Diflunisal 500mg tablets
Diflunisal, a salicylate derivative, is a nonsteroidal anti-inflammatory agent (NSAIA) with pharmacologic actions similar to other prototypical NSAIAs.
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Suspected adverse reactions reported for Diflunisal
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2 branded products available
WHO defined daily dose (DDD)
750 mg
Not a recommended dose. The DDD is the assumed average maintenance dose per day for a drug used for its main indication in adults. It is a statistical measure used for research and comparison purposes only.
Source: WHO Collaborating Centre for Drug Statistics Methodology, distributed via the NHS dm+d supplementary BNF/ATC mapping files (NHSBSA). Contains public sector information licensed under the Open Government Licence v3.0.
Therapeutically similar medicines
Similarity is based on WHO Anatomical Therapeutic Chemical (ATC) classification and on a factual NHS dm+d therapeutic-grouping code prefix. Source data: NHS dm+d via TRUD (OGL v3.0), WHO ATC/DDD Index.
NHS prescribing volume and spending trends
Guidelines from the National Institute for Health and Care Excellence
NICE clinical guidance(2)
Tafamidis for treating transthyretin amyloidosis with cardiomyopathy (TA984)
Patisiran for treating hereditary transthyretin amyloidosis (HST10)
Source: National Institute for Health and Care Excellence (NICE). Contains public sector information licensed under the Open Government Licence v3.0.
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Codes for healthcare professionals and prescribing systems
These codes are used by healthcare IT systems and prescribers to identify this medicine.
NHS UK identifiers
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SNOMED CT and dm+d codes from NHS TRUD (Technology Reference data Update Distribution), licensed under the Open Government Licence v3.0. BNF code shown is the factual mapping value distributed by NHS Business Services Authority (NHSBSA) in the dm+d supplementary file under OGL v3.0; it is not affiliated with, nor licensed from, the publishers of the British National Formulary. ATC codes from the WHO Collaborating Centre for Drug Statistics Methodology (whocc.no).
Active and completed clinical studies from ClinicalTrials.gov
Source: ClinicalTrials.gov, a database of the U.S. National Library of Medicine (NLM), National Institutes of Health (NIH). Data accessed via ClinicalTrials.gov API v2. Trial information is provided for research purposes and does not constitute medical advice.
Academic studies and reviews for this medicine's active substance
Showing all 21 studies.
Reviews & meta-analyses: 3 · 2019–2025
Showing all 21 studies, sorted by most relevant.
Wilbert Huang, A. Frederich, Apridya Nurhafizah, et al.
The Egyptian Heart Journal, 2025
Abstract Background Transthyretin cardiac amyloidosis (ATTR-CA) is a progressive cause of diastolic heart failure associated with poor prognosis. Currently available treatment, tafamidis, a TTR stabilizer, is highly effective and tolerable but is not cost-effective. Hence, we aim to evaluate the efficacy and safety of a mechanistically similar but more affordable TTR stabilizer, diflunisal, in patients with ATTR-CA. Methods Systematic searching until June 2024 was done on 3 databases to include patients with ATTR-CA of any type (hereditary or wild-type). Efficacy and safety of diflunisal are assessed by baseline to follow-up mean difference of specific clinical parameters and mortality risk reduction comparing intervention to the control group is evaluated by the generic inverse variance model. The proportion of discontinuation rate and adverse effects are evaluated with a single-arm inverse variance model. Statistical analyses are done with a random effect model conducted on RevMan and R software. Results Twelve studies comprising 539 ATTR-CA patients with a mean of 70 years old are included. The majority of them are male with NYHA I–II severity and are being followed up for approximately 12 months. For diflunisal efficacy outcomes, we found no statistically significant changes in BNP, troponin I, LVEF, GLS, IVSD, PWD, and E wave from baseline to diflunisal posttreatment, however, we found a statistically significant posttreatment increase of transthyretin level (MD 9.34 mg/dL; CI 1.54–17.14; I 2 0%; p 0.02). We also found a statistically significant 77% (CI 58–87%; I 2 34%; p < 0.001) risk reduction of mortality in the diflunisal group compared to the control group. For diflunisal safety outcomes, we found a statistically significant reduction of eGFR, hemoglobin, and platelet count (MD − 5.55, − 0.32, − 11.61, respectively, p < 0.01) but no statistically significant change in creatinine level. Pooled proportions of discontinuation rate of diflunisal therapy is 24% (CI 15–36%; I 2 72%; p < 0.01) and adverse events causing therapy discontinuation are renal impairment (21%), GI impairment (13%), bleeding (6%), and fluid retention (6%). Conclusion Diflunisal therapy is beneficial in treating ATTR-CA patients but is associated with adverse effects that require therapy discontinuation. Hence, careful monitoring during diflunisal therapy is necessary.
Abstract licence: CC BY
S. H. Abd El-Alim, A. Kassem, M. Basha, et al.
International Journal of Pharmaceutics, 2019
- Administration, Cutaneous
- Analgesics
- Anti-Inflammatory Agents
Michel Ibrahim, G. S. Saint Croix, Spencer C. Lacy, et al.
Heart Failure Reviews, 2021
- Diflunisal
- Amyloid Neuropathies, Familial
- Myocardium
G. Lohrmann, Alexandra Pipilas, R. Mussinelli, et al.
Journal of cardiac failure, 2019
- Diflunisal
- Heart Failure
- Cardiomyopathies
P. Snetkov, S. Morozkina, R. Olekhnovich, et al.
Materials, 2021
Diflunisal is a well-known drug for the treatment of rheumatoid arthritis, osteoarthritis, primary dysmenorrhea, and colon cancer. This molecule belongs to the group of nonsteroidal anti-inflammatory drugs (NSAID) and thus possesses serious side effects such as cardiovascular diseases risk development, renal injury, and hepatic reactions. The last clinical data demonstrated that diflunisal is one of the recognized drugs for the treatment of cardiac amyloidosis and possesses a survival benefit similar to that of clinically approved tafamidis. Diflunisal stabilizes the transthyretin (TTR) tetramer and prevents the misfolding of monomers and dimers from forming amyloid deposits in the heart. To avoid serious side effects of diflunisal, the various delivery systems have been developed. In the present review, attention is given to the recent development of diflunisal-loaded delivery systems, its technology, release profiles, and effectiveness.
Abstract licence: CC BY
M. Bashir, Junaid Ahmad, M. Asif, et al.
International Journal of Nanomedicine, 2021
- Nanogels
- Administration, Topical
- Anti-Inflammatory Agents
PURPOSE: Rheumatoid arthritis is an autoimmune disorder that directly affects joints. However, other body organs including heart, eyes, skin, blood vessels and lungs may also be affected. The purpose of this study was to design and evaluate a nanoemulgel formulation of diflunisal (DIF) and solubility enhanced diflunisal (DIF-IC) for enhanced topical anti-inflammatory activity. METHODOLOGY: Nanoemulsion formulations of both DIF and DIF-IC were prepared and incorporated in three different gelling agents, namely carboxymethylcellulose sodium (CMC-Na), sodium alginate (Na-ALG) and xanthan gum (XG). All the formulations were evaluated in term of particle size, pH, conductivity, viscosity, zeta potential and in vitro drug release. The formulation 2 (NE2) of both DIF and DIF-IC which expressed optimum release and satisfactory physicochemical properties was incorporated with gelling agents to produce final nanoemulgel formulations. The optimized nanoemulgel formulation was subjected to three different in vivo anti-inflammatory models including carrageenan-induced paw edema model, histamine-induced paw edema model and formalin-induced paw edema model. RESULTS: DIF-IC-loaded nanoemulgel formulations yielded significantly enhanced in vitro skin permeation than DIF-loaded nanoemulgel. The nanoemulgel formulation of DIF-IC formulated with XG produced improved in vivo anti-inflammatory activity. CONCLUSION: It was recommended that DIF-IC-based nanoemulgel formulation prepared with XG could be a better option for effective topical treatment of inflammatory conditions.
Abstract licence: CC BY-NC
Lennert Cools, E. Derveaux, F. Reniers, et al.
International journal of pharmaceutics, 2024
- Diflunisal
- Hydrogen Bonding
- Excipients
C. Chao, S. Tzeng, Ming-Chang Chiang, et al.
Annals of Clinical and Translational Neurology, 2024
- Benzoxazoles
- Diflunisal
- Cardiomyopathies
Abstract Objectives Hereditary transthyretin (TTR) amyloidosis (ATTRv) is frequently complicated by polyneuropathy (ATTRv‐PN) and cardiomyopathy (ATTRv‐CM). The long‐term efficacy of diflunisal on both polyneuropathy and cardiomyopathy in ATTRv patients, especially those with non‐V30M genotypes, has not been fully investigated and compared with that of tafamidis. Methods We compared the structural and biochemical characteristics of A97S‐TTR complexed with tafamidis with those of diflunisal, and prospectively followed up and compared the progression of polyneuropathy and cardiomyopathy between ATTRv‐PN patients taking diflunisal and those taking tafamidis. Results Both diflunisal and tafamidis effectively bind to the two thyroxine‐binding sites at the A97S‐TTR dimer–dimer interface and equally and almost sufficiently reduce amyloid fibril formation. Thirty‐five ATTRv‐PN patients receiving diflunisal and 22 patients receiving tafamidis were enrolled. Compared with no treatment, diflunisal treatment significantly delayed the transition of FAP Stage 1 to 2 and Stage 2 to 3 and decreased the deterioration in parameters of the ulnar nerve conduction study (NCS). The progression of FAP stage or NCS parameters did not differ between patients treated with diflunisal and those treated with tafamidis. Both diflunisal and tafamidis treatments significantly decreased radiotracer uptake on 99m Tc‐PYP SPECT and stabilized cardiac wall thickness and blood pro‐B‐type natriuretic peptide levels. No significant adverse events occurred during diflunisal or tafamidis treatment. Interpretations The binding patterns of both tafamidis and diflunisal to A97S‐TTR closely resembled those observed in the wild type. Diflunisal can effectively delay the progression of polyneuropathy and cardiomyopathy with similar efficacy to tafamidis and may become a cost‐effective alternative treatment for late‐onset ATTRv‐PN.
Abstract licence: CC BY
P. Agarwala, Arabinda Ghosh, P. Hazarika, et al.
The journal of physical chemistry. B, 2023
- Cyclodextrins
- Diflunisal
- 2-Hydroxypropyl-beta-cyclodextrin
L. Chan, Hong K. Lee, Ling Wang, et al.
Antibiotics, 2023
Invasive methicillin-resistant Staphylococcus aureus (MRSA) infections are leading causes of morbidity and mortality that are complicated by increasing resistance to conventional antibiotics. Thus, minimizing virulence and enhancing antibiotic efficacy against MRSA is a public health imperative. We originally demonstrated that diflunisal (DIF; [2-hydroxy-5-(2,4-difluorophenyl) benzoic acid]) inhibits S. aureus virulence factor expression. To investigate pharmacophores that are active in this function, we evaluated a library of structural analogues for their efficacy to modulate virulence phenotypes in a panel of clinically relevant S. aureus isolates in vitro. Overall, the positions of the phenyl, hydroxyl, and carboxylic moieties and the presence or type of halogen (F vs. Cl) influenced the efficacy of compounds in suppressing hemolysis, proteolysis, and biofilm virulence phenotypes. Analogues lacking halogens inhibited proteolysis to an extent similar to DIF but were ineffective at reducing hemolysis or biofilm production. In contrast, most analogues lacking the hydroxyl or carboxylic acid groups did not suppress proteolysis but did mitigate hemolysis and biofilm production to an extent similar to DIF. Interestingly, chirality and the substitution of fluorine with chlorine resulted in a differential reduction in virulence phenotypes. Together, this pattern of data suggests virulence-suppressing pharmacophores of DIF and structural analogues integrate halogen, hydroxyl, and carboxylic acid moiety stereochemistry. The anti-virulence effects of DIF were achieved using concentrations that are safe in humans, do not impair platelet antimicrobial functions, do not affect S. aureus growth, and do not alter the efficacy of conventional antibiotics. These results offer proof of concept for using novel anti-virulence strategies as adjuvants to antibiotic therapy to address the challenge of MRSA infection.
Abstract licence: CC BY
Sources: aggregated from Europe PMC (EMBL-EBI), OpenAlex, Crossref, PubMed and other open scholarly databases. Retracted articles are excluded. Study information is provided for research purposes and does not constitute medical advice.
Pharmacology and chemical data from DrugBank
Key facts
Drug status
Approved
Major interactions
160 found
Half-life
8 to 12 hours
Mechanism
The precise mechanism of the analgesic and anti-inflammatory actions of diflunisal is not known.
Food interactions
2 warnings
Human targets
2 targets
Data: DrugBank · CC BY-NC 4.0
Pharmacokinetics at a glance
Absorption
80-90%
Half-life
8 to 12 hours
Protein binding
98 to 99%
Metabolism
90%
Elimination
90%
Pharmacokinetic data: DrugBank · CC BY-NC 4.0
Known interactions with other medications. Always consult a healthcare professional.
Showing 50 of 1550 interactions
Selective COX-2 inhibitors have been associated with increased risk of serious cardiovascular events (e.g. myocardial infarction, stroke) in some patients.
Current data is insufficient to assess the cardiovascular risk of diflunisal. Short-term use does not appear to be associated with increased cardiovascular risk (except when used immediately following coronary artery bypass graft (CABG) surgery). Risk of GI toxicity including bleeding, ulceration and perforation.
Risk of direct renal injury, including renal papillary necrosis. Severe hepatic reactions, including cholestasis and/or jaundice, have been reported. May cause rash or hypersensitivity syndrome.
How the body processes this drug — absorption, distribution, metabolism, and elimination
Proteins and enzymes this drug interacts with in the body
PMID:11939906 PMID:16373578 PMID:19540099 PMID:22942274 PMID:26859324 PMID:27226593 PMID:7592599 PMID:7947975 PMID:9261177
The cyclooxygenase activity oxygenates AA to the hydroperoxy endoperoxide prostaglandin G2 (PGG2), and the peroxidase activity reduces PGG2 to the hydroxy endoperoxide prostaglandin H2 (PGH2), the precursor of all 2-series prostaglandins and thromboxanes .
PMID:16373578 PMID:22942274 PMID:26859324 PMID:27226593 PMID:7592599 PMID:7947975 PMID:9261177
This complex transformation is initiated by abstraction of hydrogen at carbon 13 (with S-stereochemistry), followed by insertion of molecular O2 to form the endoperoxide bridge between carbon 9 and 11 that defines prostaglandins. The insertion of a second molecule of O2 (bis-oxygenase activity) yields a hydroperoxy group in PGG2 that is then reduced to PGH2 by two electrons .
PMID:16373578 PMID:22942274 PMID:26859324 PMID:27226593 PMID:7592599 PMID:7947975 PMID:9261177
Similarly catalyzes successive cyclooxygenation and peroxidation of dihomo-gamma-linoleate (DGLA, C20:3(n-6)) and eicosapentaenoate (EPA, C20:5(n-3)) to corresponding PGH1 and PGH3, the precursors of 1- and 3-series prostaglandins .
PMID:11939906 PMID:19540099
In an alternative pathway of prostanoid biosynthesis, converts 2-arachidonoyl lysophopholipids to prostanoid lysophopholipids, which are then hydrolyzed by intracellular phospholipases to release free prostanoids .
PMID:27642067
Metabolizes 2-arachidonoyl glycerol yielding the glyceryl ester of PGH2, a process that can contribute to pain response .
PMID:22942274
Generates lipid mediators from n-3 and n-6 polyunsaturated fatty acids (PUFAs) via a lipoxygenase-type mechanism. Oxygenates PUFAs to hydroperoxy compounds and then reduces them to corresponding alcohols .
PMID:11034610 PMID:11192938 PMID:9048568 PMID:9261177
Plays a role in the generation of resolution phase interaction products (resolvins) during both sterile and infectious inflammation .
PMID:12391014
Metabolizes docosahexaenoate (DHA, C22:6(n-3)) to 17R-HDHA, a precursor of the D-series resolvins (RvDs) .
PMID:12391014
As a component of the biosynthetic pathway of E-series resolvins (RvEs), converts eicosapentaenoate (EPA, C20:5(n-3)) primarily to 18S-HEPE that is further metabolized by ALOX5 and LTA4H to generate 18S-RvE1 and 18S-RvE2 .
PMID:21206090
In vascular endothelial cells, converts docosapentaenoate (DPA, C22:5(n-3)) to 13R-HDPA, a precursor for 13-series resolvins (RvTs) shown to activate macrophage phagocytosis during bacterial infection .
PMID:26236990
In activated leukocytes, contributes to oxygenation of hydroxyeicosatetraenoates (HETE) to diHETES (5,15-diHETE and 5,11-diHETE) .
PMID:22068350 PMID:26282205
Can also use linoleate (LA, (9Z,12Z)-octadecadienoate, C18:2(n-6)) as substrate and produce hydroxyoctadecadienoates (HODEs) in a regio- and stereospecific manner, being (9R)-HODE ((9R)-hydroxy-(10E,12Z)-octadecadienoate) and (13S)-HODE ((13S)-hydroxy-(9Z,11E)-octadecadienoate) its major products (By similarity).
During neuroinflammation, plays a role in neuronal secretion of specialized preresolving mediators (SPMs) 15R-lipoxin A4 that regulates phagocytic microglia (By similarity)
The insertion of a second molecule of O2 (bis-oxygenase activity) yields a hydroperoxy group in PGG2 that is then reduced to PGH2 by two electrons .
PMID:7947975
Involved in the constitutive production of prostanoids in particular in the stomach and platelets. In gastric epithelial cells, it is a key step in the generation of prostaglandins, such as prostaglandin E2 (PGE2), which plays an important role in cytoprotection. In platelets, it is involved in the generation of thromboxane A2 (TXA2), which promotes platelet activation and aggregation, vasoconstriction and proliferation of vascular smooth muscle cells (Probable).
Can also use linoleate (LA, (9Z,12Z)-octadecadienoate, C18:2(n-6)) as substrate and produce hydroxyoctadecadienoates (HODEs) in a regio- and stereospecific manner, being (9R)-HODE ((9R)-hydroxy-(10E,12Z)-octadecadienoate) and (13S)-HODE ((13S)-hydroxy-(9Z,11E)-octadecadienoate) its major products (By similarity)
Enzymes involved in drug metabolism — important for understanding drug interactions
Proteins that transport this drug across cell membranes
PMID:11669456 PMID:11907186 PMID:14675047 PMID:22108572 PMID:23832370 PMID:28534121 PMID:9950961
Mediates the uptake of OA across the basolateral side of proximal tubule epithelial cells, thereby contributing to the renal elimination of endogenous OA from the systemic circulation into the urine .
PMID:9887087
Functions as a biopterin transporters involved in the uptake and the secretion of coenzymes tetrahydrobiopterin (BH4), dihydrobiopterin (BH2) and sepiapterin to urine, thereby determining baseline levels of blood biopterins .
PMID:28534121
Transports prostaglandin E2 (PGE2) and prostaglandin F2-alpha (PGF2-alpha) and may contribute to their renal excretion .
PMID:11907186
Also mediates the uptake of cyclic nucleotides such as cAMP and cGMP .
PMID:26377792
Involved in the transport of neuroactive tryptophan metabolites kynurenate (KYNA) and xanthurenate (XA) and may contribute to their secretion from the brain .
PMID:22108572 PMID:23832370
May transport glutamate .
PMID:26377792
Also involved in the disposition of uremic toxins and potentially toxic xenobiotics by the renal organic anion secretory pathway, helping reduce their undesired toxicological effects on the body .
PMID:11669456 PMID:14675047
Uremic toxins include the indoxyl sulfate (IS), hippurate/N-benzoylglycine (HA), indole acetate (IA), 3-carboxy-4- methyl-5-propyl-2-furanpropionate (CMPF) and urate .
PMID:14675047 PMID:26377792
Xenobiotics include the mycotoxin ochratoxin (OTA) .
PMID:11669456
May also contribute to the transport of organic compounds in testes across the blood-testis-barrier PMID:35307651
Proteins that carry this drug through the body
PMID:19021548
Major calcium and magnesium transporter in plasma, binds approximately 45% of circulating calcium and magnesium in plasma (By similarity).
Potentially has more than two calcium-binding sites and might additionally bind calcium in a non-specific manner (By similarity). The shared binding site between zinc and calcium at residue Asp-273 suggests a crosstalk between zinc and calcium transport in the blood (By similarity). The rank order of affinity is zinc > calcium > magnesium (By similarity).
Binds to the bacterial siderophore enterobactin and inhibits enterobactin-mediated iron uptake of E.coli from ferric transferrin, and may thereby limit the utilization of iron and growth of enteric bacteria such as E.coli .
PMID:6234017
Does not prevent iron uptake by the bacterial siderophore aerobactin PMID:6234017
ATC N02BA11
Chemical identifiers
CAS, UNII, InChI Key and database cross-references
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Chemical identifiers
CAS, UNII, InChI Key and database cross-references
Linked compound data from DrugBank Open Data (CC BY-NC 4.0)
Diflunisal
Additional database identifiers
Drugs Product Database (DPD)
2113
ChemSpider
2951
BindingDB
50240510
PDB
1FL
ZINC
ZINC000000020243
HUGO Gene Nomenclature Committee (HGNC)
HGNC:9605
GenAtlas
PTGS2
GeneCards
PTGS2
GenBank Gene Database
L15326
GenBank Protein Database
291988
Guide to Pharmacology
1376
UniProt Accession
PGH2_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:9604
GenAtlas
PTGS1
GeneCards
PTGS1
GenBank Gene Database
M31822
GenBank Protein Database
387018
Guide to Pharmacology
1375
UniProt Accession
PGH1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:12540
GeneCards
UGT1A8
GenBank Gene Database
AF030310
GenBank Protein Database
2613044
UniProt Accession
UD18_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:12541
GeneCards
UGT1A9
GenBank Gene Database
S55985
GenBank Protein Database
7690346
UniProt Accession
UD19_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:12405
GenAtlas
TTR
GeneCards
TTR
GenBank Gene Database
K02091
GenBank Protein Database
189582
Guide to Pharmacology
2851
UniProt Accession
TTHY_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:399
GenAtlas
ALB
GeneCards
ALB
GenBank Gene Database
V00494
GenBank Protein Database
28590
UniProt Accession
ALBU_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:10970
GenAtlas
hROAT1
GeneCards
SLC22A6
GenBank Gene Database
AF057039
GenBank Protein Database
3831566
Guide to Pharmacology
1025
UniProt Accession
S22A6_HUMAN
DrugBank citations
If you use DrugBank data in your research, please cite the following publications:
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Structured knowledge from the free knowledge base
ATC classifications (Wikidata)
Linked open data from Wikidata (Q2602750), a free and open knowledge base operated by the Wikimedia Foundation. Data is available under the Creative Commons CC0 1.0 Public Domain Dedication. WHO INN from the World Health Organization.