formaldehyde and Inflammation studies

paraform: polymerized formaldehyde; RN given refers to parent cpd; used in root canal therapy

Inflammation: A pathological process characterized by injury or destruction of tissues caused by a variety of cytologic and chemical reactions. It is usually manifested by typical signs of pain, heat, redness, swelling, and loss of function.

Research Excerpts

Excerpt	Relevance	Reference
"These electrophysiological studies, using desensitization and selective antagonists, demonstrate a peripheral role of bradykinin in the generation of pain in the rat."	8.78	Electrophysiological approaches to the study of bradykinin and nitric oxide in inflammatory pain. ( Chapman, V; Dickenson, A; Haley, J; Schachter, M, 1992)
"Different nociceptive models induced with heat and chemicals were used to assess the potency of emodin in alleviating pain."	8.31	Emodin Reduces Inflammatory and Nociceptive Responses in Different Pain-and Inflammation-Induced Mouse Models. ( Guan, L; Li, J; Zhang, X, 2023)
"Sixty-six Wistar rats were allocated into five groups: the first group (six rats) was treated with the vehicle only, without induction of paw edema and granulomatous inflammation, and served as a negative control; the second group (12 rats) was allocated into two subgroups and treated with the vehicle only, with induction of paw edema and granulomatous inflammation, and served as a positive control; the third group (36 rats) was allocated into six subgroups and treated with different doses of aliskiren (15, 30, and 60 mg/kg) in both models; the fourth group (12 rats) was treated with dexamethasone (1 mg/kg) in both models of inflammation."	7.96	The Anti-Inflammatory Effect of Different Doses of Aliskiren in Rat Models of Inflammation. ( Ahmed, ZA; Aziz, TA; Kareem, AA; Othman, HH, 2020)
"To unravel the underlying mechanism of minocycline in formalin-induced inflammatory pain, and to investigate the effects of minocycline on synaptic transmission in substantia gela-tinosa (SG) neurons of rat spinal dorsal horn."	7.88	[Minocycline inhibits formalin-induced inflammatory pain and the underlying mechanism]. ( Cheng, XE; Feng, XJ; Hu, XX; Jiang, CY; Liu, T; Ma, LX; Peng, HZ, 2018)
"Epidemiological evidence suggests that formaldehyde (FA) exposure may influence the prevalence and severity of allergic asthma."	7.85	Differential effects of formaldehyde exposure on airway inflammation and bronchial hyperresponsiveness in BALB/c and C57BL/6 mice. ( Bao, Y; He, Y; Hua, L; Li, L, 2017)
"We aimed to evaluate whether circulating immune/inflammation markers were altered in workers occupationally exposed to formaldehyde."	7.81	Circulating immune/inflammation markers in Chinese workers occupationally exposed to formaldehyde. ( Bassig, BA; Beane Freeman, LE; Blair, A; Guo, W; Hildesheim, A; Hu, W; Huang, H; Ji, Z; Kemp, TJ; Kim, C; Lan, Q; Li, L; Pinto, LA; Qiu, C; Reiss, B; Rothman, N; Seow, WJ; Shen, M; Shiels, MS; Smith, MT; Tang, X; Vermeulen, R; Wen, C; Zhang, L, 2015)
"To observe the effect of formaldehyde inhalation on the allergic rhinitis mice model."	7.81	[Effect of formaldehyde inhalation on allergic rhinitis in mice]. ( Xiang, R; Xu, Y, 2015)
" Opioid coadministration had a synergistic effect in the acute tonic pain (acetic acid writhing test), acute phasic pain (tail flick test) and inflammatory pain (orofacial formalin test)."	7.79	Systemic synergism between codeine and morphine in three pain models in mice. ( Miranda, HF; Noriega, V; Prieto, JC; Sierralta, F; Zepeda, RJ, 2013)
" The present study aimed to assess the role of cysteinyl leukotriene receptor antagonist on peripheral inflammation and whether montelukast treatment enhances the anti-inflammatory effect of indomethacin."	7.79	Potentiation of indomethacin-induced anti-inflammatory response by montelukast in formalin-induced inflammation in rats. ( Behmanesh, MA; Ghorbanzadeh, B; Hemmati, AA, 2013)
"Tolerance to morphine analgesia following repeated administration disturbs the continuation of opioid therapy for severe pain."	7.78	Inhibition of morphine tolerance is mediated by painful stimuli via central mechanisms. ( Fukazawa, Y; Iwai, S; Kiguchi, N; Kishioka, S; Kobayashi, Y; Saika, F; Ueno, K; Yamamoto, C, 2012)
"Endothelin-1 (ET-1) has been suggested to be involved in different types of pain due to its neuromodulatory nature."	7.78	Over-expression of endothelin-1 in astrocytes, but not endothelial cells, ameliorates inflammatory pain response after formalin injection. ( Chen, AY; Chen, SM; Cheung, CW; Chung, SK; Hung, VK; Tai, LW, 2012)
"Formaldehyde (FA) is an indoor and outdoor pollutant widely used by many industries, and its exposure is associated with inflammation and oxidative stress in the airways."	7.77	Formaldehyde induces lung inflammation by an oxidant and antioxidant enzymes mediated mechanism in the lung tissue. ( Bertoni, Jde A; Breithaupt-Faloppa, AC; Câmara, NO; Correa-Costa, M; de Oliveira, AP; Durão, AC; Lino-dos-Santos-Franco, A; Marcourakis, T; Oliveira-Filho, RM; Tavares-de-Lima, W, 2011)
"Exposure to air pollutants such as formaldehyde (FA) leads to inflammation, oxidative stress and immune-modulation in the airways and is associated with airway inflammatory disorders such as asthma."	7.76	Differential effects of formaldehyde exposure on the cell influx and vascular permeability in a rat model of allergic lung inflammation. ( Bolonheis, S; Breithaupt-Faloppa, AC; de Oliveira, AP; Domingos, HV; Lino-dos-Santos-Franco, A; Muscará, MN; Oliveira-Filho, RM; Peron, JP; Tavares-de-Lima, W; Vargaftig, BB, 2010)
"The GABA amides of the antidepressants nortriptyline and fluoxetine, 1 and 2, were compared to their respective parent compounds in rodent models of pain."	7.75	Gamma-aminobutyric acid amides of nortriptyline and fluoxetine display improved pain suppressing activity. ( Aharoni, A; Geffen, Y; Gil-Ad, I; Halbfinger, E; Nisemblat, Y; Nudelman, A; Rephaeli, A; Tarasenko, I; Tarasenko, N; Weizman, A, 2009)
"We evaluated the effects of zonisamide on inflammatory and neuropathic pain using the mouse formalin test and streptozotocin (STZ)-induced diabetic mice with a reduced withdrawal threshold to mechanical stimuli, respectively."	7.74	Zonisamide suppresses pain symptoms of formalin-induced inflammatory and streptozotocin-induced diabetic neuropathy. ( Murakami, T; Ono, H; Tanabe, M, 2008)
"Recent clinical studies have demonstrated that when morphine is used to control pain in cancer patients, psychological dependence is not a major concern."	7.73	Direct evidence for the involvement of the mesolimbic kappa-opioid system in the morphine-induced rewarding effect under an inflammatory pain-like state. ( Ise, Y; Kishimoto, Y; Misawa, K; Narita, M; Suzuki, T; Yajima, Y, 2005)
"Intrathecally administered edaravone, a free radical scavenger, had analgesic effects on inflammatory-induced acute and facilitated pain but not on acute thermal pain, without any behavioural side-effects."	7.73	Intrathecal edaravone, a free radical scavenger, is effective on inflammatory-induced pain in rats. ( Nishiyama, T; Ogawa, M, 2005)
"It has been demonstrated that spinal microglial activation is involved in formalin-induced pain and that minocycline, an inhibitor of microglial activation, attenuate behavioral hypersensitivity in neuropathic pain models."	7.73	Systemic administration of minocycline inhibits formalin-induced inflammatory pain in rat. ( Cho, IH; Choi, SY; Chung, YM; Jung, SJ; Kim, D; Kim, JS; Lee, H; Lee, SJ; Li, HY; Oh, SB; Park, CK; Park, K; Park, SH; Piao, ZG, 2006)
"In both acute thermal- and inflammatory-induced pain, intrathecally administered midazolam and bupivacaine produced synergistic analgesia with decreased side effects in intrathecally catheterized rats."	7.72	Midazolam can potentiate the analgesic effects of intrathecal bupivacaine on thermal- or inflammatory-induced pain. ( Hanaoka, K; Nishiyama, T, 2003)
"We investigated the interaction between spinally administered bupivacaine and clonidine using an animal model of acute and inflammatory pain."	7.72	Intrathecal clonidine and bupivacaine have synergistic analgesia for acute thermally or inflammatory-induced pain in rats. ( Hanaoka, K; Nishiyama, T, 2004)
"Intrathecal administration of propofol had analgesic effects on inflammation-induced acute and facilitated pain but not on thermally-induced acute pain."	7.72	Intrathecal propofol has analgesic effects on inflammation-induced pain in rats. ( Hanaoka, K; Matsukawa, T; Nishiyama, T, 2004)
"Spinally-administered midazolam, a benzodiazepine, and clonidine, an alpha2-adrenergic receptor agonist, have significant synergistic effects on thermally-induced acute and formalin-induced inflammatory pain."	7.71	The synergistic interaction between midazolam and clonidine in spinally-mediated analgesia in two different pain models of rats. ( Hanaoka, K; Nishiyama, T, 2001)
"Peripherally administered nitric oxide itself has no analgesic effect, but it enhances the analgesic effects of peripherally administered morphine during inflammation induced by paw formalin injection in the rat."	7.70	The interaction of FK409, a novel nitric oxide releaser, and peripherally administered morphine during experimental inflammation. ( Nozaki-Taguchi, N; Yamamoto, T, 1998)
" (1) The therapeutic effects of the cannabinoid anandamide and the putative CB2 agonist palmitoylethanolamide were tested in a model of persistent visceral pain (turpentine inflammation of the urinary bladder)."	7.70	The anti-hyperalgesic actions of the cannabinoid anandamide and the putative CB2 receptor agonist palmitoylethanolamide in visceral and somatic inflammatory pain. ( Hasnie, FS; Jaggar, SI; Rice, AS; Sellaturay, S, 1998)
"We previously reported that the morphine-induced place preference was attenuated under inflammation produced by the unilateral injection of 2."	7.70	Role of the kappa-opioid system in the attenuation of the morphine-induced place preference under chronic pain. ( Kishimoto, Y; Misawa, M; Nagase, H; Suzuki, T; Takeda, F, 1999)
"The mechanism underlying the previous findings that the development of antinociceptive tolerance to morphine was significantly delayed in the presence of inflammatory pain induced by formalin was examined."	7.69	Involvement of pain associated anxiety in the development of morphine tolerance in formalin treated mice. ( Kaneto, H; Rahman, AF; Takahashi, M, 1994)
"Possible central noradrenergic and cholinergic modulation of acute peripheral inflammation was investigated in rats, adopting the formaldehyde-induced pedal inflammation as the experimental model."	7.69	Central noradrenergic and cholinergic modulation of formaldehyde-induced pedal inflammation and nociception in rats. ( Dumka, VK; Raviprakash, V; Tandan, SK; Tripathi, HC, 1996)
"Morphine-, methamphetamine- and cocaine-induced place preferences under inflammation produced by unilateral injections of 2."	7.69	Formalin- and carrageenan-induced inflammation attenuates place preferences produced by morphine, methamphetamine and cocaine. ( Kishimoto, Y; Misawa, M; Suzuki, T, 1996)
"Possible central serotonergic and histaminergic modulation of acute peripheral inflammation was investigated in rats, adopting the formaldehyde-induced acute pedal inflammation as an experimental model."	7.69	Central serotonergic and histaminergic modulation of peripheral inflammation and nociception in rats. ( Dumka, VK; Raviprakash, V; Tandan, SK; Tripathi, HC, 1996)
" Cortisone, mepyramine and sodium salicylate were effective in reducing histamine-induced inflammation, sodium salicylate being less active in the adrenalectomized animal."	7.64	Some inhibitors of histamine-induced and formaldehyde-induced inflammation in mice. ( NORTHOVER, BJ; SUBRAMANIAN, G, 1961)
" Kidney function was assessed by dosage of uric acid, creatinine and urea."	5.46	The exposure to formaldehyde causes renal dysfunction, inflammation and redox imbalance in rats. ( Bandeira, ACB; Bezerra, FS; Campos, KKD; Costa, GP; Machado, DF; Nardeli, CR; Pena, KB; Ramos, CO; Talvani, A, 2017)
"Formaldehyde (FA) is an environmental pollutant widely used in industry."	5.42	Short-term exposure to formaldehyde promotes oxidative damage and inflammation in the trachea and diaphragm muscle of adult rats. ( Bandeira, AC; Bezerra, FS; Lima, LF; Lima, WG; Murta, GL; Nardeli, CR, 2015)
"Acute pain was determined using the hot plate test (thermal nociception) and the formalin test (inflammatory pain)."	5.40	The oral administration of trans-caryophyllene attenuates acute and chronic pain in mice. ( Andersen, ML; Carlini, EL; Gama, VS; Molska, GR; Paula-Freire, LI, 2014)
" Furthermore, A-425619 maintained efficacy in the postoperative pain model after twice daily dosing p."	5.33	A-425619 [1-isoquinolin-5-yl-3-(4-trifluoromethyl-benzyl)-urea], a novel transient receptor potential type V1 receptor antagonist, relieves pathophysiological pain associated with inflammation and tissue injury in rats. ( El Kouhen, R; Faltynek, CR; Gauvin, DM; Gomtsyan, A; Honore, P; Jarvis, MF; Lee, CH; Marsh, K; Mikusa, J; Sullivan, JP; Wismer, CT; Zhong, C; Zhu, CZ, 2005)
"Ambroxol's effects were compared with those of gabapentin."	5.33	Ambroxol, a Nav1.8-preferring Na(+) channel blocker, effectively suppresses pain symptoms in animal models of chronic, neuropathic and inflammatory pain. ( Arndt, K; Gaida, W; Klinder, K; Weiser, T, 2005)
" The efficacy of the newly developed nonolipid vesicle formulation loaded with semipurified extract of Bhut Jolokia was tested on carrageenan and formaldehyde-induced inflammation as well as Freund's adjuvant-induced arthritis model."	5.22	Topical Analgesic Nanolipid Vesicles Formulation of Capsaicinoids Extract of Bhut Jolokia (Capsicum chinense Jacq): Pharmacodynamic Evaluation in Rat Models and Acceptability studies in Human Volunteers. ( Kaur, CD; Mazumder, B; Sarwa, KK; Suresh, PK, 2016)
"These electrophysiological studies, using desensitization and selective antagonists, demonstrate a peripheral role of bradykinin in the generation of pain in the rat."	4.78	Electrophysiological approaches to the study of bradykinin and nitric oxide in inflammatory pain. ( Chapman, V; Dickenson, A; Haley, J; Schachter, M, 1992)
"A paratertiary-butyl phenol-formaldehyde resin is present in the routine patch test series of the International Contact Dermatitis Research Group."	4.77	Contact sensitizers in resins based on phenol and formaldehyde. ( Bruze, M, 1985)
"Different nociceptive models induced with heat and chemicals were used to assess the potency of emodin in alleviating pain."	4.31	Emodin Reduces Inflammatory and Nociceptive Responses in Different Pain-and Inflammation-Induced Mouse Models. ( Guan, L; Li, J; Zhang, X, 2023)
"The presence of phenobarbital and formaldehyde in drugs, food, and beverages can lead to various health issues, including inflammation, oncogenesis, and neurological distress."	4.31	Biochemical Pilot Study on Effects of Pomegranate Seed Oil Extract and Cosmetic Cream on Neurologically Mediated Skin Inflammation in Animals and Humans: A Comparative Observational Study. ( Felemban, S; Hamouda, AF, 2023)
"The objective of this study is to test the hypothesis that citral modulates orofacial pain using two experimental models: formalin-induced hyperalgesia in the vibrissae area and during persistent temporomandibular hypernociception using Complete Freund's Adjuvant - CFA test."	4.31	Orofacial anti-hypernociceptive effect of citral in acute and persistent inflammatory models in rats. ( Branco, LGS; Cárnio, EC; Emilio-Silva, MT; Garcia, FS; Hiruma-Lima, CA; Jesus, AA; Nascimento, GC; Santos, BM; Santos, WS; Solon, IG, 2023)
" For mechanism investigation, it was used hot plate test to induce opioid receptors, a histamine and serotonin test to induce edema paw, finally, for the TRPV1 receptor, it was used the capsaicin test."	4.02	Pharmacological studies on aqueous extract of Launaea arborescens from southwest Algeria. ( Belboukhari, N; Cheriti, A; Ould El Hadj-Khelil, A; Seddiki, LS; Sekkoum, K; Sulaiman, MR, 2021)
"Sixty-six Wistar rats were allocated into five groups: the first group (six rats) was treated with the vehicle only, without induction of paw edema and granulomatous inflammation, and served as a negative control; the second group (12 rats) was allocated into two subgroups and treated with the vehicle only, with induction of paw edema and granulomatous inflammation, and served as a positive control; the third group (36 rats) was allocated into six subgroups and treated with different doses of aliskiren (15, 30, and 60 mg/kg) in both models; the fourth group (12 rats) was treated with dexamethasone (1 mg/kg) in both models of inflammation."	3.96	The Anti-Inflammatory Effect of Different Doses of Aliskiren in Rat Models of Inflammation. ( Ahmed, ZA; Aziz, TA; Kareem, AA; Othman, HH, 2020)
" The plant extract at doses of 50, 100 and 150 mg/kg was tested for anti-inflammatory activity against carrageenan and egg albumin induced paw edema in mice and analgesic activity was appraised against acetic acid induced writhing and formalin induced paw licking in mice models."	3.96	Evaluation of anti-inflammatory and analgesic activities of aqueous methanolic extract of Ranunculus muricatus in albino mice. ( Alamgeer, -; Asif, H; Hasan, UH; Irfan, HM; Nasreen, P; Sharif, A; Uttra, AM; Younis, W, 2020)
" platensis on different types of pain and inflammation in comparison to diclofenac sodium."	3.96	Effects of Spirulina platensis on pain and inflammation in long Evans rats. ( Akhter, S; Ali, T; Nipa, NS; Rafiq, K, 2020)
" Nociceptive response induced by formaldehyde and mechanical allodynia induced by chronic constriction injury (CCI) of the sciatic nerve or intraplantar (ipl) injection of complete Freund's adjuvant (CFA) were used as experimental models of pain."	3.91	The phthalimide analogues N-3-hydroxypropylphthalimide and N-carboxymethyl-3-nitrophthalimide exhibit activity in experimental models of inflammatory and neuropathic pain. ( Alves, RJ; Araújo, DP; Batista, CRA; Brito, AMS; Canhestro, WG; Coelho, MM; Coura, GME; de Fátima, Â; Dutra, MMGB; Godin, AM; Machado, RR; Matsui, TC; Melo, ISF, 2019)
"To unravel the underlying mechanism of minocycline in formalin-induced inflammatory pain, and to investigate the effects of minocycline on synaptic transmission in substantia gela-tinosa (SG) neurons of rat spinal dorsal horn."	3.88	[Minocycline inhibits formalin-induced inflammatory pain and the underlying mechanism]. ( Cheng, XE; Feng, XJ; Hu, XX; Jiang, CY; Liu, T; Ma, LX; Peng, HZ, 2018)
"Epidemiological evidence suggests that formaldehyde (FA) exposure may influence the prevalence and severity of allergic asthma."	3.85	Differential effects of formaldehyde exposure on airway inflammation and bronchial hyperresponsiveness in BALB/c and C57BL/6 mice. ( Bao, Y; He, Y; Hua, L; Li, L, 2017)
"05) suppressed topical ear edema, systemic paw edema, global edematous response to formaldehyde arthritis and granuloma tissue growth."	3.83	Extracts of Leptadenia hastata Leaf, a Famine Food and Traditional Remedy for Furuncles, Suppress Inflammation in Murine Models. ( Akah, PA; Ezea, SC; Ezike, AC; Okoli, CO; Ufere, IK, 2016)
" The analgesic, anti-inflammatory and anti-platelet activities were assessed using acetic acid and formalin-induced nociception in mice, carrageenan-induced rat paw edema and arachidonic acid-induced platelets aggregation tests."	3.83	Analgesic, anti-inflammatory and anti-platelet activities of Buddleja crispa. ( Bukhari, IA; Gilani, AH; Meo, SA; Saeed, A, 2016)
"The mixture and the individual isolated cycloartanes significantly inhibited both phases of formalin-induced pain with percentage inhibition ranging from 13 to 78%."	3.83	Cycloartanes from Oxyanthus pallidus and derivatives with analgesic activities. ( Achounna, AS; Greffrath, W; Ngnokam, D; Nguelefack, TB; Piegang, BN; Tigoufack, IB; Treede, RD; Watcho, P, 2016)
" At same doses, SP-Ul was tested on Wistar rats on paw edema elicited by different irritants (carrageenan, dextran, bradykinin, histamine or serotonin)."	3.83	Analgesic and anti-inflammatory actions on bradykinin route of a polysulfated fraction from alga Ulva lactuca. ( Benevides, NM; Bezerra, MM; Chaves, HV; de Araújo, IW; de Sousa Oliveira Vanderlei, E; Maciel, GF; Pereira, KM; Quinderé, AL; Ribeiro, KA; Ribeiro, NA; Rodrigues, JA; Silva, JF, 2016)
" Then, the pharmacological activities of FJHQT extract with respect to clinical use was investigated with acetic acid-induced writhing response, formalin-induced licking response and carrageenan-induced paw edema."	3.81	Anti-nociceptive, anti-inflammatory and toxicological evaluation of Fang-Ji-Huang-Qi-Tang in rodents. ( Chang, CW; Lin, YC; Wu, CR, 2015)
"We aimed to evaluate whether circulating immune/inflammation markers were altered in workers occupationally exposed to formaldehyde."	3.81	Circulating immune/inflammation markers in Chinese workers occupationally exposed to formaldehyde. ( Bassig, BA; Beane Freeman, LE; Blair, A; Guo, W; Hildesheim, A; Hu, W; Huang, H; Ji, Z; Kemp, TJ; Kim, C; Lan, Q; Li, L; Pinto, LA; Qiu, C; Reiss, B; Rothman, N; Seow, WJ; Shen, M; Shiels, MS; Smith, MT; Tang, X; Vermeulen, R; Wen, C; Zhang, L, 2015)
" Xylene-induced ear edema, carrageenan-induced paw edema and acetic acid-induced vascular permeability test were used to investigate the anti-inflammatory activities of GL in mice."	3.81	Observing Anti-inflammatory and Anti-nociceptive Activities of Glycyrrhizin Through Regulating COX-2 and Pro-inflammatory Cytokines Expressions in Mice. ( Li, YX; Ma, L; Niu, Y; Niu, YT; Shi, GJ; Sun, T; Wang, HL; Wu, J; Yu, JQ; Zheng, J, 2015)
"To observe the effect of formaldehyde inhalation on the allergic rhinitis mice model."	3.81	[Effect of formaldehyde inhalation on allergic rhinitis in mice]. ( Xiang, R; Xu, Y, 2015)
" & Naudin (Ss-EtOH) in the experimental models of edema induced by carrageenan, dextran, or histamin and nociception induced by chemical stimuli, such as acetic acid, formalin, capsaicin, or glutamate."	3.80	Anti-inflammatory and antinociceptive effects of Sterculia striata A. St.-Hil. & Naudin (Malvaceae) in rodents. ( Almeida, FR; Amaral, MP; Chaves, MH; Costa, DA; Figueiredo, KA; Júnior, FB; Oliveira, FA; Oliveira, IS; Oliveira, RC; Silva, FV, 2014)
"Diverse proinflammatory and algesic agents activate melagatran-sensitive serine proteases that cause inflammation and pain by a PAR2-mediated mechanism."	3.80	Serine proteases and protease-activated receptor 2 mediate the proinflammatory and algesic actions of diverse stimulants. ( Amadesi, S; Bogyo, M; Bunnett, NW; Carlsson, JF; Cattaruzza, F; Cottrell, GS; Kirkwood, K; Knecht, W; Lyo, V; Murphy, JE, 2014)
"Intra-gastric administration of AGB (75, 150, and 300 mg/kg) showed a dose-dependent antinociceptive effect in intraperitoneal acetic acid (writhing), thermal nociception in CD1 mice, and subplantar formalin models, as well as anti-inflammatory effect in carrageenan- induced paw edema in Wistar rats."	3.80	Antinociceptive and anti-inflammatory activities of Geranium bellum and its isolated compounds. ( Altamirano-Báez, DA; Ángeles, LJ; Bautista-Ávila, M; Cariño-Cortés, R; De la O Arciniega, M; Gayosso de Lucio, JA; Ortiz, MI; Velázquez-González, C, 2014)
" Opioid coadministration had a synergistic effect in the acute tonic pain (acetic acid writhing test), acute phasic pain (tail flick test) and inflammatory pain (orofacial formalin test)."	3.79	Systemic synergism between codeine and morphine in three pain models in mice. ( Miranda, HF; Noriega, V; Prieto, JC; Sierralta, F; Zepeda, RJ, 2013)
"Curcumin, the active ingredient of turmeric (Curcuma longa), has a wide range of beneficial effects including anti-inflammation and analgesia."	3.79	Antinociceptive curcuminoid, KMS4034, effects on inflammatory and neuropathic pain likely via modulating TRPV1 in mice. ( Choi, JM; Chung, HJ; Han, H; Jung, SJ; Kim, HJ; Lee, JY; Lee, YS; Oh, Y; Seo, KS; Shin, KJ; Shin, TJ; Yoon, TG, 2013)
" The antinociceptive study of DV was performed using models of acetic acid-induced writhing and formalin-induced pain in mice."	3.79	Bioassay-guided evaluation of Dioscorea villosa - an acute and subchronic toxicity, antinociceptive and anti-inflammatory approach. ( Araújo, AA; Barreto, RS; de Albuquerque, RL; de Almeida, EB; Lima, AK; Lima, CM; Melo, MG; Moraes, VR; Nogueira, PC; Oliveira, DL; Oliveira, ER; Quintans-Júnior, LJ; Serafini, MR, 2013)
"To investigate bone marrow toxicity (bone marrow pathology, hematotoxicity) and underlying mechanisms (oxidative stress, inflammation, apoptosis) in formaldehyde-exposed mice."	3.79	Bone marrow injury induced via oxidative stress in mice by inhalation exposure to formaldehyde. ( Ding, S; Li, R; Liu, X; McHale, C; Wu, Y; Yang, X; Ye, X; Zhang, L; Zhang, Y, 2013)
" The anti-inflammatory and anti-nociceptive activities of 40% ethanolic extracts of the three plants were compared using the models of xylene-induced ear edema, formalin-induced inflammation, carrageenan-induced air pouch inflammation, acetic acid-induced writhing and formalin-induced nociception."	3.79	Comparison of active constituents, acute toxicity, anti-nociceptive and anti-inflammatory activities of Porana sinensis Hemsl., Erycibe obtusifolia Benth. and Erycibe schmidtii Craib. ( Chen, Z; Liao, L; Wang, Z; Wu, L; Zhang, Z, 2013)
" Triphala recipe (4 mg/ear) significantly exhibited an inhibitory effect on the ear edema formation induced by ethyl phenylpropiolate-induced, but not on the arachidonic acid-induced ear edema in rats."	3.79	Evaluation of anti-inflammatory and antinociceptive activity of Triphala recipe. ( Jaijoy, K; Sireeratawong, S; Soonthornchareonnon, N, 2013)
" The present study aimed to assess the role of cysteinyl leukotriene receptor antagonist on peripheral inflammation and whether montelukast treatment enhances the anti-inflammatory effect of indomethacin."	3.79	Potentiation of indomethacin-induced anti-inflammatory response by montelukast in formalin-induced inflammation in rats. ( Behmanesh, MA; Ghorbanzadeh, B; Hemmati, AA, 2013)
" The anti-inflammatory activity was investigated using carragenin, egg-albumin induced oedema models, while acetic acid, formalin-induced paw licking and thermal-induced pain models were used to evaluate the antinociceptive property."	3.78	Anti-inflammatory and analgesic activities of Melanthera scandens. ( Amazu, LU; Frank, SG; Okokon, JE; Udoh, AE, 2012)
" The oral administration of the Chantaleela recipe reduced ulcer formation in acute gastric ulcer models (EtOH/HCl-, indomethacin-, and stress-induced gastric lesions)."	3.78	Anti-inflammatory and anti-ulcerogenic activities of Chantaleela recipe. ( Jaijoy, K; Khonsung, P; Nanna, U; Piyabhan, P; Sireeratawong, S; Soonthornchareonnon, N, 2012)
" Chlorophyll a and pheophytin a (magnesium-free chlorophyll a) from fresh leaves showed potent anti-inflammatory activity against carrageenan-induced paw edema in mice and formalin-induced paw edema in rats."	3.78	Chlorophyll revisited: anti-inflammatory activities of chlorophyll a and inhibition of expression of TNF-α gene by the same. ( Asha, VV; Karunagaran, D; Nair, SA; Rajendran, KN; Ramalingam, K; Sasidharan, SP; Subramoniam, A; Sureshkumar, PK, 2012)
"Tolerance to morphine analgesia following repeated administration disturbs the continuation of opioid therapy for severe pain."	3.78	Inhibition of morphine tolerance is mediated by painful stimuli via central mechanisms. ( Fukazawa, Y; Iwai, S; Kiguchi, N; Kishioka, S; Kobayashi, Y; Saika, F; Ueno, K; Yamamoto, C, 2012)
" EO(MeOH) was evaluated for its analgesic activity in acetic acid-induced writhing response and formalin test, and anti-inflammatory effect was examined by λ-carrageenan-induced paw edema assay."	3.78	Analgesic and anti-inflammatory activities of the methanol extract of Elaeagnus oldhamii Maxim. in mice. ( Chang, YS; Ho, YL; Lai, SC; Liao, CR; Peng, WH, 2012)
"Endothelin-1 (ET-1) has been suggested to be involved in different types of pain due to its neuromodulatory nature."	3.78	Over-expression of endothelin-1 in astrocytes, but not endothelial cells, ameliorates inflammatory pain response after formalin injection. ( Chen, AY; Chen, SM; Cheung, CW; Chung, SK; Hung, VK; Tai, LW, 2012)
"The antinociceptive and antiinflammatory activities of MEA were evaluated using the writhing, formalin, and tail-flick tests, carrageenan-induced paw edema and arachidonic acid-induced ear edema."	3.77	Antinociceptive and antiinflammatory activities of Adiantum latifolium Lam.: evidence for a role of IL-1β inhibition. ( Barros, TA; Lucchese, AM; Nogueira, TM; Nonato, FR; Oliveira, CE; Santos, RR; Soares, MB; Villarreal, CF, 2011)
" While the analgesic activity was examined against thermally and chemically induced nociceptive pain in mice, using the acetic acid and hot-plate test methods."	3.77	Anti-inflammatory and analgesic activity of different extracts of Commiphora myrrha. ( Duan, JA; Hua, YQ; Qian, DW; Su, S; Tang, YP; Wang, T; Yu, L; Zhou, W, 2011)
" Effects of intrathecal glutamate transporter activator (R)-(-)-5-methyl-1-nicotinoyl-2-pyrazoline and inhibitors (DL-threo-β-benzyloxyaspartate [TBOA], dihydrokainate, and DL-threo-β-hydroxyaspartate), or TBOA plus group III metabotropic glutamate receptor antagonist (RS)-α-methylserine-O-phosphate, on formalin- and CFA-induced inflammatory pain were examined."	3.77	Effect of inhibition of spinal cord glutamate transporters on inflammatory pain induced by formalin and complete Freund's adjuvant. ( Guan, X; Lu, W; Petralia, RS; Rothstein, JD; Tao, YX; Yaster, M, 2011)
" All extracts were evaluated for (1) topical administration against both arachidonic acid and 12-deoxyphorbol-13-decanoate (TPA)-induced inflammation in mice and (2) per-os administration against inflammation by λ-carrageenan-induced paw oedema in guinea-pigs and (3) topical analgesia in tail flick and formalin models and per-os writhing test in mice."	3.77	Chemical study and anti-inflammatory, analgesic and antioxidant activities of the leaves of Aristotelia chilensis (Mol.) Stuntz, Elaeocarpaceae. ( Backhouse, N; Christen, P; Correa, O; Costa, E; Cretton, S; Delporte, C; Miranda, H; Muñoz, O; Torres, V, 2011)
"Kirenol has demonstrated its significant potential to be further investigated for its discovery as a new lead compound for management of topical pain and inflammation, although further pharmacological research is necessary to fully understand its mechanism of action."	3.77	Topical anti-inflammatory and analgesic activity of kirenol isolated from Siegesbeckia orientalis. ( Cai, YL; Shang, XM; Wang, JP; Wu, YX; Xiong, CM; Xu, HX; Ye, YJ; Zhou, YM, 2011)
"Salicylaldehyde 2-chlorobenzoyl hydrazone (H(2)LASSBio-466), salicylaldehyde 4-chlorobenzoyl hydrazone (H(2)LASSBio-1064) and their complexes [Zn(LASSBio-466)H(2)O](2) (1) and [Zn(HLASSBio-1064)Cl](2) (2) were evaluated in animal models of peripheral and central nociception, and acute inflammation."	3.77	Analgesic and anti-inflammatory activities of salicylaldehyde 2-chlorobenzoyl hydrazone (H(2)LASSBio-466), salicylaldehyde 4-chlorobenzoyl hydrazone (H(2)LASSBio-1064) and their zinc(II) complexes. ( Alexandre-Moreira, MS; Alves, MA; Barreiro, EJ; Beraldo, H; Castellano, EE; Júnior, WB; Lima, LM; Parrilha, GL; Perez-Rebolledo, A; Piro, OE, 2011)
"Formaldehyde (FA) is an indoor and outdoor pollutant widely used by many industries, and its exposure is associated with inflammation and oxidative stress in the airways."	3.77	Formaldehyde induces lung inflammation by an oxidant and antioxidant enzymes mediated mechanism in the lung tissue. ( Bertoni, Jde A; Breithaupt-Faloppa, AC; Câmara, NO; Correa-Costa, M; de Oliveira, AP; Durão, AC; Lino-dos-Santos-Franco, A; Marcourakis, T; Oliveira-Filho, RM; Tavares-de-Lima, W, 2011)
" In an inflammatory pain model, Compound 5 suppressed the capsaicin-induced flinching behavior in a dose-dependent manner."	3.77	Suppressive effects of glycyrrhetinic acid derivatives on tachykinin receptor activation and hyperalgesia. ( Akasaka, Y; Hatta, A; Inoue, H; Sakai, A; Suzuki, H; Takasu, K; Tsukahara, M, 2011)
" Since the sympathetic chain ganglia neurons (SChG) affect colonic function, the purpose of our study was to determine the precise location of the SChG neurons innervating the porcine descending colon, define their chemical coding and answer the question of whether paraformaldehyde-induced colitis in female pigs is able to change the chemical phenotype of the perikarya."	3.76	Phenotyping of sympathetic chain ganglia (SChG) neurons in porcine colitis. ( Calka, J; Gonkowski, S; Skobowiat, C, 2010)
"This study examined the analgesic and anti-inflammatory actions of cis-mulberroside A isolated from Ramulus mori in several models of inflammatory pain in mice."	3.76	Anti-inflammatory and analgesic properties of cis-mulberroside A from Ramulus mori. ( Shi, L; Zhang, Z, 2010)
"Exposure to air pollutants such as formaldehyde (FA) leads to inflammation, oxidative stress and immune-modulation in the airways and is associated with airway inflammatory disorders such as asthma."	3.76	Differential effects of formaldehyde exposure on the cell influx and vascular permeability in a rat model of allergic lung inflammation. ( Bolonheis, S; Breithaupt-Faloppa, AC; de Oliveira, AP; Domingos, HV; Lino-dos-Santos-Franco, A; Muscará, MN; Oliveira-Filho, RM; Peron, JP; Tavares-de-Lima, W; Vargaftig, BB, 2010)
"The purpose of this study was to assess the possible antinociceptive effect of the acid sensing ion channels (ASICs) inhibitors amiloride and benzamil after local peripheral administration in three models of inflammatory pain in rats."	3.75	Acid increases inflammatory pain in rats: effect of local peripheral ASICs inhibitors. ( García-López, BE; Granados-Soto, V; Herrejon-Abreu, EB; López-Santillán, FJ; Murbartián, J; Rocha-González, HI, 2009)
"The GABA amides of the antidepressants nortriptyline and fluoxetine, 1 and 2, were compared to their respective parent compounds in rodent models of pain."	3.75	Gamma-aminobutyric acid amides of nortriptyline and fluoxetine display improved pain suppressing activity. ( Aharoni, A; Geffen, Y; Gil-Ad, I; Halbfinger, E; Nisemblat, Y; Nudelman, A; Rephaeli, A; Tarasenko, I; Tarasenko, N; Weizman, A, 2009)
"Central neurotensin (NT) administration results in a naloxone-insensitive antinociceptive response in animal models of acute and persistent pain."	3.75	Evidence for a role of NTS2 receptors in the modulation of tonic pain sensitivity. ( Baudisson, S; Beaudet, N; Belleville, K; Dansereau, MA; Ezzoubaa, F; Martinez, J; Richelson, E; Roussy, G; Sarret, P, 2009)
"We evaluated the effects of zonisamide on inflammatory and neuropathic pain using the mouse formalin test and streptozotocin (STZ)-induced diabetic mice with a reduced withdrawal threshold to mechanical stimuli, respectively."	3.74	Zonisamide suppresses pain symptoms of formalin-induced inflammatory and streptozotocin-induced diabetic neuropathy. ( Murakami, T; Ono, H; Tanabe, M, 2008)
" The glucan was tested for its effects on the acetic acid-induced writhing reaction in mice, a typical model for quantifying inflammatory pain."	3.74	Anti-inflammatory and analgesic properties in a rodent model of a (1-->3),(1-->6)-linked beta-glucan isolated from Pleurotus pulmonarius. ( Baggio, CH; Carbonero, ER; Freitas, CS; Gorin, PA; Iacomini, M; Marcon, R; Olsen, LM; Santos, AR; Smiderle, FR, 2008)
"Painful reaction of rats to intraperitoneal injections of L-arginine, Nw-nitro-L-arginine, and agmatine was studied on the model of formalin-induced inflammation."	3.74	Effects of NO-modulating agents on the development of acute painful reaction in rats. ( Dyuizen, IV; Lamash, NE, 2008)
"In this study, the effect of (S)-3,4-dicarboxyphenylglycine (DCPG), a selective mGlu8 receptor agonist, has been investigated in inflammatory and neuropathic pain models in order to elucidate the role of mGlu8 receptor in modulating pain perception."	3.74	Effects of (S)-3,4-DCPG, an mGlu8 receptor agonist, on inflammatory and neuropathic pain in mice. ( de Novellis, V; Maione, S; Marabese, I; Palazzo, E; Rossi, F; Scafuro, MA; Vita, D, 2007)
"Substituted thiazoles with different structural features were synthesized and screened for their anti-inflammatory activity in acute carrageenin induced rat paw edema model and chronic formalin induced rat paw edema model."	3.74	2-Amino-5-thiazolyl motif: a novel scaffold for designing anti-inflammatory agents of diverse structures. ( Franklin, PX; Nivsarkar, M; Padh, H; Pillai, AD; Rathod, PD; Sudarsanam, V; Vasu, KK; Yerande, S, 2008)
"In the present study, we have investigated the analgesic effect of the aqueous extract of the root of Glycine tomentella (AGT) using models of acetic acid-induced writhing response and formalin test, the anti-inflammatory effect of AGT using model of lambda-carrageenan-induced paw edema."	3.74	Analgesic and anti-inflammatory activities of aqueous extract from Glycine tomentella root in mice. ( Huang, HW; Hung, YC; Ko, YZ; Lin, YC; Lu, TC; Peng, WH, 2007)
"The present study investigated the hypothesis that hydrogen sulfide (H2S) is pro-nociceptive in the formalin model of persistent inflammatory pain in the adult rat."	3.74	A nociceptive-intensity-dependent role for hydrogen sulphide in the formalin model of persistent inflammatory pain. ( Cheng, Y; Khanna, S; Lee, AT; Li, L; Moore, PK; Shah, JJ, 2008)
"Recent clinical studies have demonstrated that when morphine is used to control pain in cancer patients, psychological dependence is not a major concern."	3.73	Direct evidence for the involvement of the mesolimbic kappa-opioid system in the morphine-induced rewarding effect under an inflammatory pain-like state. ( Ise, Y; Kishimoto, Y; Misawa, K; Narita, M; Suzuki, T; Yajima, Y, 2005)
"Intrathecally administered edaravone, a free radical scavenger, had analgesic effects on inflammatory-induced acute and facilitated pain but not on acute thermal pain, without any behavioural side-effects."	3.73	Intrathecal edaravone, a free radical scavenger, is effective on inflammatory-induced pain in rats. ( Nishiyama, T; Ogawa, M, 2005)
" In order to determine if the endogenous opioid system is involved in this antinociception, naloxone was administered just prior to the injection of a selective P2X3/P2X2/3 receptor antagonist, A-317491, in rat models of neuropathic, chemogenic, and inflammatory pain."	3.73	Endogenous opioid mechanisms partially mediate P2X3/P2X2/3-related antinociception in rat models of inflammatory and chemogenic pain but not neuropathic pain. ( Bianchi, B; Faltynek, CR; Honore, P; Jarvis, MF; McDonald, HA; McGaraughty, S; Mikusa, J; Wismer, CT; Zhu, CZ, 2005)
"It has been demonstrated that spinal microglial activation is involved in formalin-induced pain and that minocycline, an inhibitor of microglial activation, attenuate behavioral hypersensitivity in neuropathic pain models."	3.73	Systemic administration of minocycline inhibits formalin-induced inflammatory pain in rat. ( Cho, IH; Choi, SY; Chung, YM; Jung, SJ; Kim, D; Kim, JS; Lee, H; Lee, SJ; Li, HY; Oh, SB; Park, CK; Park, K; Park, SH; Piao, ZG, 2006)
"The analgesic effects of celecoxib, a cyclooxygenase-2 (COX-2) inhibitor, on formalin-induced pain are still controversial."	3.73	Analgesic effects of intrathecally administered celecoxib, a cyclooxygenase-2 inhibitor, in the tail flick test and the formalin test in rats. ( Nishiyama, T, 2006)
"The effect of methanolic extract of Asparagus pubescens was investigated on chemical, thermal-induced pain as well as fresh egg albumin-induced inflammation and pentylenetetrazol (PTZ)-induced convulsion in rodents."	3.72	Anti-nociceptive and anti-inflammatory effects of methanolic extract of Asparagus pubescens root in rodents. ( Nwafor, PA; Okwuasaba, FK, 2003)
"In both acute thermal- and inflammatory-induced pain, intrathecally administered midazolam and bupivacaine produced synergistic analgesia with decreased side effects in intrathecally catheterized rats."	3.72	Midazolam can potentiate the analgesic effects of intrathecal bupivacaine on thermal- or inflammatory-induced pain. ( Hanaoka, K; Nishiyama, T, 2003)
"We investigated the interaction between spinally administered bupivacaine and clonidine using an animal model of acute and inflammatory pain."	3.72	Intrathecal clonidine and bupivacaine have synergistic analgesia for acute thermally or inflammatory-induced pain in rats. ( Hanaoka, K; Nishiyama, T, 2004)
"The analgesic and anti-inflammatory effects of subcutaneously administered bupivacaine, morphine and tramadol on formalin-induced inflammation were compared."	3.72	The analgesic and anti-inflammatory effects of subcutaneous bupivacaine, morphine and tramadol in rats. ( Eti, Z; Gerçek, A; Göğüş, FY; Sav, A, 2004)
"Intrathecal administration of propofol had analgesic effects on inflammation-induced acute and facilitated pain but not on thermally-induced acute pain."	3.72	Intrathecal propofol has analgesic effects on inflammation-induced pain in rats. ( Hanaoka, K; Matsukawa, T; Nishiyama, T, 2004)
"The tolerance to analgesia and dependence liability of dihydroetorphine following topical application were investigated in hairless rats with and without formalin-induced inflammation."	3.71	Tolerance to analgesia and dependence liability by topical application of dihydroetorphine to hairless rats. ( Fang, L; Kawase, M; Morimoto, Y; Ohmori, S; Saito, S, 2001)
"Spinally-administered midazolam, a benzodiazepine, and clonidine, an alpha2-adrenergic receptor agonist, have significant synergistic effects on thermally-induced acute and formalin-induced inflammatory pain."	3.71	The synergistic interaction between midazolam and clonidine in spinally-mediated analgesia in two different pain models of rats. ( Hanaoka, K; Nishiyama, T, 2001)
" The effects of C-1 on the acute phase of inflammation were studied in formaldehyde-induced edema."	3.71	An investigation of the antiinflammatory effects of an extract from Cladonia rangiformis HOFFM. ( Aslan, A; Gepdiremen, A; Göçer, F; Güvenalp, Z; Süleyman, H; Yildirim, D, 2002)
"The peripheral antinociceptive effect of the selective COX-2 inhibitor celecoxib in the formalin-induced inflammatory pain was compared with that of resveratrol (COX-1 inhibitor) and diclofenac (non-selective COX inhibitor)."	3.71	Comparison of the antinociceptive effect of celecoxib, diclofenac and resveratrol in the formalin test. ( Alonso-López, R; Asomoza-Espinosa, R; Castañeda-Hernández, G; Granados-Soto, V; Ortiz, MI; Torres-López, JE, 2002)
"In the present study the antiinflammatory activity of fusidic acid was investigated in a model of formalin-induced edema formation in rats."	3.71	The effects of fusidic acid on the inflammatory response in rats. ( Batu, O; Erol, K; Kilic, FS; Usluer, G; Yildirim, E, 2002)
"Peripherally administered nitric oxide itself has no analgesic effect, but it enhances the analgesic effects of peripherally administered morphine during inflammation induced by paw formalin injection in the rat."	3.70	The interaction of FK409, a novel nitric oxide releaser, and peripherally administered morphine during experimental inflammation. ( Nozaki-Taguchi, N; Yamamoto, T, 1998)
" (1) The therapeutic effects of the cannabinoid anandamide and the putative CB2 agonist palmitoylethanolamide were tested in a model of persistent visceral pain (turpentine inflammation of the urinary bladder)."	3.70	The anti-hyperalgesic actions of the cannabinoid anandamide and the putative CB2 receptor agonist palmitoylethanolamide in visceral and somatic inflammatory pain. ( Hasnie, FS; Jaggar, SI; Rice, AS; Sellaturay, S, 1998)
"The present study shows that meloxicam dose-dependently exhibited systemic antinociceptive action when assessed against neurogenic and inflammatory pain caused by acetic acid, formalin and capsaicin models."	3.70	Antinociceptive effect of meloxicam, in neurogenic and inflammatory nociceptive models in mice. ( De Freitas, GA; Santos, AR; Vedana, EM, 1998)
"We previously reported that the morphine-induced place preference was attenuated under inflammation produced by the unilateral injection of 2."	3.70	Role of the kappa-opioid system in the attenuation of the morphine-induced place preference under chronic pain. ( Kishimoto, Y; Misawa, M; Nagase, H; Suzuki, T; Takeda, F, 1999)
"The involvement of bradykinin and some other inflammatory mediators in formalin-induced oedema and plasma extravasation was examined."	3.70	The inflammatory reaction induced by formalin in the rat paw. ( Damas, J; Liégeois, JF, 1999)
"The mechanism underlying the previous findings that the development of antinociceptive tolerance to morphine was significantly delayed in the presence of inflammatory pain induced by formalin was examined."	3.69	Involvement of pain associated anxiety in the development of morphine tolerance in formalin treated mice. ( Kaneto, H; Rahman, AF; Takahashi, M, 1994)
"Possible central noradrenergic and cholinergic modulation of acute peripheral inflammation was investigated in rats, adopting the formaldehyde-induced pedal inflammation as the experimental model."	3.69	Central noradrenergic and cholinergic modulation of formaldehyde-induced pedal inflammation and nociception in rats. ( Dumka, VK; Raviprakash, V; Tandan, SK; Tripathi, HC, 1996)
"Morphine-, methamphetamine- and cocaine-induced place preferences under inflammation produced by unilateral injections of 2."	3.69	Formalin- and carrageenan-induced inflammation attenuates place preferences produced by morphine, methamphetamine and cocaine. ( Kishimoto, Y; Misawa, M; Suzuki, T, 1996)
"The opioid antagonist, naloxone, produces equivocal effects on the magnitude of nociceptive responses in several animal models of persistent pain, including the formalin test."	3.69	Continuous intravenous infusion of naloxone does not change behavioral, cardiovascular, or inflammatory responses to subcutaneous formalin in the rat. ( Basbaum, AI; Peterson, MA; Taylor, BK, 1997)
"Possible central serotonergic and histaminergic modulation of acute peripheral inflammation was investigated in rats, adopting the formaldehyde-induced acute pedal inflammation as an experimental model."	3.69	Central serotonergic and histaminergic modulation of peripheral inflammation and nociception in rats. ( Dumka, VK; Raviprakash, V; Tandan, SK; Tripathi, HC, 1996)
"This study evaluated the role of nitric oxide (NO) in spinal cord nociceptive transmission during peripheral inflammation evoked by formalin injection into the rat paw, using N omega-nitro-L-arginine (N-Arg), an NO synthase inhibitor."	3.68	Nitric oxide synthase inhibitor blocks spinal sensitization induced by formalin injection into the rat paw. ( Mizuguchi, T; Shimoyama, N; Yamamoto, T, 1993)
"Systemic capsaicin and an analogue, olvanil (NE-19550, 4-hydroxy-3-methoxyphenyl methyl-9Z-octadecenamide), were tested for antinociceptive activity in a model of persistent pain produced by the subcutaneous injection of formalin into the rodent hind paw."	3.68	Systemic capsaicin and olvanil reduce the acute algogenic and the late inflammatory phase following formalin injection into rodent paw. ( Dickenson, A; Dray, A, 1991)
"Accumulation of 111indium-oxine (111In)-labelled platelets and the kinetics of 111In-labelled polymorphonuclear leukocytes (PMNLs) were studied in the anterior eye during neurogenic inflammation (induced by topical neutral formaldehyde) or after paracentesis in the rabbit, after formaldehyde irritation, 40 times more platelets were found in the aqueous humor 60 min later than in the control eyes and 400 times more after paracentesis."	3.67	Platelets and polymorphonuclear leukocytes in experimental ocular inflammation in the rabbit eye. ( Krootila, K; Lehtosalo, JI; Syrjälä, M; Uusitalo, H, 1989)
") was administered for three days in rats in which formaldehyde-induced arthritis was produced, and for seven days in rats in which cotton pellets were implanted."	3.66	Effect of ethanol on experimental inflammatory models. ( Khanna, NK; Mahatma, OP; Rathore, DS; Verma, GS, 1982)
" The effect was compared with the activity of hydrocortisone, phenylbutazone, sodium salicylate and cyproheptadine against different types of inflammation."	3.65	Inhibitory effect of a pyrrolizidine alkaloid, crotalaburnine, on rat paw oedema and cotton pellet granuloma. ( Ghosh, MN; Singh, H, 1974)
" Cortisone, mepyramine and sodium salicylate were effective in reducing histamine-induced inflammation, sodium salicylate being less active in the adrenalectomized animal."	3.64	Some inhibitors of histamine-induced and formaldehyde-induced inflammation in mice. ( NORTHOVER, BJ; SUBRAMANIAN, G, 1961)
"Iproniazid was found to inhibit formalin-induced oedema of the foot, dextran-induced oedema and cotton-pellet-induced granulomatous tissue in the rat."	3.64	Antiphlogistic activity of iproniazid. ( SALVATERRA, M; SETNIKAR, I; TEMELCOU, O, 1959)
"Formaldehyde (FA) is a widespread environmental organic pollutant."	2.61	Formaldehyde, Epigenetics, and Alzheimer's Disease. ( Chen, D; Jin, C; Klein, C; Wang, F; Wu, P, 2019)
"Chronic pain is a common disease that severely disrupts the quality of life."	1.91	Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. ( Cao, W; Cheng, Y; Liu, M; Qin, X; Tong, J; Wu, X, 2023)
"Heat and mechanical hyperalgesia were evaluated by radiant heat and von Frey filament tests, respectively."	1.91	Mechanisms involved in the antinociceptive and anti-inflammatory effects of xanthotoxin. ( Guo, J; Song, Y; Tang, J; Tang, Z; Yang, Y; Yu, G; Zhu, C, 2023)
"Corynoline treatment significantly suppressed the paw licking, writhing in the abdominal region, and displayed high nociceptive inhibitory reaction in a dose-related manner."	1.72	Antinociceptive and Anti-inflammatory Effect of Corynoline in Different Nociceptive and Inflammatory Experimental Models. ( Lei, F; Yan, Z, 2022)
"Acute inflammation was induced by carrageenan (1%) in vivo tests and there were several groups tested."	1.72	Antinociceptive, anti-inflammatory and antioxidant activities of the crude ethanolic extract and alkaloid fraction of Waltheria viscosissima A. St. - Hil. (Malvaceae). ( Agra Cavalcante Silva, LH; Alves de Lima, L; Caldas da Silva Dantas Viegas, C; Felício de Sousa Santos, AK; Leite Ferreira, MD; Marinho Braga, R; Nobrega de Almeida, R; Nunes de Andrade, HH; Ribeiro, MD; Sérgio Silva, A; Simões de Assis Cantalice, T; Vanderlei de Souza, MF, 2022)
" aureus and incubated with treatment for cytokine dosage and gene expression analysis."	1.72	β-caryophyllene and docosahexaenoic acid, isolated or associated, have potential antinociceptive and anti-inflammatory effects in vitro and in vivo. ( Campos, GB; da Silva, LSC; das Neves Selis, N; Marques, LM; Morbeck, LLB; Oliveira, HBM; Reis, MM; Sampaio, BA; Santos, TC; Sousa, LFB; Timenetsky, J; Viana, JCS; Yatsuda, R, 2022)
"Inflammation is one of the mechanisms responsible for these effects."	1.62	The relationship between impaired lung functions and cytokine levels in formaldehyde exposure. ( Alaguney, ME; Deniz, S; Dip, A; Eravci, DB; Iritas, SB; Oztan, O; Turksoy, VA; Tutkun, L, 2021)
" High dosage (200 μg/mL) of EEVt displayed highly significant inhibitory (p < 0."	1.62	The anti-inflammatory and analgesic activities of the ethyl acetate extract of Viburnum taitoense Hayata. ( He, S; Huang, Y; Qiu, L; Wu, X; Xie, J; Xie, Y; Xu, H; Zhang, Q; Zou, L, 2021)
"Chronic pain is recognized as an important problem in communities."	1.62	Formalin-induced inflammatory pain increases excitability in locus coeruleus neurons. ( Azizi, H; Farahani, F; Janahmadi, M; Semnanian, S; Seutin, V, 2021)
"The poncirin (30 mg/kg) treatment considerably inhibited the mechanical hyperalgesia and allodynia as well as thermal hyperalgesia and cold allodynia."	1.51	Anti-hyperalgesic properties of a flavanone derivative Poncirin in acute and chronic inflammatory pain models in mice. ( Afridi, R; Khalid, S; Khan, AU; Khan, S; Kim, YS; Rasheed, H; Shal, B; Shehzad, O; Ullah, MZ, 2019)
" But its long-term administration increases the risk of complications of pharmacotherapy."	1.51	Study of Anti-inflammatory Activity of a New Non-opioid Analgesic on the Basis of a Selective Inhibitor of TRPA1 Ion Channels. ( Beskhmelnitsyna, EA; Kulikov, AL; Peresypkina, AA; Pokrovskii, MV; Varavin, EI, 2019)
" TMJ tissue, trigeminal ganglion, and subnucleus caudalis were collected for TNF-α dosage (ELISA)."	1.48	The efficacy of a lectin from Abelmoschus Esculentus depends on central opioid receptor activation to reduce temporomandibular joint hypernociception in rats. ( Alves, SM; Bezerra, MM; Chaves, HV; Clemente-Napimoga, JT; Cristino Filho, G; de Assis, EL; de Lacerda, JTJG; do Val, DR; Freitas, RS; Gadelha, CAA; Gadelha, TS; Gomes, FIF; Pinto, VPT; Vieira, LV, 2018)
"Intrathecal AIBP reverses established allodynia in mice in which pain states were induced by the chemotherapeutic cisplatin, intraplantar formalin, or intrathecal LPS, all of which are pro-nociceptive interventions known to be regulated by TLR4 signaling."	1.48	Inhibition of Neuroinflammation by AIBP: Spinal Effects upon Facilitated Pain States. ( An, EJ; Bae, YS; Choi, SH; Corr, M; Kim, J; Low, H; Miller, YI; Ramachandran, R; Schneider, DA; Sviridov, D; Woller, SA; Yaksh, TL, 2018)
"Most drugs used to treat pain and inflammation have potential side effects, which makes it necessary to search for new sources of bioactive molecules."	1.48	LASSBio-1586, an N-acylhydrazone derivative, attenuates nociceptive behavior and the inflammatory response in mice. ( Alencar Filho, EB; Almeida, JRGDS; Barreiro, EJL; Diniz, TC; Lavor, ÉM; Lima, LM; Lima-Saraiva, SRG; Mendes, RL; Oliveira Júnior, RG; Silva, JC; Silva, MGE; Soares, JMD, 2018)
" Kidney function was assessed by dosage of uric acid, creatinine and urea."	1.46	The exposure to formaldehyde causes renal dysfunction, inflammation and redox imbalance in rats. ( Bandeira, ACB; Bezerra, FS; Campos, KKD; Costa, GP; Machado, DF; Nardeli, CR; Pena, KB; Ramos, CO; Talvani, A, 2017)
"Sinomenine, which is a main bioactive ingredient in Sinomenium acutum, has been reported to have an analgesic effect in diverse pain animal models."	1.46	Sinomenine produces peripheral analgesic effects via inhibition of voltage-gated sodium currents. ( Kang, Y; Kim, HB; Lee, JY; Oh, SB; Won, J; Yoon, SY, 2017)
" We evaluated the impact of TLR and Notch signaling on ERD in a murine model by administering CpG, an agonist of TLR9, in combination with L685,458, an inhibitor of Notch signaling during FI-RSV immunization."	1.46	CpG in Combination with an Inhibitor of Notch Signaling Suppresses Formalin-Inactivated Respiratory Syncytial Virus-Enhanced Airway Hyperresponsiveness and Inflammation by Inhibiting Th17 Memory Responses and Promoting Tissue-Resident Memory Cells in Lung ( Deng, Y; Du, X; Hai, Y; Li, H; Li, N; Li, W; Wei, L; Yin, W; Zeng, R; Zhang, L; Zhang, Z; Zheng, B, 2017)
"Inflammation is a local defensive reaction of a host to cellular injury or infection."	1.43	Acacia ferruginea inhibits inflammation by regulating inflammatory iNOS and COX-2. ( Guruvayoorappan, C; Sakthivel, KM, 2016)
"Insufficient sleep and chronic pain are public health epidemics."	1.43	Sleep Deprivation and Recovery Sleep Prior to a Noxious Inflammatory Insult Influence Characteristics and Duration of Pain. ( Vanini, G, 2016)
"Orofacial pain is a common clinical symptom that is accompanied by tooth pain, migraine and gingivitis."	1.43	Acid-sensing ion channels in trigeminal ganglion neurons innervating the orofacial region contribute to orofacial inflammatory pain. ( Chen, JG; Fang, P; Fu, H; Hu, ZL; Jin, Y; Ni, M; Wang, F; Yu, XW; Zheng, JY; Zhou, HY; Zhou, J, 2016)
"Pain is one of the most challenging and stressful conditions to patients with sickle cell disease (SCD) and their clinicians."	1.43	CaMKIIα underlies spontaneous and evoked pain behaviors in Berkeley sickle cell transgenic mice. ( Chen, Y; DeSimone, J; He, Y; Lu, J; Molokie, RE; Tian, X; Wang, ZJ; Wilkie, DJ; Xiao, C; Yang, C, 2016)
"In the pleurisy model, induced by carrageenan, treatment with SA inhibited important events involved in inflammatory responses, namely leukocyte influx, plasma leakage, and increased inflammatory mediators (TNF-α, IL-1β, and chemokine CXCL1), in the pleural exudate."	1.42	Antinociceptive and anti-inflammatory activity of the siaresinolic acid, a triterpene isolated from the leaves of Sabicea grisea Cham. & Schltdl. var. grisea. ( Barreto, E; Conserva, LM; de Araújo, AF; de Oliveira, AM; de Souza Ferro, JN; Lyra Lemos, RP, 2015)
"Formaldehyde (FA) is an environmental pollutant widely used in industry."	1.42	Short-term exposure to formaldehyde promotes oxidative damage and inflammation in the trachea and diaphragm muscle of adult rats. ( Bandeira, AC; Bezerra, FS; Lima, LF; Lima, WG; Murta, GL; Nardeli, CR, 2015)
"otitidis elicits cytokines observed in middle ear effusions was supported; the need to use recent clinical isolates in studies of pathogenesis was highlighted."	1.40	In vitro inflammatory responses elicited by isolates of Alloiococcus otitidis obtained from children with otitis media with effusion. ( Ashhurst-Smith, C; Blackwell, CC; Burns, CJ; Hall, ST; Stuart, J, 2014)
"Acute pain was determined using the hot plate test (thermal nociception) and the formalin test (inflammatory pain)."	1.40	The oral administration of trans-caryophyllene attenuates acute and chronic pain in mice. ( Andersen, ML; Carlini, EL; Gama, VS; Molska, GR; Paula-Freire, LI, 2014)
"CFA-induced hind paw mechanical allodynia (P < ."	1.40	Suppression of voluntary wheel running in rats is dependent on the site of inflammation: evidence for voluntary running as a measure of hind paw-evoked pain. ( Grace, PM; Maier, SF; Strand, KA; Watkins, LR, 2014)
"The thermal hyperalgesia and mechanical allodynia induced by carrageenan injection and spared-nerve injury were significantly reduced in Adv/Ano1fl/fl mice."	1.40	Anoctamin 1 contributes to inflammatory and nerve-injury induced hypersensitivity. ( Cho, H; Jung, J; Lee, B; Oh, U; Yang, DJ; Yang, YD, 2014)
" Experiments showed that administration of extract (25, 50 and 100 mg kg(-1)) could induced analgesia in a dose-response manner in both phases of formalin test."	1.38	Effects of Papaver rhoeas (L.) extract on formalin-induced pain and inflammation in mice. ( Delfan, B; Esfandiari, B; Ghahramani, M; Jafari, F; Mojabi, N; Najafi-Abedi, A; Rahmani, B; Ranjbaran, M; Saeed-Abadi, S; Sahraei, H, 2012)
"We evaluated the modulatory role of the groundwater contaminant arsenic on the pharmacodynamic responses of the nonsteroidal analgesic-antipyretic drug ketoprofen and the major pro-inflammatory mediators linked to the mechanism of ketoprofen's therapeutic effects."	1.38	Subacute arsenic exposure through drinking water reduces the pharmacodynamic effects of ketoprofen in male rats. ( Ahmad, W; Chanderashekara, HH; Prawez, S; Sankar, P; Sarkar, SN; Tandan, SK, 2012)
" At the same time, the pharmacokinetic assay of AGF was also made."	1.38	Pharmacological and pharmacokinetic studies with agaricoglycerides, extracted from Grifola frondosa, in animal models of pain and inflammation. ( Cui, B; Han, C, 2012)
"crassifolius for the treatment of pain and inflammation."	1.38	Anti-nociceptive and anti-inflammatory effects of Croton crassifolius ethanol extract. ( Fang, F; Wang, G; Yang, L; Yu, L; Zhao, J, 2012)
"Inflammation is a protective immune response against harmful stimuli whose long time continuation results in host disease."	1.38	Exploring the anti-inflammatory activity of a novel 2-phenylquinazoline analog with protection against inflammatory injury. ( Banerjee, S; Bose, D; Chatterjee, N; Chattopadhyay, D; Das, S; Saha, KD, 2012)
"armatum in the treatment of inflammation and pain is warranted."	1.37	Antinociceptive and anti-inflammatory activities of ethyl acetate fraction from Zanthoxylum armatum in mice. ( Cai, CC; Deng, YX; Guo, T; Pan, SL; Wang, YL; Xie, H; Yao, CY, 2011)
" The inhibition of oedema formation increased with increasing dosage from 25 to 100mg/kg."	1.37	Analgesic effects and anti-inflammatory properties of the crude methanolic extract of Schwenckia americana Linn (Solanaceae). ( Abdullahi, N; Adebisi, I; Chika, A; Jimoh, AO; Umar, MT, 2011)
"Evaluation of pain is a critical issue in human pathologies but also in animal experimentation."	1.37	Poincaré plot descriptors of heart rate variability as markers of persistent pain expression in freely moving rats. ( Charlet, A; Poisbeau, P; Rodeau, JL, 2011)
"The inflammation is one of the initial parameter for most of the disorders occurring in the body."	1.37	Differential inhibitory potencies of alcoholic extract of different parts of Dryopteris chrysocoma on inflammation in mice and rats. ( Ahmad, M; Jahan, N; Mohammad, N; Rehman, AB; Ullah, O, 2011)
"Morphine (3-9 mg/kg) was injected intraperitoneally (i."	1.36	Role of nitric oxide in the rat hippocampal CA1 in morphine antinociception. ( Hashemi, M; Karami, M; Sahebgharani, M; Zarrindast, MR, 2010)
"Moreover, in two neuropathic pain models induced by chronic constriction and spared nerve injury, KST5468 significantly increased the mechanical pain threshold."	1.36	KST5468, a new T-type calcium channel antagonist, has an antinociceptive effect on inflammatory and neuropathic pain models. ( Choo, H; Chung, HJ; Kim, HJ; Koh, HY; Lee, JE; Lee, MJ; Lee, SC; Pae, AN; Shin, TJ, 2010)
"Mechanical hyperalgesia induced by Freund's Complete Adjuvant (CFA) was attenuated by 3-ASP administration to mice (maximal inhibition of 42+/-11%)."	1.35	Antinociceptive and anti-allodynic effects of 3-alkynyl selenophene on different models of nociception in mice. ( Bortolatto, CF; Jesse, CR; Nogueira, CW; Savegnago, L; Wilhelm, EA, 2009)
"It also produced thermal allodynia in response to cold (paw acetone test: 200% increase of allodynia score during week 3-5) and heat (42 degrees C tail immersion test: 15% decrease of withdrawal threshold, from week 2 onward)."	1.35	Chronic restraint stress induces mechanical and cold allodynia, and enhances inflammatory pain in rat: Relevance to human stress-associated painful pathologies. ( Bardin, L; Depoortère, R; Malfetes, N; Newman-Tancredi, A, 2009)
"Tramadol is an atypical analgesic with a unique dual mechanism of action."	1.35	The novel compound (+/-)-1-[10-((E)-3-Phenyl-allyl)-3,10-diaza-bicyclo[4.3.1]dec-3-yl]-propan-1-one (NS7051) attenuates nociceptive transmission in animal models of experimental pain; a pharmacological comparison with the combined mu-opioid receptor agoni ( Baek, CA; Erichsen, HK; Munro, G; Nielsen, AN; Nielsen, EØ; Peters, D; Scheel-Kruger, J; Weikop, P, 2008)
" Furthermore, A-425619 maintained efficacy in the postoperative pain model after twice daily dosing p."	1.33	A-425619 [1-isoquinolin-5-yl-3-(4-trifluoromethyl-benzyl)-urea], a novel transient receptor potential type V1 receptor antagonist, relieves pathophysiological pain associated with inflammation and tissue injury in rats. ( El Kouhen, R; Faltynek, CR; Gauvin, DM; Gomtsyan, A; Honore, P; Jarvis, MF; Lee, CH; Marsh, K; Mikusa, J; Sullivan, JP; Wismer, CT; Zhong, C; Zhu, CZ, 2005)
"NPB-deficient mice also exhibit hyperalgesia in response to inflammatory pain."	1.33	Neuropeptide B-deficient mice demonstrate hyperalgesia in response to inflammatory pain. ( Beuckmann, CT; Garry, MG; Hammer, RE; Kelly, MA; Motoike, T; Richardson, JA; Sinton, CM; Williams, SC; Yanagisawa, M, 2005)
"Ambroxol's effects were compared with those of gabapentin."	1.33	Ambroxol, a Nav1.8-preferring Na(+) channel blocker, effectively suppresses pain symptoms in animal models of chronic, neuropathic and inflammatory pain. ( Arndt, K; Gaida, W; Klinder, K; Weiser, T, 2005)
" Acute and chronic administration of 1% or 2."	1.33	Nitric oxide and c-Jun N-terminal kinase are involved in the development of dark neurons induced by inflammatory pain. ( Ahmadiani, A; Hassanzadeh, P, 2006)
"Neuropathic pain was induced by either ligation of left L5/L6 spinal nerves or administration of streptozotocin (50 mg/kg, i."	1.33	Benfotiamine relieves inflammatory and neuropathic pain in rats. ( Caram-Salas, NL; Granados-Soto, V; Medina-Santillán, R; Reyes-García, G; Rocha-González, HI; Sánchez-Ramírez, GM; Vidal-Cantú, GC, 2006)
"However, they attenuated hyperalgesia in several nociceptive models associated with spinal sensitization including direct spinal activation (intrathecal substance P) and peripheral tissue inflammation (intraplantar formalin or carrageenan)."	1.32	Activation of p38 mitogen-activated protein kinase in spinal microglia is a critical link in inflammation-induced spinal pain processing. ( Calcutt, NA; Campana, WM; Catalano, R; Feng, Y; Freshwater, JD; Marsala, M; Protter, AA; Scott, B; Svensson, CI; Westerlund, A; Yaksh, TL, 2003)
" Repeated intraperitoneal injections were, therefore, chosen as the dosing regimen."	1.32	Specific Inhibition of IkappaB kinase reduces hyperalgesia in inflammatory and neuropathic pain models in rats. ( Geisslinger, G; Gühring, H; Kunz, S; Michaelis, M; Niederberger, E; Ritzeler, O; Schmidt, R; Tegeder, I, 2004)
"As clinical pain is characterized by hyperalgesia, we evaluated the effects of NSAIDs with similar chemical structures but different selectivities for cyclo-oxygenase (COX)-1 and COX-2 in a new behavioural model of central hyperalgesia in rats."	1.31	Effects of lornoxicam, piroxicam, and meloxicam in a model of thermal hindpaw hyperalgesia induced by formalin injection in rat tail. ( Bianchi, M; Panerai, AE, 2002)
"Pretreatment with morphine (2 mg/kg) attenuated, in a naloxone-reversible manner, the nociceptive behaviour observed following intradental application of capsaicin."	1.31	Nociceptive behaviour induced by dental application of irritants to rat incisors: a new model for tooth inflammatory pain. ( Chidiac, JJ; Hawwa, NN; Jabbur, SJ; Jurjus, AR; Massaad, CA; Rifai, K; Saadé, NE, 2002)
" The initial slopes of the dose-response curves were used to calculate the inflammatory potential, or potency factor (PF), of the samples."	1.31	Interleukin-8 secretion from monocytic cell lines for evaluation of the inflammatory potential of organic dust. ( Allermann, L; Poulsen, OM, 2002)

Timeframe	Studies, this research(%)	All Research%
pre-1990	77 (15.62)	18.7374
1990's	43 (8.72)	18.2507
2000's	138 (27.99)	29.6817
2010's	183 (37.12)	24.3611
2020's	52 (10.55)	2.80

Trial	Phase	Enrollment	Study Type	Start Date	Status
Oxidative Stress and Surgical Recovery[NCT04732000]	Phase 2	21 participants (Actual)	Interventional	2021-07-01	Active, not recruiting
Effect of Ambroxol on the Inflammatory Markers and Clinical Outcome of Patients With Diabetic Peripheral Neuropathy[NCT05558878]		80 participants (Anticipated)	Interventional	2022-10-01	Not yet recruiting
Iontophoresis Effects on Senses[NCT02487914]	Phase 2/Phase 3	30 participants (Actual)	Interventional	2013-01-31	Completed
Comparison of Cyanoacrylate Tissue Adhesives to Polytetrafluoroethylene (PTFE) Sutures in the Donor Site of Connective Tissue Grafts- A Randomized Clinical Trial[NCT02935426]		32 participants (Anticipated)	Interventional	2017-01-09	Recruiting
Center-Based and Home-Based Walking Exercise Intervention to Reduce Fatigue in Older Breast Cancer Survivors[NCT05684367]		24 participants (Anticipated)	Interventional	2023-11-29	Recruiting
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Article	Year
Formaldehyde, Epigenetics, and Alzheimer's Disease. Chemical research in toxicology, 2019, 05-20, Volume: 32, Issue:5 Topics: Alzheimer Disease; Amyloid beta-Peptides; Animals; Chromatin; DNA; Epigenesis, Genetic; Epigenomics;	2019
Cross-linking in biomaterials: a primer for clinicians. Plastic and reconstructive surgery, 2012, Volume: 130, Issue:5 Suppl 2 Topics: Abdominal Wall; Acellular Dermis; Animals; Collagen; Cross-Linking Reagents; Foreign-Body Reaction;	2012
[Anti-inflammatory properties of antidepressants (a review of experimental results)]. Eksperimental'naia i klinicheskaia farmakologiia, 2012, Volume: 75, Issue:11 Topics: Animals; Anti-Inflammatory Agents; Antidepressive Agents; Carrageenan; Cytokines; Drug Administratio	2012
Physiological and pathological implications of semicarbazide-sensitive amine oxidase. Biochimica et biophysica acta, 2003, Apr-11, Volume: 1647, Issue:1-2 Topics: Acetone; Adipocytes; Amine Oxidase (Copper-Containing); Animals; Catalysis; Cell Adhesion Molecules;	2003
[Experimental methods in pain using neuropathic and inflammatory animal models]. Nihon yakurigaku zasshi. Folia pharmacologica Japonica, 2007, Volume: 130, Issue:1 Topics: Animals; Diagnostic Techniques, Neurological; Disease Models, Animal; Formaldehyde; Hot Temperature;	2007
[Possibilities and limitations of the use of rat paw edemas as models of inflammation. 1. Review on edemas as models and their possible use]. Die Pharmazie, 1975, Volume: 30, Issue:7 Topics: Animals; Anti-Inflammatory Agents; Bradykinin; Carrageenan; Cell Migration Inhibition; Dextrans; Dis	1975
Electrophysiological approaches to the study of bradykinin and nitric oxide in inflammatory pain. Agents and actions. Supplements, 1992, Volume: 38 ( Pt 2) Topics: Animals; Arginine; Bradykinin; Formaldehyde; Inflammation; Neurons; NG-Nitroarginine Methyl Ester; N	1992
Contact sensitizers in resins based on phenol and formaldehyde. Acta dermato-venereologica. Supplementum, 1985, Volume: 119 Topics: Allergens; Animals; Chemical Phenomena; Chemistry; Cross Reactions; Dermatitis, Contact; Dermatitis,	1985
Pulpectomy, a review of histological studies. Svensk tandlakare tidskrift. Swedish dental journal, 1968, Volume: 61, Issue:10 Topics: Animals; Anti-Bacterial Agents; Anti-Infective Agents, Local; Calcium Hydroxide; Dental Materials; D	1968

formaldehyde and Inflammation

Research Excerpts

Research

Studies (493)

Authors

Clinical Trials (5)

Trial Overview

Reviews

Trials

Other Studies

Authors	Studies
Skobowiat, C	1
Gonkowski, S	1
Calka, J	1
Miyagi, M	1
Ishikawa, T	1
Kamoda, H	1
Orita, S	1
Kuniyoshi, K	1
Ochiai, N	1
Kishida, S	1
Nakamura, J	1
Eguchi, Y	1
Arai, G	1
Suzuki, M	1
Aoki, Y	1
Toyone, T	1
Takahashi, K	1
Inoue, G	1
Ohtori, S	1
Hirt, UA	1
Leist, M	1
Singh, R	1
Vidal, B	1
Ascanio, J	1
Redhu, NS	1
Ruiz de Somocurcio, J	1
Majid, A	1
VanderLaan, PA	1
Gangadharan, SP	1
Wilt, S	1
Kodani, S	1
Valencia, L	1
Hudson, PK	1
Sanchez, S	1
Quintana, T	1
Morisseau, C	1
Hammock, BD	1
Kandasamy, R	1
Pecic, S	1
Ikram, J	1

Article	Year
Phenotyping of sympathetic chain ganglia (SChG) neurons in porcine colitis. The Journal of veterinary medical science, 2010, Volume: 72, Issue:10 Topics: Amidines; Animals; Colitis; Colon; Female; Formaldehyde; Ganglia, Sympathetic; Immunohistochemistry;	2010
Assessment of gait in a rat model of myofascial inflammation using the CatWalk system. Spine, 2011, Oct-01, Volume: 36, Issue:21 Topics: Animals; Automation; Behavior, Animal; Biomechanical Phenomena; Calcitonin Gene-Related Peptide; Dis	2011
Rapid, noninflammatory and PS-dependent phagocytic clearance of necrotic cells. Cell death and differentiation, 2003, Volume: 10, Issue:10 Topics: Animals; Annexin A5; Antibodies, Monoclonal; Apoptosis; Calcium; CD36 Antigens; Cell Line; Cell Memb	2003
Pilot Gene Expression and Histopathologic Analysis of Tracheal Resections in Tracheobronchomalacia. The Annals of thoracic surgery, 2022, Volume: 114, Issue:5 Topics: Elastin; Fibroblast Growth Factors; Formaldehyde; Gene Expression; Humans; Inflammation; Intercellul	2022
Further exploration of the structure-activity relationship of dual soluble epoxide hydrolase/fatty acid amide hydrolase inhibitors. Bioorganic & medicinal chemistry, 2021, 12-01, Volume: 51 Topics: Acute Pain; Amidohydrolases; Animals; Anti-Inflammatory Agents, Non-Steroidal; Dose-Response Relatio	2021
Ethyl-acetate extract of tara mira (Eruca sativa) alleviates the inflammation and rheumatoid arthritis in rats. Pakistan journal of pharmaceutical sciences, 2021, Volume: 34, Issue:5(Suppleme Topics: Acetates; Animals; Anti-Inflammatory Agents; Arthritis, Experimental; Arthritis, Rheumatoid; Carrage	2021
Neurokinin receptor mechanisms in forebrain medial septum modulate nociception in the formalin model of inflammatory pain. Scientific reports, 2021, 12-21, Volume: 11, Issue:1 Topics: Animals; Disinfectants; Formaldehyde; Hippocampus; Inflammation; Male; Nociception; Pain; Piperidine	2021
Multi-region local field potential signatures in response to the formalin-induced inflammatory stimulus in male rats. Brain research, 2022, 03-01, Volume: 1778 Topics: Amygdala; Animals; Brain Waves; Disease Models, Animal; Disinfectants; Electrophysiological Phenomen	2022
Toxicity studies and anti-arthritic effect of mandelic acid (2-hydroxy -2-phenyl acetic acid) using in vitro and in vivo techniques. Pakistan journal of pharmaceutical sciences, 2021, Volume: 34, Issue:6(Suppleme Topics: Albumins; Animals; Antirheumatic Agents; Arthritis, Experimental; Egg Proteins; Erythrocytes; Formal	2021
Antinociceptive and Anti-inflammatory Effect of Corynoline in Different Nociceptive and Inflammatory Experimental Models. Applied biochemistry and biotechnology, 2022, Volume: 194, Issue:10 Topics: Analgesics; Animals; Anti-Inflammatory Agents; Berberine Alkaloids; Capsaicin; Carrageenan; Cytokine	2022
Antinociceptive, anti-inflammatory and antioxidant activities of the crude ethanolic extract and alkaloid fraction of Waltheria viscosissima A. St. - Hil. (Malvaceae). Journal of ethnopharmacology, 2022, Jun-28, Volume: 292 Topics: Alkaloids; Analgesics; Animals; Anti-Inflammatory Agents; Antioxidants; Carrageenan; Dexamethasone;	2022
Emodin Reduces Inflammatory and Nociceptive Responses in Different Pain-and Inflammation-Induced Mouse Models. Combinatorial chemistry & high throughput screening, 2023, Volume: 26, Issue:5 Topics: Analgesics; Animals; Anti-Inflammatory Agents; Anti-Inflammatory Agents, Non-Steroidal; Capsaicin; E	2023
Crohn's disease may promote inflammation in IgA nephropathy: a case-control study of patients undergoing kidney biopsy. Virchows Archiv : an international journal of pathology, 2022, Volume: 481, Issue:4 Topics: Biopsy; Case-Control Studies; Crohn Disease; Formaldehyde; Galactose; Glomerulonephritis, IGA; Human	2022
Synthesis, Molecular Docking and Biological Evaluation of N-Substituted Indole Derivatives as Potential Anti-Inflammatory and Antioxidant Agents. Chemistry & biodiversity, 2022, Volume: 19, Issue:9 Topics: Anti-Inflammatory Agents; Anti-Inflammatory Agents, Non-Steroidal; Antioxidants; Ascorbic Acid; Carr	2022
Anti-inflammatory potential of berberine-rich extract via modulation of inflammation biomarkers. Journal of food biochemistry, 2022, Volume: 46, Issue:12 Topics: Animals; Anti-Inflammatory Agents; Antioxidants; Berberine; Carrageenan; Formaldehyde; Hypoglycemic	2022
Potential anti-arthritic and analgesic properties of essential oil and viridiflorol obtained from Allophylus edulis leaves in mice. Journal of ethnopharmacology, 2023, Jan-30, Volume: 301 Topics: Analgesics; Animals; Anti-Inflammatory Agents; Carrageenan; Dexamethasone; Dihydroxyphenylalanine; D	2023
EXPERIMENTAL RESEARCH OF THE EFFECT OF COXIBS ON THE CERULOPLASMIN LEVEL IN RAT SERUM ON THE FORMALIN-INDUCED EDEMA MODEL. Wiadomosci lekarskie (Warsaw, Poland : 1960), 2022, Volume: 75, Issue:9 pt 1 Topics: Animals; Anti-Inflammatory Agents; Benzenesulfonamides; Celecoxib; Ceruloplasmin; Cyclooxygenase 2 I	2022
β-caryophyllene and docosahexaenoic acid, isolated or associated, have potential antinociceptive and anti-inflammatory effects in vitro and in vivo. Scientific reports, 2022, 11-10, Volume: 12, Issue:1 Topics: Analgesics; Animals; Anti-Inflammatory Agents; Antioxidants; Docosahexaenoic Acids; Edema; Formaldeh	2022
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Caspase-11 contributes to pain hypersensitivity in the later phase of CFA-induced pain of mice. Brain research, 2023, 02-15, Volume: 1801 Topics: Animals; Chronic Pain; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Hypersensitivity; Inflammation	2023
Biochemical Pilot Study on Effects of Pomegranate Seed Oil Extract and Cosmetic Cream on Neurologically Mediated Skin Inflammation in Animals and Humans: A Comparative Observational Study. Molecules (Basel, Switzerland), 2023, Jan-16, Volume: 28, Issue:2 Topics: Animals; Dermatitis; Formaldehyde; Humans; Inflammation; Pilot Projects; Plant Extracts; Plant Oils;	2023
Detection of Enterobius vermicularis in archived formalin-fixed paraffin-embedded (FFPE) appendectomy blocks: It's potential to compare genetic variations based on mitochondrial DNA (cox1) gene. PloS one, 2023, Volume: 18, Issue:2 Topics: Animals; Appendectomy; Appendicitis; DNA, Mitochondrial; Enterobiasis; Enterobius; Formaldehyde; Gen	2023
UHPLC-MS and GC-MS phytochemical profiling, amelioration of pain and inflammation with chloroform extract of Funaria hygrometrica Hedw. via modulation of inflammatory biomarkers. Inflammopharmacology, 2023, Volume: 31, Issue:4 Topics: Analgesics; Animals; Anti-Inflammatory Agents; Carrageenan; Chloroform; Chromatography, High Pressur	2023
Orofacial anti-hypernociceptive effect of citral in acute and persistent inflammatory models in rats. Archives of oral biology, 2023, Volume: 152 Topics: Analgesics; Animals; Facial Pain; Formaldehyde; Hyperalgesia; Inflammation; Rats	2023
Acupuncture and laserpuncture as a therapeutic approach for nociception and inflammation: An experimental study in mice. Anais da Academia Brasileira de Ciencias, 2023, Volume: 95, Issue:suppl 1 Topics: Acupuncture Therapy; Analgesics; Animals; Carrageenan; Edema; Formaldehyde; Inflammation; Male; Mice	2023
Mechanisms involved in the antinociceptive and anti-inflammatory effects of xanthotoxin. The European journal of neuroscience, 2023, Volume: 58, Issue:7 Topics: Acute Pain; Analgesics; Animals; Anti-Inflammatory Agents; Capsaicin; Chronic Pain; Formaldehyde; Ga	2023
Exploring the therapeutic potential of Prinsepia utilis Royle seed oil: A comprehensive study on chemical composition, physicochemical properties, anti-inflammatory, and analgesic activities. Journal of ethnopharmacology, 2024, Jan-30, Volume: 319, Issue:Pt 3 Topics: Analgesics; Animals; Anti-Inflammatory Agents; Carrageenan; Edema; Formaldehyde; Gas Chromatography-	2024
Drug design, development and therapy, 2023, Volume: 17 Topics: Analgesics; Animals; Disease Models, Animal; Ethanol; Fallopia japonica; Formaldehyde; Inflammation;	2023
Comparison of four softening agents used on formalin-fixed paraffin-embedded nail biopsies with inflammatory disease. Journal of histotechnology, 2020, Volume: 43, Issue:1 Topics: Adolescent; Adult; Biopsy; Female; Formaldehyde; Humans; Inflammation; Male; Microtomy; Middle Aged;	2020
Spinal TASK-1 and TASK-3 modulate inflammatory and neuropathic pain. European journal of pharmacology, 2019, Nov-05, Volume: 862 Topics: Animals; Disease Models, Animal; Down-Regulation; Female; Formaldehyde; Ganglia, Spinal; Humans; Hyp	2019
Anti-hyperalgesic properties of a flavanone derivative Poncirin in acute and chronic inflammatory pain models in mice. BMC pharmacology & toxicology, 2019, 09-11, Volume: 20, Issue:1 Topics: Acetic Acid; Animals; Anti-Inflammatory Agents, Non-Steroidal; Carrageenan; Chronic Pain; Disease Mo	2019
The phthalimide analogues N-3-hydroxypropylphthalimide and N-carboxymethyl-3-nitrophthalimide exhibit activity in experimental models of inflammatory and neuropathic pain. Pharmacological reports : PR, 2019, Volume: 71, Issue:6 Topics: Analgesics; Animals; Disease Models, Animal; Formaldehyde; Freund's Adjuvant; Hyperalgesia; Inflamma	2019
Bioinspired in Vitro Lung Airway Model for Inflammatory Analysis via Hydrophobic Nanochannel Membrane with Joint Three-Phase Interface. Analytical chemistry, 2019, 12-17, Volume: 91, Issue:24 Topics: Aluminum Oxide; Benzene; Cell Culture Techniques; Cell Line; Cell Survival; Epithelial Cells; Formal	2019