoxib for the treatment of pain or dysmenorrhea is generally much larger than that required for the treatment of arthritis. Thus, the risk of side effects may be increased.
A third selective COX-2 inhibitor, meloxicam, was introduced into the US market solely for the treatment of osteoarthritis. This drug is marketed on the basis of its more favorable side-effect profile rather than its selectivity in blocking the COX-2 isoform.
Carboxylic acids. The first of the carboxylic acid subgroups are the salicylic acids. The use of salicylates derived from the bark or leaves of the Salic alba or S. fragilis dates back to Biblical times. Salicylates were formally introduced into medical use in 1763 by the Reverend Edmund Stone.23
The relatively low potency of aspirin for reducing prostaglandin synthesis in the uterus limits its clinical utility in preventing moderate or severe dysmenorrhea. In contrast, diflunisal has a long half-life, making twice-daily dosing possible. However, its slow onset of action limits use for most patients with menstrual pain.
The indoleacetic acid subgroup offers increased potency against dysmenorrhea. Most of these drugs have a direct effect rather than requiring metabolism into an active form.
Indomethacin was one of the first NSAIDs widely used to treat dysmenorrhea, but a moderate incidence of side effects limits its use—and that of most of the other drugs in this family.
No NSAID completely eliminates gastric cyclooxygenase activity.
The most commonly used drugs for dysmenorrhea come from the 2 remaining carboxylate groups: arylalkanoic acids (propionic acid derivatives) and anthranilic acids (fenamates). Of the propionic acid derivatives currently available, ibuprofen and naproxen are commonly used for dysmenorrhea. Other drugs of this class have been used for pain relief or arthritis therapy, but are not currently FDA-approved for dysmenorrhea. The subset of drugs that are phenylpropionic acid derivatives are associated with a higher incidence of GI side effects and skin reactions.
Mefenamic acid was the first alternative synthesized in an effort to reduce the gastric irritation caused by acetylsalicylic acid.24 Mefenamic acid and meclofenamate sodium—both fenamates—are potent prostaglandin synthetase inhibitors. In addition, they have been shown to antagonize already formed prostaglandins, providing a dual mode of action.25-28 This ability to block the action of existing prostaglandins produces a more rapid onset of uterine relaxation. Some of the first studies of NSAIDs in dysmenorrhea used these agents.29,30 In fact, they are some of the most thoroughly investigated drugs for the treatment of dysmenorrhea, shown to be consistently effective in reducing its subjective discomfort.31-35
In the U.S., mefenamic acid was one of the first drugs approved for dysmenorrhea, and clinical studies have shown meclofenamate to be very effective in improving symptoms and altering the underlying pathophysiology.36,37 The dual mechanism of action likely gives these agents an edge in efficacy, although no clinical trials have been initiated to evaluate this presumed advantage. Intrauterine pressure changes have been documented as soon as 15 minutes after administration of the medications, suggesting a very rapid onset of action (obviating the need for preloading). In addition, in vitro studies have demonstrated meclofenamate’s ability to inhibit the activity of 5-lipooxygenase, unlike members of the propionic acid group, which have little or no inhibitory ability.38,39 The clinical significance of inhibiting the production of the extremely potent leukotrienes has yet to be fully explored.
TABLE 1
Families of NSAIDs
Family | Example |
---|---|
ENOLIC ACIDS | |
PYRAZOLONES | |
Oxyphenbutazone | Azolid** |
Phenylbutazone | Butazolidin** |
Nabumetone | Relafen |
Celecoxib | Celebrex |
Rofecoxib* | Vioxx |
OXICAMS | |
Piroxicam | Feldene, Piroxicam |
Meloxicam | Mobic |
CARBOXYLIC ACIDS | |
SALICYLIC ACIDS | |
Acetylsalicylic acid | Aspirin (various) |
Diflunisal | Dolobid |
Salicylate | Disalcid, Trilisate |
INDOLEACETIC ACIDS | |
Diclofenac potassium | Cataflam |
Diclofenac sodium | Voltaren, Arthrotec (combined with misoprostol) |
Etodolac | Lodine |
Indomethacin | Indocin |
Ketorolac tromethamine | Acular, Toradol |
Sulindac | Clinoril, Sulindac |
Tolmetin | Tolectin, Tolmetin |
PROPIONIC ACIDS | |
Fenoprofen calcium | Fenoprofen |
Flurbiprofen | Flurbiprofen |
Ibuprofen* | Motrin |
Ketoprofen | Orudis, Oruvail, Ketoprofen |
Naproxen sodium* | Aleve, Anaprox, Naprelan |
Naproxen* | Naprosyn |
FENAMATES | |
Meclofenamate sodium* | Meclofenamate |
Mefenamic acid | Ponstel |
*FDA-approved for primary dysmenorrhea | |
**No longer available | |
Adapted from: Smith RP.Gynecology in Primary Care. Baltimore, Md: Williams and Wilkins; 1996:399. |
FIGURE 1 Comparison of rofecoxib, naproxen, and placebo in treatment of primary dysmenorrhea
Reprinted with permission from The American College of Obstetricians and Gynecologists. Morrison BW, Daniels SE, Kotey P, Cantu N, Seidenberg B. Rofecoxib, a specific cyclooxygenase-2 inhibitor, in primary dysmenorrhea: a randomized-controlled trial. Obstet Gynecol. 1999;94:504-508.
COX-2 inhibitors
Although the short-term efficacy and safety of new selective COX-2 inhibitors appear to be good, several concerns remain. Despite a decrease in the incidence of GI side effects with these agents, their use by patients with active GI ulceration, infection with Helicobacter pylori, or inflammatory bowel disease has not been adequately studied. Indeed, recent studies suggest that, at therapeutic concentrations, no NSAID—not even the selective COX-2 inhibitors—completely eliminates gastric cyclooxygenase activity.40
In addition, questions have been raised about the speed and efficacy of the selective COX-2 inhibitors for the management of acute pain, compared with conventional NSAIDs.41 When used for postoperative analgesia, these agents theoretically could retard wound healing because of the role that COX-2 plays in healing and neovascularization. As more data emerge about the physiologic functions of COX-1 and -2 (Table 2), there are growing concerns that COX-2 is not restricted to inflammation and pathology, suggesting the possibility of unanticipated adverse effects associated with its use. For example, there is evidence of constitutive expression of COX-2 in the kidney and brain, and essential physiological functions in ovulation and implantation.42 In the treatment of dysmenorrhea, the increased cost of these drugs over the more commonly used agents, along with the lack of clinical efficacy studies, suggests a second-line role.
Like most NSAIDs, COX-2 inhibitors fall into pregnancy category C. Because of the risk of premature closure of the ductus arteriosus, they should not be used in the third trimester of pregnancy. In addition, drug levels in human milk mimic those in serum, so the decision to use these agents in nursing mothers must be made carefully.
Studies over the past 10 years have revealed that the cyclooxygenase enzyme (COX) is found in 2 isomeric forms, known as COX-1 and COX-2.1 Initial investigations suggested that COX-1 was present in most tissues and responsible for the homeostatic production of arachidonic acid metabolites. The COX-2 enzyme was thought to be induced in response to inflammatory stimuli such as cytokines and bacterial lipopolysaccharides, rather than expressed under normal cellular function. Thus, the COX-2 form was thought to be responsible for the large amounts of prostaglandins associated with inflammation. It was further hypothesized that COX-2 used intracellular arachidonic acid as a substrate almost exclusively, while COX-1 could use phospholipase A2 as an extracellular substrate under some conditions.2
Recent data suggest that COX-1 and -2 are more complex than originally assumed. There is increasing evidence that COX-2 is constitutively expressed in the brain, kidneys, and pancreatic islet cells and plays a role in intestinal tolerance to dietary antigens, ulcer healing, ovulation, and implantation. Transgenic mice with deletions of the COX-2 enzyme maintain the inflammatory response when only COX-1 is present.3
In the reproductive tract, COX-2 expression increases substantially in midcycle because of the surge in luteinizing hormone (LH). COX-2 and the resulting prostaglandins (released from granulosa cells) are thought to play an important role in rupture of the follicle.4,5 With fertilization, COX-2 expression increases in the endometrium surrounding the implantation site.6 The resultant prostaglandins are important for successful implantation and angiogenesis. Interestingly, transgenic mice that lack the COX-2 enzyme are infertile, while those missing only the COX-1 enzyme have normal reproduction.7,8
Studies also have demonstrated a rapid increase in COX-2 expression in the placenta and amnion immediately before and during labor.9 It is well established that prostaglandins have a pivotal role in myometrial contraction10 and inhibition of COX-2 has been shown to delay labor.11
The COX-1 and -2 enzymes share approximately 60% homology.12 Both have a long, narrow channel that is the active site of arachidonic acid folding and oxygenation. The critical difference between the 2 isoenzymes occurs at position 523, where the COX-1 enzyme has an isoleucine while COX-2 has a valine.13 This substitution causes the channel in the COX-2 form to be 17% wider; it also provides a side pocket that increases the volume of the active site by 8%. Drugs that are designed to block the COX-2 enzyme take advantage of this difference in channel size—they are too large to fit the normal channel. Nonselective NSAIDs are small enough to block the channel in both isoenzymes while, at least in theory, the selective agents can block only the larger channel.14 Most COX-2 inhibitors also exhibit some action against the COX-1 isoform.—Roger P. Smith, MD, and Jeffrey Ellis, MD
REFERENCES
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2. Herschman HR. Prostaglandin synthase 2. Biochem Biophys Acta. 1996;1299:125-140.
3. Wallace JL, Bak A, McKnight W, Asfaha S, Sharkey KA, MacNaughton WK. Cyclooxygenase 1 contributes to inflammatory responses in rats and mice: implications for gastrointestinal toxicity. Gastroenterology. 1998;115:101-109.
4. Richards JS, Fitzpatrick SL, Clemens JW, Morris JK, Alliston T, Sirois J. Ovarian cell differentiation: a cascade of multiple hormones, cellular signals, and regulated genes. Recent Prog Horm Res. 1995;50:223-254.
5. Akil M, Amos RS, Stewart P. Infertility may sometimes be associated with NSAID consumption. Br J Rheumatol. 1996;35:76-78.
6. Chakraborty I, Das SK, Wang J, Dey SK. Developmental expression of the cyclo-oxygenase-1 and cyclooxygenase-2 genes in the peri-implantation mouse uterus and their differential regulation by the blastocyst and ovarian steroids. J Mol Endocrinol. 1996;16:107-122.
7. Lim H, Paria BC, Das SK, Dinchuk JE, Langenbach R, Trzaskos JM, et al. Multiple female reproductive failures in cyclooxygenase 2-deficient mice. Cell. 1997;91:197-208.
8. Langenbach R, Loftin C, Lee C, Tiano H. Cyclooxygenase knockout mice: models for elucidating isoform-specific functions. Biochem Pharmacol. 1999;58:1237-1246.
9. Gibb W, Sun M. Localization of prostaglandin H synthase type 2 protein and mRNA in term human fetal membranes and decidua. J Endocrinol. 1996;150:497-503.
10. O’Brien WF. The role of prostaglandins in labor and delivery. Clin Perinatol. 1995;22:973-984.
11. Mitchell MD, Romero RJ, Edwin SS, Trautman MS. Prostaglandins and parturition. Reprod Fertil Dev. 1995;7:623-632.
12. Kurumbail RG, Stevens AM, Gierse JK, et al. Structural basis for selective inhibition of cyclooxygenase-2 by anti-inflammatory agents. Nature. 1996;384:644-4.(Published correction appears in Nature. 1997;385:555.)
13. Gierse JK, McDonald JJ, Hauser SD, Rangwala SH, Koboldt CM, Seibert K. A single amino acid difference between cyclooxygenase-1 (COX-1) and -2 (COX-2) reverses the selectivity of COX-2 specific inhibitors. J Biol Chem. 1996;271:15810.-
14. Lanzo CA, Beechem JM, Talley J, Marnett LJ. Investigation of the binding of isoform-selective inhibitors to prostaglandin endoperoxide synthases using fluorescence spectroscopy. Biochemistry. 1998;37:217-226.
TABLE 2
Comparison of COX-1 and COX-2 in human tissues
Characteristic | COX-1 | COX-2 |
---|---|---|
Tonic expression | High | Low |
Inducibility | Low | High |
Predominant location | All (stomach, kidney, platelets, vasculature) | Sites of inflammation (neoplastic tissue, small intestine, ovary, uterus, brain) |
Function | Homeostasis | Inflammation and repair, neoplasia, modulation of immune response |
Conclusion
It is apparent from the multitude of published studies and the breadth of clinical experience with NSAID therapy for primary dysmenorrhea that most of these drugs provide relief for the majority of dysmenorrheic women. The success rates reported from both subjective and objective studies of the use of mefenamic acid in dysmenorrhea support its potential superiority. The physiology of primary dysmenorrhea would suggest that the ability of the fenamates to block the action of preformed prostaglandins—as well as the 5-lipooxygenase pathway—gives them a therapeutic edge. Interestingly, one investigation of the level of selectivity of multiple NSAIDs found that mefenamic acid had a selectivity (preferential COX-2 inhibition) comparable to some of the newest selective COX-2 inhibitors.43 This may account for the low incidence of GI and other side effects reported with mefenamic acid.
The history of NSAIDs has involved the sequential introduction of agents designed to reduce side effects or increase efficacy, often through the modification of existing compounds. Many of these products have failed to meet expectations and have been withdrawn from the market. Notable recent examples include benoxaprofen, suprofen, oxyphenbutazone, and zomepirac.
Thus, it is ironic that mefenamic acid, the first agent introduced to overcome the drawbacks of aspirin, has proved to be so robust in efficacy and tolerability. In addition, it is one of the only agents objectively shown to reduce menstrual blood loss in women with menorrhagia,44-47 and to ease menstrual migraine48 and the physical and emotional symptoms of premenstrual syndrome.49-51 In fact, the combination of dysmenorrhea, premenstrual syndrome, and menorrhagia experienced by many women would seem to support the use of mefenamic acid over other agents.
Unfortunately, no direct comparisons of various drugs have definitively resolved the question of which agent is “best” for the treatment of dysmenorrhea. Until there is further refinement of our knowledge of uterine prostaglandins, menstrual function, and the physiology of dysmenorrhea, it would seem wise to rely on agents that have been studied most extensively.
Dr. Smith reports no financial relationship with any companies whose products are mentioned in this article. Dr. Ellis reports that he is on the speakers’ bureau for First Horizon Pharmaceutical Company.
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34. Powell JR, Smith RP. Mefenamic acid (Ponstel) for treating primary spasmodic dysmenorrhea. Curr Ther Res. 1981;29:544.-
35. Roy S. A double-blind comparison of a propionic acid derivative (ibuprofen) and a fenamate (mefenamic acid) in the treatment of dysmenorrhea. Obstet Gynecol. 1983;61:628.-
36. Smith RP, Powell JR. Simultaneous objective and subjective evaluation of meclofenamate sodium in the treatment of primary dysmenorrhea. Am J Obstet Gynecol. 1987;157:611.-
37. Smith RP. The dynamics of nonsteroidal anti-inflammatory therapy for primary dysmenorrhea. Obstet Gynecol. 1987;70:785.-
38. Boctor AM, Eickholt M, Pugsley TA. Meclofenamate sodium is an inhibitor of both the 5-lipooxygenase and cyclooxygenase pathways of the arachidonic acid cascade in vitro. Prostaglandins, Leukotrienes & Med. 1986;23:229.-
39. Myers RF, Siegel MI. Differential effects of anti-inflammatory drugs on lipooxygenase and cyclooxygenase activities of neutrophils from a reverse passive Arthus reaction. Biochemical Biophysical Res Comm. 1983;112:586.-
40. Feldman M, McMahon AT. Do cyclooxygenase-2 inhibitors provide benefits similar to those of traditional nonsteroidal anti-inflammatory drugs, with less gastrointestinal toxicity? Ann Intern Med. 2000;132:134-143.
41. Bannwarth B. Are COX-2 inhibitors as effective as conventional NSAIDs in acute pain states? [letter] Arch Intern Med. 2001;161:127-128.
42. Lipsky PE, Brooks P, Crofford LJ, DuBois R, Graham D, Simon LS, van de Putte LBA, Abramson SB, et al. Unresolved issues in the role of cyclooxygenase-2 in normal physiologic processes and disease. Arch Intern Med. 2000;160(7):913-920.
43. Cryer B, Feldman M. Cyclooxygenase-1 and cyclooxygenase-2 selectivity of widely used nonsteroidal anti-inflammatory drugs. Am J Med. 1998;104(5):413-421.
44. Fraser IS, Pearse C, Shearman RP, Elliott PM, McIlveen J, Markham R. Efficacy of mefenamic acid in patients with a complaint of menorrhagia. Obstet Gynecol. 1981;58:543-551.
45. Fraser IS, McCarron G, Markham R, Robinson M, Smyth E. Long-term treatment of menorrhagia with mefenamic acid. Obstet Gynecol. 1983;61:109-112.
46. Vargyas JM, Campeau JD, Mishell DR Jr. Treatment of menorrhagia with meclofenamate sodium. Am J Obstet Gynecol. 1987;157:944-950.
47. Van Eijkeren MA, Christiaens GCML, Geuze HJ, Haspels AA, Sixma JJ. Effects of mefenamic acid on menstrual hemostasis in essential menorrhagia. Am J Obstet Gynecol. 1992;166:1419-1428.
48. Al-Waili NS. Treatment of menstrual migraine with prostaglandin synthesis inhibitor mefenamic acid: double-blind study with placebo. Eur J Med Res. 2000;5:176-182.
49. Wood C, Jakubowicz D. The treatment of premenstrual symptoms with mefenamic acid. Br J Obstet Gynaecol. 1980;87:627-630.
50. Jakubowicz DL, Godard E, Dewhurst J. The treatment of premenstrual tension with mefenamic acid: analysis of prostaglandin concentrations. Br J Obstet Gynaecol. 1984;91:78-84.
51. Mira M, McNeil D, Fraser IS, Vizzard J, Abraham S. Mefenamic acid in the treatment of premenstrual syndrome. Obstet Gynecol. 1986;68:395-398.
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33. Budoff PW. Use of mefenamic acid in the treatment of primary dysmenorrhea. JAMA. 1979;241:2713.-
34. Powell JR, Smith RP. Mefenamic acid (Ponstel) for treating primary spasmodic dysmenorrhea. Curr Ther Res. 1981;29:544.-
35. Roy S. A double-blind comparison of a propionic acid derivative (ibuprofen) and a fenamate (mefenamic acid) in the treatment of dysmenorrhea. Obstet Gynecol. 1983;61:628.-
36. Smith RP, Powell JR. Simultaneous objective and subjective evaluation of meclofenamate sodium in the treatment of primary dysmenorrhea. Am J Obstet Gynecol. 1987;157:611.-
37. Smith RP. The dynamics of nonsteroidal anti-inflammatory therapy for primary dysmenorrhea. Obstet Gynecol. 1987;70:785.-
38. Boctor AM, Eickholt M, Pugsley TA. Meclofenamate sodium is an inhibitor of both the 5-lipooxygenase and cyclooxygenase pathways of the arachidonic acid cascade in vitro. Prostaglandins, Leukotrienes & Med. 1986;23:229.-
39. Myers RF, Siegel MI. Differential effects of anti-inflammatory drugs on lipooxygenase and cyclooxygenase activities of neutrophils from a reverse passive Arthus reaction. Biochemical Biophysical Res Comm. 1983;112:586.-
40. Feldman M, McMahon AT. Do cyclooxygenase-2 inhibitors provide benefits similar to those of traditional nonsteroidal anti-inflammatory drugs, with less gastrointestinal toxicity? Ann Intern Med. 2000;132:134-143.
41. Bannwarth B. Are COX-2 inhibitors as effective as conventional NSAIDs in acute pain states? [letter] Arch Intern Med. 2001;161:127-128.
42. Lipsky PE, Brooks P, Crofford LJ, DuBois R, Graham D, Simon LS, van de Putte LBA, Abramson SB, et al. Unresolved issues in the role of cyclooxygenase-2 in normal physiologic processes and disease. Arch Intern Med. 2000;160(7):913-920.
43. Cryer B, Feldman M. Cyclooxygenase-1 and cyclooxygenase-2 selectivity of widely used nonsteroidal anti-inflammatory drugs. Am J Med. 1998;104(5):413-421.
44. Fraser IS, Pearse C, Shearman RP, Elliott PM, McIlveen J, Markham R. Efficacy of mefenamic acid in patients with a complaint of menorrhagia. Obstet Gynecol. 1981;58:543-551.
45. Fraser IS, McCarron G, Markham R, Robinson M, Smyth E. Long-term treatment of menorrhagia with mefenamic acid. Obstet Gynecol. 1983;61:109-112.
46. Vargyas JM, Campeau JD, Mishell DR Jr. Treatment of menorrhagia with meclofenamate sodium. Am J Obstet Gynecol. 1987;157:944-950.
47. Van Eijkeren MA, Christiaens GCML, Geuze HJ, Haspels AA, Sixma JJ. Effects of mefenamic acid on menstrual hemostasis in essential menorrhagia. Am J Obstet Gynecol. 1992;166:1419-1428.
48. Al-Waili NS. Treatment of menstrual migraine with prostaglandin synthesis inhibitor mefenamic acid: double-blind study with placebo. Eur J Med Res. 2000;5:176-182.
49. Wood C, Jakubowicz D. The treatment of premenstrual symptoms with mefenamic acid. Br J Obstet Gynaecol. 1980;87:627-630.
50. Jakubowicz DL, Godard E, Dewhurst J. The treatment of premenstrual tension with mefenamic acid: analysis of prostaglandin concentrations. Br J Obstet Gynaecol. 1984;91:78-84.
51. Mira M, McNeil D, Fraser IS, Vizzard J, Abraham S. Mefenamic acid in the treatment of premenstrual syndrome. Obstet Gynecol. 1986;68:395-398.