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| AHFS/Drugs.com | International Drug Names |
| Routes of administration | Oral, transdermal |
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| Pharmacokinetic data | |
| Protein binding | 97% |
| Metabolism | Liver glucuronidation |
| Elimination half-life | 75 minutes |
| Excretion | Kidney |
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| Chemical and physical data | |
| Formula | C15H18O3 |
| Molar mass | 246.306 g·mol−1 |
| 3D model (JSmol) | |
| Chirality | Racemic mixture |
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Loxoprofen is a nonsteroidal anti-inflammatory drug (NSAID) in the propionic acid derivatives group, which also includes ibuprofen and naproxen among others. It is available in some countries for oral administration. A transdermal preparation was approved for sale in Japan in January 2006;[1] medicated tape and gel formulations followed in 2008 and 2010.
It was patented in 1977 and approved for medical use in 1986.[2]
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Transcription
(Music) Say you're at the beach, and you get sand in your eyes. How do you know the sand is there? You obviously can't see it, but if you are a normal, healthy human, you can feel it, that sensation of extreme discomfort, also known as pain. Now pain makes you do something, in this case, rinse your eyes until the sand is gone. And how do you know the sand is gone? Exactly. Because there's no more pain. There are people who don't feel pain. Now, that might sound cool, but it's not. If you can't feel pain, you could get hurt, or even hurt yourself and never know it. Pain is your body's early warning system. It protects you from the world around you, and from yourself. As we grow, we install pain detectors in most areas of our body. These detectors are specialized nerve cells called nociceptors that stretch from your spinal cord to your skin, your muscles, your joints, your teeth and some of your internal organs. Just like all nerve cells, they conduct electrical signals, sending information from wherever they're located back to your brain. But, unlike other nerve cells, nociceptors only fire if something happens that could cause or is causing damage. So, gently touch the tip of a needle. You'll feel the metal, and those are your regular nerve cells. But you won't feel any pain. Now, the harder you push against the needle, the closer you get to the nociceptor threshold. Push hard enough, and you'll cross that threshold and the nociceptors fire, telling your body to stop doing whatever you're doing. But the pain threshold isn't set in stone. Certain chemicals can tune nociceptors, lowering their threshold for pain. And when cells are damaged, they and other nearby cells start producing these tuning chemicals like crazy, lowering the nociceptors' threshold to the point where just touch can cause pain. And this is where over-the-counter painkillers come in. Aspirin and ibuprofen block production of one class of these tuning chemicals, called prostaglandins. Let's take a look at how they do that. When cells are damaged, they release a chemical called arachidonic acid. Now, two enzymes called COX-1 and COX-2 convert this arachidonic acid into prostaglandin H2, which is then converted into a bunch of other chemicals that do a bunch of things, including raise your body temperature, cause inflammation and lower the pain threshold. Now, all enzymes have an active site. That's the place in the enzyme where the reaction happens. The active sites of COX-1 and COX-2 fit arachidonic acid very cozily. As you can see, there is no room to spare. Now, it's in this active site that aspirin and ibuprofen do their work. So, they work differently -- aspirin acts like a spine from a porcupine. It enters the active site and then breaks off, leaving half of itself in there, totally blocking that channel and making it impossible for the arachidonic acid to fit. This permanently deactivates COX-1 and COX-2. Ibuprofen, on the other hand, enters the active site, but doesn't break apart or change the enzyme. COX-1 and COX-2 are free to spit it out again, but for the time that that ibuprofen is in there, the enzyme can't bind arachidonic acid, and can't do its normal chemistry. But how do aspirin and ibuprofen know where the pain is? Well, they don't. Once the drugs are in your bloodstream, they are carried throughout your body, and they go to painful areas just the same as normal ones. So that's how aspirin and ibuprofen work. But there are other dimensions to pain. Neuropathic pain, for example, is pain caused by damage to our nervous system itself; there doesn't need to be any sort of outside stimulus. And scientists are discovering that the brain controls how we respond to pain signals. For example, how much pain you feel can depend on whether you're paying attention to the pain, or even your mood. Pain is an area of active research. If we can understand it better, maybe we can help people manage it better.
Pharmacokinetics
Loxoprofen is a prodrug. It is quickly converted to its active trans-alcohol metabolite following oral administration, and reaches its peak plasma concentration within 30 to 50 minutes.
Mechanism of action
As most NSAIDs, loxoprofen is a non-selective cyclooxygenase inhibitor, and works by reducing the synthesis of prostaglandins from arachidonic acid.
Interactions
Loxoprofen should not be administered at the same time as second-generation quinolone antibiotics such as ciprofloxacin and norfloxacin, as it increases their inhibition of GABA and this may cause seizures.[3] It may also increase the plasma concentration of warfarin, methotrexate, sulfonylurea derivatives and lithium salts, so care should be taken when loxoprofen is administered to patients taking any of these drugs.[3]
Brand names
It is marketed in Brazil, Mexico, China and Japan by Sankyo as its sodium salt, loxoprofen sodium, under the trade name Loxonin; in Argentina as Oxeno; in India as Loxomac; in Thailand as Japrolox; and in Saudi Arabia as Roxonin and Roxonin Tape.
A generic drug is marketed in Brazil by Aché as Oxotron. In Japan, two fixed dose combinations are available: Loxonin S Plus, with magnesium oxide, and Loxonin S Premium, with apronal, caffeine, and aluminium magnesium silicate.
References
- ^ Daiichi Sankyo Co. (January 24, 2006). "Percutaneous Absorption-Type Analgesic and Anti-inflammatory Drug Loxonin Poultice 100mg Receives Approval for Manufacture" (Press release). Doctor's Guide Global Edition. Retrieved 2007-04-19.
- ^ Fischer J, Ganellin CR (2006). Analogue-based Drug Discovery. John Wiley & Sons. p. 521. ISBN 9783527607495.
- ^ a b "LOXONIN - Bula do Medicamento [Label Information]" (in Portuguese). Centralx. 2007. Retrieved 2007-04-19.
| pyrazolones / pyrazolidines | |
|---|---|
| salicylates | |
| acetic acid derivatives and related substances | |
| oxicams |
|
| propionic acid derivatives (profens) |
|
| n-arylanthranilic acids (fenamates) | |
| COX-2 inhibitors (coxibs) | |
| other | |
| NSAID combinations | |
Key: underline indicates initially developed first-in-class compound of specific group; #WHO-Essential Medicines; †withdrawn drugs; ‡veterinary use. | |
This page was last edited on 20 January 2024, at 13:11