Research history The COX-2 enzyme was discovered in 1988 by Daniel Simmons, a
Brigham Young University researcher. The mouse COX-2 gene was cloned by UCLA scientist Harvey Herschman, a finding published in 1991. The basic research leading to the discovery of COX-2 inhibitors has been the subject of at least two lawsuits. Brigham Young University has sued
Pfizer, alleging breach of contract from relations BYU had with the company at the time of Simmons's work. A settlement was reached in April 2012 in which Pfizer agreed to pay $450 million. The other litigation is based on United States Pat. No. 6,048,850 owned by
University of Rochester, which claimed a method to treat pain without causing gastro-intestinal distress by selectively inhibiting COX-2. When the patent issued, the university sued Searle (later Pfizer) in a case called,
University of Rochester v. G.D. Searle & Co., 358 F.3d 916 (Fed. Cir. 2004). The court ruled in favor of Searle in 2004, holding in essence that the university had claimed a method requiring, yet provided no written description of, a compound that could inhibit COX-2 and therefore the patent was invalid. In the course of the search for a specific
inhibitor of the negative effects of
prostaglandins that spared the positive effects, it was discovered that prostaglandins could indeed be separated into two general classes that could loosely be regarded as "good prostaglandins" and "bad prostaglandins", according to the structure of a particular
enzyme involved in their
biosynthesis,
cyclooxygenase. Prostaglandins whose synthesis involves the
cyclooxygenase-I enzyme, or COX-1, are responsible for maintenance and protection of the
gastrointestinal tract, while prostaglandins whose synthesis involves the cyclooxygenase-II enzyme, or COX-2, are responsible for inflammation and pain. The existing
nonsteroidal anti-inflammatory drugs (NSAIDs) differ in their relative specificities for COX-2 and COX-1; while aspirin and ibuprofen inhibit COX-2 and COX-1 enzymes, other NSAIDs appear to have partial COX-2 specificity, particularly
meloxicam (
Mobic). Aspirin is ≈170-fold more potent in inhibiting COX-1 than COX-2. Studies of meloxicam 7.5 mg per day for 23 days find a level of gastric injury similar to that of a
placebo, and for meloxicam 15 mg per day a level of injury lower than that of other NSAIDs; however, in clinical practice meloxicam can still cause some
ulcer complications.
Valdecoxib and rofecoxib were about 300 times more potent at inhibiting COX-2 than COX-1, but too toxic for the heart, suggesting the possibility of relief from pain and inflammation without gastrointestinal irritation, and promising to be a boon for those who had previously experienced adverse effects or had
comorbidities that could lead to such complications. Celecoxib is approximately 30 times more potent at inhibiting COX-2 than COX-1, with etoricoxib being 106 times more potent.
Research fraud Between 1996 and 2009,
Scott Reuben purportedly conducted clinical research on the use of COX-2 inhibitors, often in combination with
gabapentin or
pregabalin, for the prevention and treatment of
postoperative pain, research which was found in 2009 to have been faked. Reuben pleaded guilty, paid fines, and served six months in jail, and lost his
medical license. A 2009 review of
meta-articles used in
evidence-based medicine found that while some reviews were no longer valid when the Reuben studies were removed, the conclusions in the majority of them remained unchanged. The review found that the key Reuben claims that needed to be re-examined were "the absence of detrimental effects of coxibs on
bone healing after
spine surgery, the beneficial long-term outcome after preemptive administration of coxibs including an allegedly decreased incidence of chronic pain after surgery, and the analgesic efficacy of
ketorolac or
clonidine when added to
local anesthetics for
intravenous regional anesthesia."
Early COX-2-inhibiting drugs Celebrex (and other brand names for celecoxib) was introduced in 1999 and rapidly became the most frequently prescribed new drug in the United States. By October 2000, its US sales exceeded 100 million prescriptions per year for $3 billion, and was still rising. Sales of Celebrex alone reached $3.1 billion in 2001. A
Spanish study found that between January 2000 and June 2001, 7% of NSAID prescriptions and 29% of NSAID expenditures were for COX-2 inhibitors. Over the period of the study, COX-2 inhibitors rose from 10.03% of total NSAIDs prescribed by specialty physicians to 29.79%, and from 1.52% to 10.78% of NSAIDs prescribed by
primary care physicians (98.23% of NSAIDs and 94.61% of COX-2 inhibitors were prescribed by primary care physicians). For specialty physicians, rofecoxib and celecoxib were third and fifth most frequently prescribed NSAIDs but first and second in cost, respectively; for primary-care physicians they were ninth and twelfth most frequently prescribed NSAIDs and first and fourth in cost. Sales and marketing efforts were supported by two large trials, the Celecoxib Long-term Arthritis Safety Study (CLASS) in
JAMA, and the Vioxx Gastrointestinal Outcomes Research (VIGOR). The VIGOR trial was later proven to have been based on faulty data, and Vioxx was eventually withdrawn from the market. was at the center of a dispute about the ethics of medical journals. In the VIGOR trial, over 8,000 patients were randomized to receive either naproxen or rofecoxib (Vioxx). Both studies concluded that COX-2 specific NSAIDs were associated with significantly fewer adverse gastrointestinal effects. In the CLASS trial which compared Celebrex 800 mg/day to
ibuprofen 2400 mg/day and
diclofenac 150 mg/day for
osteoarthritis or
rheumatoid arthritis for six months, Celebrex was associated with significantly fewer upper gastrointestinal complications (0.44% vs. 1.27%,
p = 0.04), with no significant difference in incidence of
cardiovascular events in patients not taking aspirin for cardiovascular
prophylaxis. The VIGOR trial results were published in 2000 in the
New England Journal of Medicine Bombardier and her research team claimed that there was "an increase in myocardial infarction in the patients given rofecoxib (0.4%) compared with those given naproxen (0.1%)" and "patients given naproxen experienced 121 side effects compared with 56 in the patients taking rofecoxib," a "marvellous result for Merck" which "contributed to huge sales of rofecoxib." In September 2001, the United States
Food and Drug Administration (FDA) sent a warning letter to the CEO of Merck, stating, "Your promotional campaign discounts the fact that in the VIGOR study, patients on Vioxx were observed to have a four to five fold increase in myocardial infarctions (MIs) compared to patients on the comparator nonsteroidal anti-inflammatory drug (NSAID), Naprosyn (naproxen)." This led to the introduction, in April 2002, of warnings on Vioxx labeling concerning the increased risk of cardiovascular events (heart attack and stroke). By 2005
The New England Journal of Medicine published an editorial accusing the Bombardier et al. of deliberately withholding data. Claire Bombardier, a University of Toronto rheumatologist, had claimed that the VIGOR trial showed that
Vioxx 50 mg/day had benefits over
naproxen for rheumatoid arthritis, specifically that Vioxx reduced the risk of symptomatic ulcers and clinical upper gastrointestinal events (
perforations,
obstructions and
bleeding) by 54%, to 1.4% from 3%, the risk of complicated
upper gastrointestinal events (complicated perforations, obstructions and bleeding in the
upper gastrointestinal tract) by 57%, and the risk of bleeding from anywhere in the gastrointestinal tract by 62%. An enormous
marketing effort capitalized on these publications; Vioxx was the most heavily advertised prescription drug in 2000, and Celebrex the seventh, according to
IMS Health.
Neuroblastomas Small tumors of the
sympathetic nervous system (
neuroblastoma) appear to have abnormal levels of COX-2 expressed. These studies report that overexpression of the COX-2 enzyme has an adverse effect on the tumor suppressor,
p53. p53 is an apoptosis
transcription factor normally found in the
cytosol. When
cellular DNA is damaged beyond repair, p53 is transported to the
nucleus where it promotes p53 mediated apoptosis. Two of the metabolites of COX-2,
prostaglandin A2 (PGA2) and A1 (PGA1), when present in high quantities, bind to p53 in the cytosol and inhibit its ability to cross into the nucleus. This essentially sequesters p53 in the cytosol and prevents apoptosis. Coxibs such as Celebrex (celecoxib), by selectively inhibiting the overexpressed COX-2, allow p53 to work properly. Functional p53 allows DNA damaged neuroblastoma cells to induce
apoptosis, halting tumor growth. COX-2 up-regulation has also been linked to the
phosphorylation and activation of the E3
ubiquitin ligase HDM2, a
protein that mediates p53 ligation and tagged destruction, through
ubiquitination. The mechanism for this neuroblastoma HDM2 hyperactivity is unknown. Studies have shown that COX-2 inhibitors block the phosphorylation of HDM2 preventing its activation. In vitro, the use of COX-2 inhibitors lowers the level of active HDM2 found in neuroblastoma cells. The exact process of how COX-2 inhibitors block HDM2 phosphorylation is unknown, but this mediated reduction in active HDM2 concentration level restores the cellular p53 levels. After treatment with a COX-2 inhibitor, the restored p53 function allows DNA damaged neuroblastoma cells to commit suicide through apoptosis reducing the size of growth of the tumor. == References ==