gallic acid has been researched along with Innate Inflammatory Response in 71 studies
gallate : A trihydroxybenzoate that is the conjugate base of gallic acid.
Excerpt | Relevance | Reference |
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" Of interest is gallic acid, a trihydroxybenzoic acid that has progressively demonstrated robust anti-obesity capabilities in various experimental models." | 8.98 | Inflammation and Oxidative Stress in an Obese State and the Protective Effects of Gallic Acid. ( Dludla, PV; Jack, B; Louw, J; Mazibuko-Mbeje, SE; Mkandla, Z; Mutize, T; Nkambule, BB; Orlando, P; Silvestri, S; Tiano, L, 2018) |
" These physiological characteristics have promoted the study of poly-gallic acid (PGAL), a poly-oxidized form of gallic acid reported to be effective in in vitro models of inflammation." | 8.12 | Anti-inflammatory and Antioxidant Effect of Poly-gallic Acid (PGAL) in an In Vitro Model of Synovitis Induced by Monosodium Urate Crystals. ( Fernández-Torres, J; Gimeno, M; Luján-Juárez, IA; Martínez-Flores, K; Martínez-López, V; Montaño-Armendariz, N; Sánchez-Sánchez, R; Zamudio-Cuevas, Y, 2022) |
"Leonurine hydrochloride (LH) has been reported to exhibit a number of biological properties such as suppression of inflammation." | 7.96 | Leonurine Hydrochloride Suppresses Inflammatory Responses and Ameliorates Cartilage Degradation in Osteoarthritis via NF-κB Signaling Pathway. ( Chen, C; Hu, N; Huang, W; Liang, X; Zhu, Z, 2020) |
"The present study was aimed to investigate the effect of diet derived AGEs (dAGEs) on the circulatory levels of pro-inflammatory cytokines, chemokines and to evaluate the protective efficacy of natural anti-oxidants curcumin (CU) and gallic acid (GA) respectively against the dAGEs-induced systemic inflammation in experimental Swiss albino mice." | 7.88 | Diet with high content of advanced glycation end products induces systemic inflammation and weight gain in experimental mice: Protective role of curcumin and gallic acid. ( Babu, AA; Chandrasekar, N; Dhanusu, S; Kalaiarasu, LP; Krishna, K; Manivasagam, S; Sowndhar Rajan, B; Vellaichamy, E, 2018) |
" According to pharmacokinetic studies, the absorption and elimination of GA after oral administration are fast, while the structural optimization or dosage form adjustment of GA is beneficial to increase its bioavailability." | 6.72 | Gallic acid: Pharmacological activities and molecular mechanisms involved in inflammation-related diseases. ( Ai, X; Bai, J; Chen, X; Hou, Y; Meng, X; Tang, C; Wang, X; Zhang, Y, 2021) |
"Co-treatment with gallic acid preserved all these changes approximately to the normal levels." | 5.62 | Gallic acid suppresses inflammation and oxidative stress through modulating Nrf2-HO-1-NF-κB signaling pathways in elastase-induced emphysema in rats. ( Badavi, M; Dianat, M; Mard, SA; Radan, M; Sohrabi, F, 2021) |
"Acute lung injury (ALI) is an inflammatory process, and has high incidence and mortality." | 5.56 | Anti-inflammatory effect of octyl gallate in alveolar macrophages cells and mice with acute lung injury. ( Antunes, GL; da Costa, MS; de Oliveira, JR; de Souza Basso, B; Donadio, MVF; Gracia-Sancho, J; Haute, GV; Kaiber, DB; Levorse, VGS; Luft, C; Silveira, JS, 2020) |
"Nonalcoholic fatty liver disease (NAFLD) is one of the most common causes of chronic liver disease, sometimes ranges from simple steatosis to nonalcoholic steatohepatitis (NASH)." | 5.56 | Gallic Acid Inhibits Lipid Accumulation via AMPK Pathway and Suppresses Apoptosis and Macrophage-Mediated Inflammation in Hepatocytes. ( Iida, K; Kishimoto, Y; Kondo, K; Mabashi-Asazuma, H; Sato, A; Tanaka, M, 2020) |
"Nano-gallic acid was prepared by double emulsions-solvent evaporation technique using Eudragit RS 100 polymer and polyvinyl alcohol as carrier." | 5.56 | Protective effect of gallic acid and gallic acid-loaded Eudragit-RS 100 nanoparticles on cisplatin-induced mitochondrial dysfunction and inflammation in rat kidney. ( Atefi Khah, M; Dehghani, MA; Khorsandi, L; Mahdavinia, M; Moghimipour, E; Shakiba Maram, N, 2020) |
"Methyl gallate (MG) is a prevalent polyphenol in the plant kingdom, which may be related to the effects of several medicinal plants." | 5.56 | Methyl gallate attenuates inflammation induced by Toll-like receptor ligands by inhibiting MAPK and NF-Κb signaling pathways. ( Correa, LB; Cunha, TM; Henriques, MG; Manchope, MF; Rosas, EC; Seito, LN; Verri, WA, 2020) |
"Neurodegenerative diseases comprise demyelination and synaptic loss." | 5.51 | Gallic and vanillic acid suppress inflammation and promote myelination in an in vitro mouse model of neurodegeneration. ( Jamali, KS; Kamal, A; Khan, F; Saify, ZS; Siddiqui, S, 2019) |
"However, the effects of GA on ulcerative colitis (UC) remain unknown." | 5.51 | Gallic acid improved inflammation via NF-κB pathway in TNBS-induced ulcerative colitis. ( Gu, P; Shen, H; Zhu, L, 2019) |
" Of interest is gallic acid, a trihydroxybenzoic acid that has progressively demonstrated robust anti-obesity capabilities in various experimental models." | 4.98 | Inflammation and Oxidative Stress in an Obese State and the Protective Effects of Gallic Acid. ( Dludla, PV; Jack, B; Louw, J; Mazibuko-Mbeje, SE; Mkandla, Z; Mutize, T; Nkambule, BB; Orlando, P; Silvestri, S; Tiano, L, 2018) |
" These physiological characteristics have promoted the study of poly-gallic acid (PGAL), a poly-oxidized form of gallic acid reported to be effective in in vitro models of inflammation." | 4.12 | Anti-inflammatory and Antioxidant Effect of Poly-gallic Acid (PGAL) in an In Vitro Model of Synovitis Induced by Monosodium Urate Crystals. ( Fernández-Torres, J; Gimeno, M; Luján-Juárez, IA; Martínez-Flores, K; Martínez-López, V; Montaño-Armendariz, N; Sánchez-Sánchez, R; Zamudio-Cuevas, Y, 2022) |
" Our aim was to study the protective effects of grape phenolic compounds epicatechin (EC), gallic acid (GA) and resveratrol (RSV) and grape-seed proanthocyanidin-rich extract (GSPE) on a cytokine-induced vascular endothelial inflammation model." | 3.96 | The effects of Vitis vinifera L. phenolic compounds on a blood-brain barrier culture model: Expression of leptin receptors and protection against cytokine-induced damage. ( Aragonès, G; Ardid-Ruiz, A; Barna, L; Bladé, C; Deli, MA; Harazin, A; Suárez, M; Walter, FR, 2020) |
"Leonurine hydrochloride (LH) has been reported to exhibit a number of biological properties such as suppression of inflammation." | 3.96 | Leonurine Hydrochloride Suppresses Inflammatory Responses and Ameliorates Cartilage Degradation in Osteoarthritis via NF-κB Signaling Pathway. ( Chen, C; Hu, N; Huang, W; Liang, X; Zhu, Z, 2020) |
"In this study, we investigated the effects of gallic acid (GA) in intracellular signaling within murine macrophages and its contribution to host immunity during Brucella infection." | 3.88 | Effects of gallic acid on signaling kinases in murine macrophages and immune modulation against Brucella abortus 544 infection in mice. ( Arayan, LT; Hop, HT; Kim, S; Lee, HJ; Min, W; Ngoc Huy, TX; Reyes, AWB; Vu, SH, 2018) |
"The present study was aimed to investigate the effect of diet derived AGEs (dAGEs) on the circulatory levels of pro-inflammatory cytokines, chemokines and to evaluate the protective efficacy of natural anti-oxidants curcumin (CU) and gallic acid (GA) respectively against the dAGEs-induced systemic inflammation in experimental Swiss albino mice." | 3.88 | Diet with high content of advanced glycation end products induces systemic inflammation and weight gain in experimental mice: Protective role of curcumin and gallic acid. ( Babu, AA; Chandrasekar, N; Dhanusu, S; Kalaiarasu, LP; Krishna, K; Manivasagam, S; Sowndhar Rajan, B; Vellaichamy, E, 2018) |
"In this study, we investigated the effect of 3,4,5-trihydroxy-N-(8-hydroxyquinolin-2-yl)benzamide) (SG-HQ2), a synthetic analogue of gallic acid (3,4,5-trihydroxybenzoic acid), on the mast cell-mediated allergic inflammation and the possible mechanism of action." | 3.81 | SG-HQ2 inhibits mast cell-mediated allergic inflammation through suppression of histamine release and pro-inflammatory cytokines. ( Je, IG; Kim, HH; Kim, SH; Kwon, TK; Park, PH; Seo, SY; Shin, TY, 2015) |
"Gallic acid (GA) and its derivatives are anti-inflammatory agents reported to have an effect on osteoarthritis (OA)." | 3.81 | A Novel Synthesized Sulfonamido-Based Gallate-JEZ-C as Potential Therapeutic Agents for Osteoarthritis. ( Lin, C; Lin, X; Liu, B; Lu, Z; Wei, S; Zhao, J; Zheng, L; Zou, Y, 2015) |
" The former 10 molecules with better mutual actions with sepsis targets were sequenced as tryptophane, danshensu, gallic acid, salvianolic acid D, protocatechuic acid, salvianolic acid A, danshensu C, vanillic acid, rosmarinic acid, phenylalanine." | 3.81 | [Potency Material Bases of Xuebijing Formula and Its Multi-target Effects on Sepsis]. ( Ma, ST; Xiong, YY; Yu, H; Zhang, XL, 2015) |
"11-O-galloylbergenin has demonstrated its significant potential to be further investigated for its discovery as a new lead compound for management of pain and inflammation." | 3.76 | Analgesic and anti-inflammatory activities of 11-O-galloylbergenin. ( Amin, H; Arfan, M; Khan, I; Khan, MA; Khan, N; Saeed, M, 2010) |
"Although multiple studies have revealed that gallic acid plays an important role in the inhibition of malignant transformation, cancer development, and inflammation, the molecular mechanism of gallic acid in inflammatory diseases is still unclear." | 3.75 | Gallic acid suppresses lipopolysaccharide-induced nuclear factor-kappaB signaling by preventing RelA acetylation in A549 lung cancer cells. ( Choi, KC; Jun, WJ; Jung, MG; Kim, MJ; Kwon, SH; Lee, J; Lee, JM; Lee, YH; Yoon, HG, 2009) |
" According to pharmacokinetic studies, the absorption and elimination of GA after oral administration are fast, while the structural optimization or dosage form adjustment of GA is beneficial to increase its bioavailability." | 2.72 | Gallic acid: Pharmacological activities and molecular mechanisms involved in inflammation-related diseases. ( Ai, X; Bai, J; Chen, X; Hou, Y; Meng, X; Tang, C; Wang, X; Zhang, Y, 2021) |
" The bioavailability of mango polyphenols, especially polymeric gallotannins, is largely dependent on the intestinal microbiota, where the generation of absorbable metabolites depends on microbial enzymes." | 2.72 | Mango ( ( Arbizu, S; Castellon-Chicas, MJ; Drury, NL; Kim, H; Mertens-Talcott, SU; Smith, S; Talcott, ST, 2021) |
"Inflammation is a complex mechanism with an objective to destroy and eliminate the invading microorganisms." | 1.72 | Octyl gallate decrease lymphocyte activation and regulates neutrophil extracellular traps release. ( de Oliveira, JR; Donadio, MVF; Haute, GV; Luft, C; Pedrazza, L, 2022) |
"Co-treatment with gallic acid preserved all these changes approximately to the normal levels." | 1.62 | Gallic acid suppresses inflammation and oxidative stress through modulating Nrf2-HO-1-NF-κB signaling pathways in elastase-induced emphysema in rats. ( Badavi, M; Dianat, M; Mard, SA; Radan, M; Sohrabi, F, 2021) |
"COPD is an inflammatory lung disease, which is often exacerbated with microbial infections resulting in worsening of respiratory symptoms." | 1.62 | Gallic acid ameliorates COPD-associated exacerbation in mice. ( Dharwal, V; Naura, AS; Puri, G; Singla, E, 2021) |
"Spontaneous preterm birth is the leading cause of neonatal mortality and morbidity globally." | 1.56 | Anti-inflammatory effects of gallic acid in human gestational tissues in vitro. ( Lai, A; Lappas, M; Nguyen-Ngo, C; Salomon, C; Willcox, JC, 2020) |
"Nonalcoholic fatty liver disease (NAFLD) is one of the most common causes of chronic liver disease, sometimes ranges from simple steatosis to nonalcoholic steatohepatitis (NASH)." | 1.56 | Gallic Acid Inhibits Lipid Accumulation via AMPK Pathway and Suppresses Apoptosis and Macrophage-Mediated Inflammation in Hepatocytes. ( Iida, K; Kishimoto, Y; Kondo, K; Mabashi-Asazuma, H; Sato, A; Tanaka, M, 2020) |
"Acute lung injury (ALI) is an inflammatory process, and has high incidence and mortality." | 1.56 | Anti-inflammatory effect of octyl gallate in alveolar macrophages cells and mice with acute lung injury. ( Antunes, GL; da Costa, MS; de Oliveira, JR; de Souza Basso, B; Donadio, MVF; Gracia-Sancho, J; Haute, GV; Kaiber, DB; Levorse, VGS; Luft, C; Silveira, JS, 2020) |
"Methyl gallate (MG) is a prevalent polyphenol in the plant kingdom, which may be related to the effects of several medicinal plants." | 1.56 | Methyl gallate attenuates inflammation induced by Toll-like receptor ligands by inhibiting MAPK and NF-Κb signaling pathways. ( Correa, LB; Cunha, TM; Henriques, MG; Manchope, MF; Rosas, EC; Seito, LN; Verri, WA, 2020) |
"Nano-gallic acid was prepared by double emulsions-solvent evaporation technique using Eudragit RS 100 polymer and polyvinyl alcohol as carrier." | 1.56 | Protective effect of gallic acid and gallic acid-loaded Eudragit-RS 100 nanoparticles on cisplatin-induced mitochondrial dysfunction and inflammation in rat kidney. ( Atefi Khah, M; Dehghani, MA; Khorsandi, L; Mahdavinia, M; Moghimipour, E; Shakiba Maram, N, 2020) |
"Neurodegenerative diseases comprise demyelination and synaptic loss." | 1.51 | Gallic and vanillic acid suppress inflammation and promote myelination in an in vitro mouse model of neurodegeneration. ( Jamali, KS; Kamal, A; Khan, F; Saify, ZS; Siddiqui, S, 2019) |
"However, the effects of GA on ulcerative colitis (UC) remain unknown." | 1.51 | Gallic acid improved inflammation via NF-κB pathway in TNBS-induced ulcerative colitis. ( Gu, P; Shen, H; Zhu, L, 2019) |
"Methyl gallate (MG) is a prevalent phenolic acid in the plant kingdom, and its presence in herbal medicines might be related to its remarkable biological effects, such as its antioxidant, antitumor, and antimicrobial activities." | 1.43 | Anti-inflammatory Effect of Methyl Gallate on Experimental Arthritis: Inhibition of Neutrophil Recruitment, Production of Inflammatory Mediators, and Activation of Macrophages. ( Candéa, AL; Correa, LB; Costa, TE; Henriques, MG; Pádua, TA; Rosas, EC; Seito, LN; Silva, MA, 2016) |
"Gallic acid is a polyhydroxy phenolic compound found in various natural products." | 1.42 | Gallic Acid Decreases Inflammatory Cytokine Secretion Through Histone Acetyltransferase/Histone Deacetylase Regulation in High Glucose-Induced Human Monocytes. ( Lee, SY; Lee, W; Son, YJ; Yun, JM, 2015) |
"Gallic acid (GA) has been demonstrated to possess multiple biological activities including anticancer function." | 1.37 | Gallic acid suppresses the migration and invasion of PC-3 human prostate cancer cells via inhibition of matrix metalloproteinase-2 and -9 signaling pathways. ( Chiang, JH; Chueh, FS; Chung, JG; Huang, AC; Lin, HY; Liu, KC; Lu, CC; Meng, M; Wu, PP; Yang, JS, 2011) |
"Gallic acid content was determined by HPLC." | 1.36 | Antiinflammatory and antioxidant activities of gum mastic. ( Ebrahimzadeh, MA; Eslami, Sh; Hafezi, S; Mahmoudi, M; Nabavi, SF; Nabavi, SM, 2010) |
"Pre-treatment with gallic acid significantly rendered K562 cells more susceptible to NK cell-mediated necrosis, while pre-treatment with rutin significantly rendered K562 cells more susceptible to apoptosis." | 1.33 | Effect of phenols on natural killer (NK) cell-mediated death in the K562 human leukemic cell line. ( Andrikopoulos, NK; Dedoussis, GV; Kaliora, AC, 2005) |
Timeframe | Studies, this research(%) | All Research% |
---|---|---|
pre-1990 | 2 (2.82) | 18.7374 |
1990's | 1 (1.41) | 18.2507 |
2000's | 3 (4.23) | 29.6817 |
2010's | 31 (43.66) | 24.3611 |
2020's | 34 (47.89) | 2.80 |
Authors | Studies |
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Abusharkh, HA | 1 |
Reynolds, OM | 1 |
Mendenhall, J | 1 |
Gozen, BA | 1 |
Tingstad, E | 1 |
Idone, V | 1 |
Abu-Lail, NI | 1 |
Van Wie, BJ | 1 |
Haute, GV | 2 |
Luft, C | 2 |
Pedrazza, L | 1 |
Donadio, MVF | 2 |
de Oliveira, JR | 2 |
Xu, Y | 1 |
Tang, G | 1 |
Zhang, C | 1 |
Wang, N | 1 |
Feng, Y | 1 |
Essa, BM | 1 |
Selim, AA | 1 |
El-Kawy, OA | 1 |
Abdelaziz, G | 1 |
Zamudio-Cuevas, Y | 1 |
Martínez-López, V | 2 |
Luján-Juárez, IA | 1 |
Montaño-Armendariz, N | 1 |
Martínez-Flores, K | 1 |
Fernández-Torres, J | 1 |
Gimeno, M | 2 |
Sánchez-Sánchez, R | 2 |
Silva, RLDS | 1 |
Lins, TLBG | 1 |
Monte, APOD | 1 |
de Andrade, KO | 1 |
de Sousa Barberino, R | 1 |
da Silva, GAL | 1 |
Campinho, DDSP | 1 |
Junior, RCP | 1 |
Matos, MHT | 1 |
Anish, RJ | 1 |
Mohanan, B | 1 |
Aswathy, TR | 1 |
Nair, A | 1 |
Radhakrishnan, KV | 1 |
Rauf, AA | 1 |
Saif-Elnasr, M | 1 |
El-Ghlban, S | 1 |
Bayomi, AI | 1 |
El-Sayyad, GS | 1 |
Maghraby, MS | 1 |
Rodwattanagul, S | 1 |
Nimlamool, W | 1 |
Okonogi, S | 1 |
Ortega-Sánchez, C | 1 |
Pérez-Díaz, MA | 1 |
Zacaula-Juárez, N | 1 |
González-Torres, M | 1 |
Leyva-Gómez, G | 1 |
Hernandez-Valdepeña, MA | 1 |
Mohamed, EK | 1 |
Hafez, DM | 1 |
Ardid-Ruiz, A | 1 |
Harazin, A | 1 |
Barna, L | 1 |
Walter, FR | 1 |
Bladé, C | 1 |
Suárez, M | 1 |
Deli, MA | 1 |
Aragonès, G | 1 |
Chen, C | 1 |
Zhu, Z | 1 |
Hu, N | 1 |
Liang, X | 1 |
Huang, W | 1 |
Liu, YL | 1 |
Hsu, CC | 1 |
Huang, HJ | 1 |
Chang, CJ | 1 |
Sun, SH | 1 |
Lin, AM | 1 |
Tanaka, M | 2 |
Sugama, A | 1 |
Sumi, K | 1 |
Shimizu, K | 1 |
Kishimoto, Y | 2 |
Kondo, K | 2 |
Iida, K | 2 |
Shree, A | 1 |
Islam, J | 1 |
Vafa, A | 1 |
Mohammad Afzal, S | 1 |
Sultana, S | 1 |
Antunes, GL | 1 |
Silveira, JS | 1 |
de Souza Basso, B | 1 |
da Costa, MS | 1 |
Levorse, VGS | 1 |
Kaiber, DB | 1 |
Gracia-Sancho, J | 1 |
Kim, MJ | 3 |
Je, IG | 3 |
Song, J | 1 |
Fei, X | 2 |
Lee, S | 2 |
Yang, H | 1 |
Kang, W | 1 |
Jang, YH | 1 |
Seo, SY | 3 |
Kim, SH | 5 |
Ning, K | 1 |
Wang, MJ | 1 |
Lin, G | 1 |
Zhang, YL | 1 |
Li, MY | 1 |
Yang, BF | 1 |
Chen, Y | 1 |
Huang, Y | 1 |
Li, ZM | 1 |
Huang, YJ | 1 |
Zhu, L | 2 |
Liang, K | 1 |
Yu, B | 1 |
Zhu, YZ | 2 |
Zhu, YC | 1 |
Owumi, SE | 2 |
Nwozo, SO | 1 |
Effiong, ME | 1 |
Najophe, ES | 1 |
Sato, A | 1 |
Mabashi-Asazuma, H | 1 |
Adedara, IA | 1 |
Akomolafe, AP | 1 |
Farombi, EO | 1 |
Oyelere, AK | 1 |
Nguyen-Ngo, C | 1 |
Salomon, C | 1 |
Lai, A | 1 |
Willcox, JC | 1 |
Lappas, M | 1 |
Dehghani, MA | 1 |
Shakiba Maram, N | 1 |
Moghimipour, E | 1 |
Khorsandi, L | 1 |
Atefi Khah, M | 1 |
Mahdavinia, M | 1 |
Diaz, A | 1 |
Muñoz-Arenas, G | 1 |
Caporal-Hernandez, K | 1 |
Vázquez-Roque, R | 1 |
Lopez-Lopez, G | 1 |
Kozina, A | 1 |
Espinosa, B | 1 |
Flores, G | 1 |
Treviño, S | 1 |
Guevara, J | 1 |
Singla, E | 1 |
Puri, G | 1 |
Dharwal, V | 1 |
Naura, AS | 1 |
Correa, LB | 2 |
Seito, LN | 2 |
Manchope, MF | 1 |
Verri, WA | 1 |
Cunha, TM | 1 |
Henriques, MG | 2 |
Rosas, EC | 2 |
Luzardo-Ocampo, I | 1 |
Loarca-Piña, G | 1 |
Gonzalez de Mejia, E | 1 |
Bai, J | 1 |
Zhang, Y | 3 |
Tang, C | 1 |
Hou, Y | 1 |
Ai, X | 1 |
Chen, X | 1 |
Wang, X | 1 |
Meng, X | 1 |
Rahimifard, M | 1 |
Baeeri, M | 1 |
Bahadar, H | 1 |
Moini-Nodeh, S | 1 |
Khalid, M | 1 |
Haghi-Aminjan, H | 1 |
Mohammadian, H | 1 |
Abdollahi, M | 1 |
Liu, W | 1 |
Liu, J | 1 |
Xing, S | 1 |
Pan, X | 1 |
Wei, S | 2 |
Zhou, M | 1 |
Li, Z | 1 |
Wang, L | 1 |
Bielicki, JK | 1 |
Baharmi, S | 1 |
Kalantari, H | 1 |
Kalantar, M | 1 |
Goudarzi, M | 1 |
Mansouri, E | 1 |
Kalantar, H | 1 |
Kim, H | 1 |
Castellon-Chicas, MJ | 1 |
Arbizu, S | 1 |
Talcott, ST | 1 |
Drury, NL | 1 |
Smith, S | 1 |
Mertens-Talcott, SU | 1 |
Sohrabi, F | 1 |
Dianat, M | 1 |
Badavi, M | 1 |
Radan, M | 1 |
Mard, SA | 1 |
Shin, TY | 3 |
Sowndhar Rajan, B | 1 |
Manivasagam, S | 1 |
Dhanusu, S | 1 |
Chandrasekar, N | 1 |
Krishna, K | 1 |
Kalaiarasu, LP | 1 |
Babu, AA | 1 |
Vellaichamy, E | 1 |
Reyes, AWB | 1 |
Arayan, LT | 1 |
Hop, HT | 1 |
Ngoc Huy, TX | 1 |
Vu, SH | 1 |
Min, W | 1 |
Lee, HJ | 2 |
Kim, S | 1 |
Liu, Y | 2 |
Duan, C | 1 |
Chen, H | 1 |
Wang, C | 1 |
Liu, X | 1 |
Qiu, M | 1 |
Tang, H | 1 |
Zhang, F | 1 |
Zhou, X | 1 |
Yang, J | 1 |
Cheng, Y | 1 |
Li, X | 1 |
Tse, HF | 1 |
Rong, J | 1 |
Yang, L | 2 |
Liu, G | 2 |
Zhu, X | 2 |
Luo, Y | 2 |
Shang, Y | 2 |
Gu, XL | 2 |
Gu, P | 1 |
Shen, H | 1 |
Jin, M | 1 |
Li, Q | 1 |
Gu, Y | 1 |
Wan, B | 1 |
Huang, J | 1 |
Xu, X | 1 |
Huang, R | 1 |
Siddiqui, S | 1 |
Kamal, A | 1 |
Khan, F | 1 |
Jamali, KS | 1 |
Saify, ZS | 1 |
Dludla, PV | 1 |
Nkambule, BB | 1 |
Jack, B | 1 |
Mkandla, Z | 1 |
Mutize, T | 1 |
Silvestri, S | 1 |
Orlando, P | 1 |
Tiano, L | 1 |
Louw, J | 1 |
Mazibuko-Mbeje, SE | 1 |
Lian, K | 1 |
Qiao, Y | 1 |
Zhang, B | 1 |
Zhang, SD | 1 |
Wang, P | 1 |
Zhang, J | 1 |
Wang, W | 1 |
Yao, LP | 1 |
Gu, CB | 1 |
Efferth, T | 1 |
Fu, YJ | 1 |
Fan, Y | 1 |
Piao, CH | 1 |
Hyeon, E | 1 |
Jung, SY | 1 |
Eom, JE | 1 |
Shin, HS | 1 |
Song, CH | 1 |
Chai, OH | 1 |
Kim, HH | 2 |
Park, SB | 1 |
Kwon, TK | 2 |
Park, PH | 2 |
Lee, SH | 1 |
Lee, JW | 1 |
Bae, CJ | 1 |
Choi, YJ | 1 |
Kim, SI | 1 |
Kwon, YS | 1 |
Kim, SS | 1 |
Chun, W | 1 |
Leow, SS | 1 |
Sekaran, SD | 1 |
Sundram, K | 1 |
Tan, Y | 1 |
Sambanthamurthi, R | 1 |
Yang, HL | 2 |
Huang, PJ | 1 |
Liu, YR | 1 |
Kumar, KJ | 2 |
Hsu, LS | 1 |
Lu, TL | 1 |
Chia, YC | 1 |
Takajo, T | 1 |
Kazunori, A | 1 |
Hseu, YC | 2 |
Lee, W | 1 |
Lee, SY | 1 |
Son, YJ | 1 |
Yun, JM | 1 |
Lu, Z | 1 |
Zou, Y | 1 |
Lin, X | 1 |
Lin, C | 1 |
Liu, B | 1 |
Zheng, L | 1 |
Zhao, J | 1 |
Jhang, JJ | 1 |
Lu, CC | 2 |
Ho, CY | 1 |
Cheng, YT | 1 |
Yen, GC | 1 |
Ahn, CB | 1 |
Jung, WK | 1 |
Park, SJ | 1 |
Kim, YT | 1 |
Kim, WS | 1 |
Je, JY | 1 |
Ma, ST | 1 |
Yu, H | 1 |
Zhang, XL | 1 |
Xiong, YY | 1 |
Pádua, TA | 1 |
Costa, TE | 1 |
Silva, MA | 1 |
Candéa, AL | 1 |
Choi, KC | 1 |
Lee, YH | 2 |
Jung, MG | 1 |
Kwon, SH | 1 |
Jun, WJ | 2 |
Lee, J | 2 |
Lee, JM | 1 |
Yoon, HG | 2 |
Arfan, M | 1 |
Amin, H | 1 |
Khan, N | 1 |
Khan, I | 1 |
Saeed, M | 1 |
Khan, MA | 1 |
Mahmoudi, M | 1 |
Ebrahimzadeh, MA | 1 |
Nabavi, SF | 1 |
Hafezi, S | 1 |
Nabavi, SM | 1 |
Eslami, Sh | 1 |
Liu, KC | 1 |
Huang, AC | 1 |
Wu, PP | 1 |
Lin, HY | 1 |
Chueh, FS | 1 |
Yang, JS | 1 |
Chiang, JH | 1 |
Meng, M | 1 |
Chung, JG | 1 |
Seong, AR | 1 |
Yoo, JY | 1 |
Jin, CH | 1 |
Kim, YJ | 1 |
Tramontina, VA | 1 |
Papalexiou, V | 1 |
Luczsyzyn, SM | 1 |
De Lima, AA | 1 |
do Prado, AM | 1 |
Liu, XH | 1 |
Pan, LL | 1 |
Yang, HB | 1 |
Gong, QH | 1 |
Hsiang, CY | 1 |
Chang, YC | 1 |
Ho, TY | 1 |
Dedoussis, GV | 1 |
Kaliora, AC | 1 |
Andrikopoulos, NK | 1 |
Huang, MT | 1 |
Ramji, D | 1 |
Lo, CY | 1 |
Ghai, G | 1 |
Dushenkov, S | 1 |
Ho, CT | 1 |
Srivastava, R | 1 |
Srimal, RC | 1 |
Northover, AM | 1 |
Zhang, JJ | 1 |
Liu, CM | 1 |
Chen, WW | 1 |
Trial | Phase | Enrollment | Study Type | Start Date | Status | ||
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Effect of Spirulina Platensis Supplementation and Calorie Restriction on Anthropometric, Body Composition, Lipid Profiles, Insulin Resistance, Stress Oxidative Biomarkers In Obese Men: A Randomized Controlled Trial Protocol Study[NCT06076161] | 32 participants (Actual) | Interventional | 2023-10-17 | Active, not recruiting | |||
[information is prepared from clinicaltrials.gov, extracted Sep-2024] |
4 reviews available for gallic acid and Innate Inflammatory Response
Article | Year |
---|---|
Gallic Acid and Diabetes Mellitus: Its Association with Oxidative Stress.
Topics: Antioxidants; Diabetes Mellitus, Type 2; Gallic Acid; Humans; Hyperglycemia; Hypoglycemic Agents; In | 2021 |
Gallic acid: Pharmacological activities and molecular mechanisms involved in inflammation-related diseases.
Topics: Animals; Anti-Inflammatory Agents; Gallic Acid; Humans; Inflammation; Inflammation Mediators; Signal | 2021 |
Mango (
Topics: Animals; Anti-Inflammatory Agents; Dietary Fiber; Gallic Acid; Gastrointestinal Microbiome; Humans; | 2021 |
Inflammation and Oxidative Stress in an Obese State and the Protective Effects of Gallic Acid.
Topics: Adipokines; Adipose Tissue; Animals; Cytokines; Diet; Fruit; Gallic Acid; Humans; Inflammation; Insu | 2018 |
67 other studies available for gallic acid and Innate Inflammatory Response
Article | Year |
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Combining stretching and gallic acid to decrease inflammation indices and promote extracellular matrix production in osteoarthritic human articular chondrocytes.
Topics: Cartilage, Articular; Cells, Cultured; Chondrocytes; Collagen Type I, alpha 1 Chain; Collagen Type I | 2021 |
Octyl gallate decrease lymphocyte activation and regulates neutrophil extracellular traps release.
Topics: Animals; Apoptosis; Extracellular Traps; Gallic Acid; Healthy Volunteers; Humans; Inflammation; Leuk | 2022 |
Preparation and preliminary evaluation study of [
Topics: Animals; Gallic Acid; Gold; Inflammation; Iodine Radioisotopes; Metal Nanoparticles; Mice; Tissue Di | 2022 |
Anti-inflammatory and Antioxidant Effect of Poly-gallic Acid (PGAL) in an In Vitro Model of Synovitis Induced by Monosodium Urate Crystals.
Topics: Anti-Inflammatory Agents; Antioxidants; Gallic Acid; Gout; Humans; Inflammation; Polyglutamic Acid; | 2022 |
Protective effect of gallic acid on doxorubicin-induced ovarian toxicity in mouse.
Topics: Animals; Apoptosis; Caspase 3; Doxorubicin; Female; Gallic Acid; Inflammation; Mice; Ovarian Follicl | 2023 |
An integrated approach to the structural characterization, long-term toxicological and anti-inflammatory evaluation of Pterospermum rubiginosum bark extract.
Topics: Animals; Anti-Inflammatory Agents; Gallic Acid; Inflammation; Inflammation Mediators; Lipopolysaccha | 2023 |
Gallic acid and/or cerium oxide nanoparticles synthesized by gamma-irradiation protect cisplatin-induced nephrotoxicity via modulating oxidative stress, inflammation and apoptosis.
Topics: Animals; Antineoplastic Agents; Apoptosis; Cisplatin; Gallic Acid; Inflammation; Kidney; Male; Nanop | 2023 |
Antioxidant, antiglycation, and anti-inflammatory activities of Caesalpinia mimosoides.
Topics: Anti-Inflammatory Agents; Antioxidants; Caesalpinia; Gallic Acid; Humans; Inflammation; Phenols; Pla | 2023 |
Inhibition of proliferation, migration, and adhesion of skin fibroblasts by enzymatic poly(gallic acid) grafted with L-Arginine, migration, and adhesion of skin fibroblasts by enzymatic poly(gallic acid) grafted with L-Arginine.
Topics: Antioxidants; Arginine; Cell Proliferation; Dermatitis, Atopic; Fibroblasts; Gallic Acid; Gentian Vi | 2023 |
Gallic acid and metformin co-administration reduce oxidative stress, apoptosis and inflammation via Fas/caspase-3 and NF-κB signaling pathways in thioacetamide-induced acute hepatic encephalopathy in rats.
Topics: Animals; Apoptosis; Caspase 3; Gallic Acid; Hepatic Encephalopathy; Inflammation; Metformin; NF-kapp | 2023 |
The effects of Vitis vinifera L. phenolic compounds on a blood-brain barrier culture model: Expression of leptin receptors and protection against cytokine-induced damage.
Topics: Animals; Animals, Newborn; Astrocytes; Blood-Brain Barrier; Catechin; Cells, Cultured; Cytokines; Dr | 2020 |
Leonurine Hydrochloride Suppresses Inflammatory Responses and Ameliorates Cartilage Degradation in Osteoarthritis via NF-κB Signaling Pathway.
Topics: ADAMTS5 Protein; Animals; Anterior Cruciate Ligament; Anti-Inflammatory Agents; Cartilage Diseases; | 2020 |
Gallic Acid Attenuated LPS-Induced Neuroinflammation: Protein Aggregation and Necroptosis.
Topics: Animals; Anti-Inflammatory Agents; Cytokines; Gallic Acid; Inflammation; Lipid Peroxidation; Lipopol | 2020 |
Gallic acid regulates adipocyte hypertrophy and suppresses inflammatory gene expression induced by the paracrine interaction between adipocytes and macrophages in vitro and in vivo.
Topics: Adipocytes; Animals; Disease Models, Animal; Gallic Acid; Gene Expression; Hypertrophy; Inflammation | 2020 |
Gallic acid prevents 1, 2-Dimethylhydrazine induced colon inflammation, toxicity, mucin depletion, and goblet cell disintegration.
Topics: 1,2-Dimethylhydrazine; Animals; Anti-Inflammatory Agents; Antioxidants; Apoptosis; Cell Proliferatio | 2020 |
Anti-inflammatory effect of octyl gallate in alveolar macrophages cells and mice with acute lung injury.
Topics: Acute Lung Injury; Animals; Disease Models, Animal; Gallic Acid; Humans; Inflammation; Lung; Lung In | 2020 |
SG-SP1 Suppresses Mast Cell-Mediated Allergic Inflammation via Inhibition of FcεRI Signaling.
Topics: Anaphylaxis; Animals; Anti-Inflammatory Agents; Calcium; Calcium Signaling; Cell Degranulation; Cell | 2020 |
eNOS-Nitric Oxide System Contributes to a Novel Antiatherogenic Effect of Leonurine via Inflammation Inhibition and Plaque Stabilization.
Topics: Animals; Atherosclerosis; Cell Line; Gallic Acid; Human Umbilical Vein Endothelial Cells; Humans; In | 2020 |
Gallic acid and omega-3 fatty acids decrease inflammatory and oxidative stress in manganese-treated rats.
Topics: Animals; Chemical and Drug Induced Liver Injury; Fatty Acids, Omega-3; Gallic Acid; Inflammation; Ki | 2020 |
Gallic Acid Inhibits Lipid Accumulation via AMPK Pathway and Suppresses Apoptosis and Macrophage-Mediated Inflammation in Hepatocytes.
Topics: AMP-Activated Protein Kinases; Animals; Apoptosis; Caspase 3; Caspase 7; Gallic Acid; Gene Expressio | 2020 |
Gallic acid enhances reproductive function by modulating oxido-inflammatory and apoptosis mediators in rats exposed to aflatoxin-B1.
Topics: Aflatoxin B1; Animals; Antioxidants; Apoptosis; Apoptosis Regulatory Proteins; Biomarkers; Epididymi | 2020 |
Anti-inflammatory effects of gallic acid in human gestational tissues in vitro.
Topics: Anti-Inflammatory Agents; Extraembryonic Membranes; Female; Gallic Acid; Gestational Age; Humans; In | 2020 |
Protective effect of gallic acid and gallic acid-loaded Eudragit-RS 100 nanoparticles on cisplatin-induced mitochondrial dysfunction and inflammation in rat kidney.
Topics: Acrylic Resins; Administration, Oral; Animals; Cisplatin; Dose-Response Relationship, Drug; Gallic A | 2020 |
Gallic acid improves recognition memory and decreases oxidative-inflammatory damage in the rat hippocampus with metabolic syndrome.
Topics: Animals; Blood Glucose; Catalase; Dendrites; Gallic Acid; Hippocampus; Inflammation; Insulin; Interl | 2020 |
Gallic acid ameliorates COPD-associated exacerbation in mice.
Topics: Animals; Anti-Inflammatory Agents; Antioxidants; Cytokines; Enzyme-Linked Immunosorbent Assay; Galli | 2021 |
Methyl gallate attenuates inflammation induced by Toll-like receptor ligands by inhibiting MAPK and NF-Κb signaling pathways.
Topics: Animals; Anti-Inflammatory Agents, Non-Steroidal; Cytokines; Edema; Gallic Acid; Hyperalgesia; Infla | 2020 |
Gallic and butyric acids modulated NLRP3 inflammasome markers in a co-culture model of intestinal inflammation.
Topics: Biomarkers; Butyric Acid; Caco-2 Cells; Cell Differentiation; Cell Survival; Coculture Techniques; C | 2020 |
Therapeutic Effects of Gallic Acid in Regulating Senescence and Diabetes; an In Vitro Study.
Topics: Animals; Antioxidants; Apoptosis; beta-Galactosidase; Caspase 9; Cell Cycle; Cellular Senescence; Di | 2020 |
The benzoate plant metabolite ethyl gallate prevents cellular- and vascular-lipid accumulation in experimental models of atherosclerosis.
Topics: Animals; Apolipoproteins E; Atherosclerosis; ATP-Binding Cassette Transporters; Benzoates; Cholester | 2021 |
Pretreatment with Gallic Acid Mitigates Cyclophosphamide Induced Inflammation and Oxidative Stress in Mice.
Topics: Animals; Antioxidants; Cyclophosphamide; Gallic Acid; Inflammation; Kidney; Male; Mice; Oxidative St | 2022 |
Gallic acid suppresses inflammation and oxidative stress through modulating Nrf2-HO-1-NF-κB signaling pathways in elastase-induced emphysema in rats.
Topics: Animals; Emphysema; Gallic Acid; Heme Oxygenase-1; Inflammation; NF-E2-Related Factor 2; NF-kappa B; | 2021 |
Synthesis of Gallic Acid Analogs as Histamine and Pro-Inflammatory Cytokine Inhibitors for Treatment of Mast Cell-Mediated Allergic Inflammation.
Topics: Animals; Gallic Acid; Histamine Antagonists; Humans; Hypersensitivity; Inflammation; Mast Cells | 2017 |
Diet with high content of advanced glycation end products induces systemic inflammation and weight gain in experimental mice: Protective role of curcumin and gallic acid.
Topics: Animals; Anti-Inflammatory Agents; Chemokines; Curcumin; Cytokines; Diet; Gallic Acid; Glycation End | 2018 |
Effects of gallic acid on signaling kinases in murine macrophages and immune modulation against Brucella abortus 544 infection in mice.
Topics: Actins; Animals; Brucella abortus; Brucellosis; Cell Proliferation; Cell Survival; Chemokine CCL2; C | 2018 |
Inhibition of COX-2/mPGES-1 and 5-LOX in macrophages by leonurine ameliorates monosodium urate crystal-induced inflammation.
Topics: Animals; Arachidonate 5-Lipoxygenase; Arthritis, Gouty; Cyclooxygenase 2; Cyclooxygenase 2 Inhibitor | 2018 |
Gallic Acid-L-Leucine Conjugate Protects Mice against LPS-Induced Inflammation and Sepsis via Correcting Proinflammatory Lipid Mediator Profiles and Oxidative Stress.
Topics: Animals; Anti-Inflammatory Agents; Gallic Acid; Inflammation; Leucine; Lipopolysaccharides; Male; Mi | 2018 |
The anti-inflammatory and antioxidant effects of leonurine hydrochloride after lipopolysaccharide challenge in broiler chicks.
Topics: Animal Feed; Animals; Chickens; Diet; Dietary Supplements; Gallic Acid; Inflammation; Lipopolysaccha | 2019 |
Gallic acid improved inflammation via NF-κB pathway in TNBS-induced ulcerative colitis.
Topics: Animals; Anti-Inflammatory Agents; Apoptosis; Cell Line; Cell Proliferation; Colitis, Ulcerative; Cy | 2019 |
Leonurine suppresses neuroinflammation through promoting oligodendrocyte maturation.
Topics: Animals; Cell Differentiation; Central Nervous System; Cuprizone; Disease Models, Animal; Encephalom | 2019 |
Gallic and vanillic acid suppress inflammation and promote myelination in an in vitro mouse model of neurodegeneration.
Topics: Action Potentials; Animals; Demyelinating Diseases; Disease Models, Animal; Extracellular Matrix Pro | 2019 |
Dietary leonurine hydrochloride supplementation attenuates lipopolysaccharide challenge-induced intestinal inflammation and barrier dysfunction by inhibiting the NF-κB/MAPK signaling pathway in broilers.
Topics: Animals; Antioxidants; Chickens; Cytokines; Dietary Supplements; Gallic Acid; Inflammation; Intestin | 2019 |
2'O-galloylhyperin attenuates LPS-induced acute lung injury via up-regulation antioxidation and inhibition of inflammatory responses in vivo.
Topics: Acute Lung Injury; Animals; Anti-Inflammatory Agents, Non-Steroidal; Antioxidants; Dose-Response Rel | 2019 |
Gallic acid alleviates nasal inflammation via activation of Th1 and inhibition of Th2 and Th17 in a mouse model of allergic rhinitis.
Topics: Allergens; Animals; Anti-Inflammatory Agents; Cytokines; Disease Models, Animal; Eosinophils; Gallic | 2019 |
Inhibitory effect of putranjivain A on allergic inflammation through suppression of mast cell activation.
Topics: Administration, Oral; Animals; Anti-Asthmatic Agents; Cells, Cultured; Cromolyn Sodium; Cytokines; G | 2014 |
3,4,5-trihydroxycinnamic acid inhibits lipopolysaccharide (LPS)-induced inflammation by Nrf2 activation in vitro and improves survival of mice in LPS-induced endotoxemia model in vivo.
Topics: Animals; Cell Line; Disease Models, Animal; Endotoxemia; Gallic Acid; Gene Expression Regulation; Hu | 2014 |
Gene expression changes in spleens and livers of tumour-bearing mice suggest delayed inflammation and attenuated cachexia in response to oil palm phenolics.
Topics: Animals; Cachexia; Dietary Supplements; Gallic Acid; Gene Expression Profiling; Gene Expression Regu | 2013 |
Toona sinensis inhibits LPS-induced inflammation and migration in vascular smooth muscle cells via suppression of reactive oxygen species and NF-κB signaling pathway.
Topics: Animals; Cell Line; Cell Movement; Cell Survival; Cyclooxygenase 2; Dinoprostone; Down-Regulation; E | 2014 |
SG-HQ2 inhibits mast cell-mediated allergic inflammation through suppression of histamine release and pro-inflammatory cytokines.
Topics: Animals; Calcium; Cytokines; Gallic Acid; Histamine Release; Hydroxyquinolines; Hypersensitivity; Im | 2015 |
Gallic Acid Decreases Inflammatory Cytokine Secretion Through Histone Acetyltransferase/Histone Deacetylase Regulation in High Glucose-Induced Human Monocytes.
Topics: Acetylation; Cell Line; CREB-Binding Protein; Cytokines; Epigenesis, Genetic; Gallic Acid; Gene Expr | 2015 |
A Novel Synthesized Sulfonamido-Based Gallate-JEZ-C as Potential Therapeutic Agents for Osteoarthritis.
Topics: Antioxidants; Cartilage, Articular; Cell Line; Chondrocytes; Gallic Acid; Humans; Inflammation; Oste | 2015 |
Protective Effects of Catechin against Monosodium Urate-Induced Inflammation through the Modulation of NLRP3 Inflammasome Activation.
Topics: Animals; Calcium; Carrier Proteins; Catechin; Disease Models, Animal; Free Radical Scavengers; Galli | 2015 |
Gallic Acid-g-Chitosan Modulates Inflammatory Responses in LPS-Stimulated RAW264.7 Cells Via NF-κB, AP-1, and MAPK Pathways.
Topics: Animals; Anti-Inflammatory Agents; Cell Line; Chitosan; Cyclooxygenase 2; Dinoprostone; Enzyme Activ | 2016 |
[Potency Material Bases of Xuebijing Formula and Its Multi-target Effects on Sepsis].
Topics: Caffeic Acids; Drugs, Chinese Herbal; Gallic Acid; Hydroxybenzoates; Inflammation; Lactates; Sepsis | 2015 |
Anti-inflammatory Effect of Methyl Gallate on Experimental Arthritis: Inhibition of Neutrophil Recruitment, Production of Inflammatory Mediators, and Activation of Macrophages.
Topics: Administration, Oral; Animals; Arthritis, Experimental; Brazil; Cyclooxygenase 2; Cytokines; Dose-Re | 2016 |
Gallic acid suppresses lipopolysaccharide-induced nuclear factor-kappaB signaling by preventing RelA acetylation in A549 lung cancer cells.
Topics: Acetylation; Animals; Apoptosis; Cell Line, Tumor; Cell Survival; E1A-Associated p300 Protein; Enzym | 2009 |
Analgesic and anti-inflammatory activities of 11-O-galloylbergenin.
Topics: Analgesics; Animals; Anti-Inflammatory Agents; Benzopyrans; Carrageenan; Edema; Euphorbiaceae; Femal | 2010 |
Antiinflammatory and antioxidant activities of gum mastic.
Topics: Animals; Anti-Inflammatory Agents; Antioxidants; Biphenyl Compounds; Carrageenan; Chromatography, Hi | 2010 |
Gallic acid suppresses the migration and invasion of PC-3 human prostate cancer cells via inhibition of matrix metalloproteinase-2 and -9 signaling pathways.
Topics: Cell Adhesion; Cell Line, Tumor; Cell Movement; Dose-Response Relationship, Drug; Gallic Acid; Gene | 2011 |
Gallic acid, a histone acetyltransferase inhibitor, suppresses β-amyloid neurotoxicity by inhibiting microglial-mediated neuroinflammation.
Topics: Amyloid beta-Peptides; Animals; Blotting, Western; Cell Survival; Coculture Techniques; Cytokines; D | 2011 |
Bismuth subgallate as a topical haemostatic agent at the palatal wounds: a histologic study in dogs.
Topics: Animals; Biopsy, Needle; Bismuth; Blood Coagulation; Cell Movement; Collagen; Connective Tissue; Dog | 2012 |
Leonurine attenuates lipopolysaccharide-induced inflammatory responses in human endothelial cells: involvement of reactive oxygen species and NF-κB pathways.
Topics: Anti-Inflammatory Agents; Cells, Cultured; Chemokine CCL2; Cyclooxygenase 2; E-Selectin; Endothelium | 2012 |
Toona sinensis and its major bioactive compound gallic acid inhibit LPS-induced inflammation in nuclear factor-κB transgenic mice as evaluated by in vivo bioluminescence imaging.
Topics: Animals; Anti-Inflammatory Agents; Down-Regulation; Female; Gallic Acid; Humans; Inflammation; Lipop | 2013 |
Effect of phenols on natural killer (NK) cell-mediated death in the K562 human leukemic cell line.
Topics: Annexin A5; Annexins; Apoptosis; Cell Death; Cell Line, Tumor; Cell Separation; Coculture Techniques | 2005 |
Inhibitory effects of black tea theaflavin derivatives on 12-O-tetradecanoylphorbol-13-acetate-induced inflammation and arachidonic acid metabolism in mouse ears.
Topics: Animals; Anti-Inflammatory Agents, Non-Steroidal; Arachidonic Acid; Biflavonoids; Catechin; Dinopros | 2006 |
Amplification of platelet response during acute inflammation in rats.
Topics: Acute Disease; Animals; Egtazic Acid; Gallic Acid; Heparin; Inflammation; Male; Phospholipases A; Ph | 1990 |
The effects of TMB-8 on the shape changes of vascular endothelial cells resulting from exposure to various inflammatory agents.
Topics: Animals; Bradykinin; Calcimycin; Calcium Channel Blockers; Dinoprostone; Endothelium, Vascular; Gall | 1989 |
[Observation on the anti-inflammatory action of propyl gallate].
Topics: Animals; Anti-Inflammatory Agents; Free Radicals; Gallic Acid; Inflammation; Male; Mice; Oxygen; Pro | 1986 |