Evaluación de los efectos de la toxicidad por sobredosis de paracetamol en ratas: el ozono, que puede preferirse como terapia complementaria
Resumen
Este estudio tiene como objetivo investigar los efectos de la ozonoterapia utilizada en la medicina tradicional y complementaria sobre la posible toxicidad provocada por acetaminofen (APAP). No hubo intervención en el primer grupo (control). El segundo grupo recibió 150 µg·kg-1 día, i.p. durante tres semanas de ozono, 2 g·kg-1 de APAP en dosis única por vía oral al tercer grupo y APAP + Ozono al cuarto grupo. APAP se administró el día 21 de la aplicación de ozono. Se midieron los niveles de malondialdehído (MDA), los niveles de glutatión reducido (GSH) y las actividades de las enzimas antioxidantes para evaluar su contribución a la patogénesis de la toxicidad en los tejidos sanguíneos. En comparación con el grupo control, el grupo que recibió APAP mostró niveles elevados de MDA (P=0,009) y niveles disminuidos de GSH (P<0,001), así como reducción de CAT (P<0,001), GSH–Px (P<0,001) y SOD. (P<0,001) actividades enzimáticas. Sin embargo, en el grupo tratado con ozono y APAP, los niveles de MDA y GSH, así como las actividades de las enzimas antioxidantes, fueron similares a los del grupo de control, lo que indica un efecto protector del ozono contra el estrés oxidativo inducido por APAP. En conclusión, los resultados del estudio mostraron que APAP causaba estrés oxidativo en el tejido sanguíneo. El presente estudio demostró que el ozono tenía potenciales efectos protectores contra la toxicidad inducida con APAP a través de varios mecanismos en diferentes procesos celulares. Esto puede estar relacionado con las propiedades citoprotectoras y antioxidantes del ozono. El ozono puede proporcionar una base química para algunos beneficios para la salud contra las toxicidades. El ozono puede proteger contra el daño oxidativo inducido por APAP. Como resultado, se concluyó que el ozono puede ser un antioxidante natural y eficaz que puede utilizarse para reducir la toxicidad causada por APAP.
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Lee WM. Acetaminophen toxicity: A history of serendipity and unintended consequences. Clin. Liver Dis. [Internet]. 2020; 16(1):34. doi: https://doi.org/mpnw
Xiao Q, Zhao Y, Ma L, Piao R. Orientin reverses acetaminophen–induced acute liver failure by inhibiting oxidative stress and mitochondrial dysfunction. J. Pharmacol. Sci. [Internet]. 2022; 149(1):11–19. doi: https://doi.org/mpnx
Ghanem CI, Pérez MJ, Manautou JE, Mottino AD. Acetaminophen from liver to brain: New insights into drug pharmacological action and toxicity. Pharm. Res. [Internet]. 2016; 109:119–131. doi: https://doi.org/f8thtw
Chowdhury A, Nabila J, Temitope IA, Wang S. Current etiological comprehension and therapeutic targets of acetaminophen–induced hepatotoxicity. Pharmacol. Res. [Internet]. 2020; 161:105102. doi: https://doi.org/mpnz
Sun F, Peng Y, Li Y, Xu M, Cai T. Fenton–reaction–triggered metabolism of acetaminophen for enhanced cancer therapy. Chinese Chem. Lett. [Internet]. 2023; 34(2):107507. doi: https://doi.org/gtpjjf
Jaeschke H, Gores GJ, Cederbaum AI, Hinson JA, Pessayre D, Lemasters JJ. Mechanisms of hepatotoxicity. Toxicol. Sci. [Internet]. 2002; 65(2):166–176. doi: https://doi.org/czdczc
Akgun E, Boyacioglu M, Kum S. The potential protective role of folic acid against acetaminophen–induced hepatotoxicity and nephrotoxicity in rats. Exp. Anim. [Internet]. 2021; 70(1):54–62. doi: https://doi.org/mpn2
Eshrati R, Jafari M, Gudarzi S, Nazari A, Samizadeh E, Hesami MG. Comparison of ameliorative effects of Taraxacum syriacum and N–acetylcysteine against acetaminophen–induced oxidative stress in rat liver and kidney. J. Biochem. [Internet]. 2021; 169(3):337–350. doi: https://doi.org/mpn3
Najafizadeh A, Kaeidi A, Rahmani M, Hakimizadeh E, Hassanshahi J. The protective effect of carvacrol on acetaminophen–induced renal damage in male rats. Mol. Biol. Rep. [Internet]. 2022; 49(3):1763–1771. doi: https://doi.org/mpn4
Olaniyi KS, Agunbiade TB. α–tocopherol attenuates acetaminopheninduced testicular dysfunction in adult male rats. Intern. J. Health All Sci. [Internet]. 2018; 7(1):6–11. doi: https://doi.org/mpn5
Clavo B, Martínez–Sánchez G, Rodríguez–Esparragón F, Rodríguez–Abreu D, Galván S, Aguiar–Bujanda D, Marrero–Callico G. Modulation by ozone therapy of oxidative stress in chemotherapy–induced peripheral neuropathy: The background for a randomized clinical trial. Intern. J. Mol. Sci. [Internet]. 2021; 22(6):2802. doi: https://doi.org/mpn6
Tahmasebi S, Qasim MT, Krivenkova MV, Zekiy AO, Thangavelu L, Aravindhan S, Roshangar L. The effects of oxygen–ozone therapy on regulatory T‐cell responses in multiple sclerosis patients. Cell Biol. Inter. [Internet]. 2021; 45(7):1498–1509. doi: https://doi.org/mpn7
Cattel F, Giordano S, Bertiond C, Lupia T, Corcione S, Scaldaferri M, De Rosa FG. Ozone therapy in COVID–19: A narrative review. Virus Res. [Internet]. 2021; 291:198207. doi: https://doi.org/gmnjd6
Bocci VA. Scientific and medical aspects of ozone therapy. State of the art. Arch. Med. Res. [Internet]. 2006; 37(4):425–435. doi: https://doi.org/bwgfx6
Delgadillo–Valero LF, Hernández–Cruz EY, Pedraza–Chaverri J. The Protective role of ozone therapy in kidney disease: A review. Life [Internet]. 2023; 13(3):752. doi: https://doi.org/mppd
Guven A, Gundogdu G, Sadir S, Topal T, Erdogan E, Korkmaz A, Surer I, Ozturk H. The efficacy of ozone therapy in experimental caustic esophageal burn. J. Ped. Surg. [Internet]. 2008; 43(9):1679–1684. doi: https://doi.org/c7sr69
Di Mauro R, Cantarella G, Bernardini R, Di Rosa M, Barbagallo I, Distefano A, Longhitano L, Vicario N, Nicolosi D, Lazzarino G, Tibullo D, Gulino ME, Spampinato M, Avola R, Li Volti G. The biochemical and pharmacological properties of ozone: the smell of protection in acute and chronic diseases. Intern. J. Mol. Sci. [Internet]. 2019; 20(3):634. doi: https://doi.org/gjrtfs
Khelfallah A, Aouay B, Kebieche M, Fetoui H. CYP2E1 inhibition and NF_κB signaling pathway are involved in the protective molecular effect of origanum floribundum against acetaminophen–induced acute hepatotoxicity in rats. Iranian J. Pharm. Res. [Internet]. 2021; 20(3):577. doi: https://doi.org/mppk
Madej P, Plewka A, Madej JA, Plewka D, Mroczka W, Wilk K, Dobrosz Z. Ozone therapy in induced endotoxemic shock. II. The effect of ozone therapy upon selected histochemical reactions in organs of rats in endotoxemic shock. Inflammation [Internet]. 2007; 30(3):69–86. doi: https://doi.org/fvbrqr
Placer ZA, Cushman L, Johnson BC. Estimation of products of lipid peroxidation in biological fluids. Anal. Biochem. [Internet]. 1966; 16(2):359–364. doi: https://doi.org/b96rpj
Ellman GL. Tissue sulfhydryl groups. Arch. Biochem. Biophys. [Internet]. 1959; 82(1):70–77. doi: https://doi.org/bz2vt8
Aebi H. Catalase. In: Bergmeyer HU, editor. Methods of Enzymatic Analysis. 2nd ed. Vol 2. New York: Academic Press; 1974. p. 673–684.
Beutler E. Red Cell Metabolism. A Manual of Biochemical Methods. 3rd ed. Orlando, FL, USA: Grune & Stratton; 1984. p. 310–311.
Sun Y, Oberly LW, Ying LA. Simple method for clinical assay of superoxide dismutase. Clin. Chem. [Internet]. 1988; 34: 497–500. https://doi.org/10.1093/clinchem/34.3.497
Frankel S, Reitman S, Sonnen AC. A textbook on laboratory procedure and their interpretation. In: Gradwohl RBH, editor. Gradwohl's Clinical Laboratory Methods and Diagnosis. St. Louis, MO, USA: C.V. Mosby; 1970. p 403–404.
Hamid A, Lee LS, Karim SR, Jufri NF. Hepatoprotective effects of zerumbone against paracetamol–induced acute hepatotoxicity in rats. Malaysian J. Med. Sci. 2018; 25(2):64–71. doi: https://doi.org/mppn
Tejo J. Curcumin, antioxidant activity, and paracetamol toxicity. Toxicol. [Internet]. 2021; 469–477. doi: https://doi.org/mppq
Bührer C, Endesfelder S, Scheuer T, Schmitz T. Paracetamol (Acetaminophen) and the developing brain. Intern. J. Mol. Sci. [Internet]. 2021; 22(20):11156. doi: https://doi.org/mppr
Jaeschke H, Ramachandran A, Chao X, Ding WX. Emerging and established modes of cell death during acetaminophen–induced liver injury. Arch. Toxicol. [Internet]. 2019; 93:3491–3502. doi: https://doi.org/gsjv5j
Abdulrazzaq AM, Badr M, Gammoh O, Abu Khalil AA, Ghanim BY, Alhussainy TM, Qinna NA. Hepatoprotective actions of ascorbic acid, alpha lipoic acid and silymarin or their combination against acetaminophen–induced hepatotoxicity in rats. Med. [Internet]. 2019; 55(5):181. doi: https://doi.org/mpps
Lalert L, Ji–au W, Srikam S, Chotipinit T, Sanguanrungsirikul S, Srikiatkhachorn A, Grand SM. Alterations in synaptic plasticity and oxidative stress following long–term paracetamol treatment in rat brain. Neurotox. Res. [Internet]. 2020; 37(2):455–468. doi: https://doi.org/mppt
Suhail M, Ahmad I. In vivo effects of acetaminophen on rat RBC and role of vitamin E. Indian J. Exp. Biol. 1995; 33(4):269–271. Cited in: PubMed; PMID 7558183.
Abdul–Hamid Z, Budin SB, Wen Jie N, Hamid A, Husain H, Mohamed J. Nephroprotective effects of Zingiber zerumbet Smith ethyl acetate extract against paracetamol–induced nephrotoxicity and oxidative stress in rats. J. Zhejiang Uni. Sci. B. [Internet]. 2012; 13(3):176–185. doi: https://doi.org/f3wtm5
Kumar G, Banu GS, Kannan V, Pandian MR. Antihepatotoxic effect of beta–carotene on paracetamol induced hepatic damage in rats. Indian J. Exp. Biol. [Internet]. 2005; 43(4):351–355. Cited in: PubMed; PMID 15875720.
Kuriakose GC, Kurup MG. Antioxidant and hepatoprotective activity of Aphanizomenon flos–aquae Linn against paracetamol intoxication in rats. Indian J. Exp. Biol. 2010; 48(11):1123–1130. Cited in: PubMed; PMID 21117453.
Sakran M, Selim Y, Zidan N. A new isoflavonoid from seeds of Lepidium sativum L. and its protective effect on hepatotoxicity induced by paracetamol in male rats. Molecules. 2014; 19(10):15440–15451. doi: https://doi.org/gchmxc
Wang Y, Li D, Cheng N, Goa H, Xue X, Cao W, Sun L. Antioxidant and hepatoprotective activity of vitex honey against paracetamol induced liver damage in mice. Food Funct. [Internet]. 2015; 6:2339–2349. doi: https://doi.org/f7vxw3
Zubairi MB, Ahmed JH, Al–Haroon SS. Effect of adrenergic blockers, carvedilol, prazosin, metoprolol and combination of prazosin and metoprolol on paracetamol–induced hepatotoxicity in rabbits. Indian J. Pharmacol. [Internet]. 2014; 46(6):644–648. doi: https://doi.org/mppv
Chellappan DK, Ganasen S, Batumalai S, Candasamy M, Krishnappa P, Dua K, Chellian J, Gupta G. The protective action of the aqueous extract of Auricularia polytricha in paracetamol induced hepatotoxicity in rats. Recent Pat. Drug Deliv. Formulat. [Internet]. 2016; 10(1):72–76. doi: https://doi.org/f8vqjs
Bhatt S, Sharma A, Dogra A, Sharma P, Kumar A, Kotwal P, Nandi U. Glabridin attenuates paracetamol–induced liver injury in mice via CYP2E1–mediated inhibition of oxidative stress. Drug Chem. Toxicol. 2022; 45(5):2352–2360. doi: https://doi.org/grk2xn
Yılmaz S, Kaya E. [Protective effects of propolis and artichoke in cyclophosphamide–induced hemorrhagic cystitis in rats]. F. Ü. Sağ. Bil. Tıp. Derg. [Internet] 2018 [cited 18 Oct 2023]; 32(2):93–98. Turkish. Available in: https://goo.su/E8yd
Hussain Z, Khan JA, Arshad A, Asif P, Rashid H, Asrhad MI. Protective effects of Cinnamomum zeylanicum L.(Darchini) in acetaminophen–induced oxidative stress, hepatotoxicity and nephrotoxicity in mouse model. Biomed. Pharm. [Internet]. 2019; 109:2285–2292. doi: https://doi.org/gf4376
Kannappan SGP, Raghunath G, Sivanesan S, Vijayaraghavan R, Swaminathan M. Inhibition of oxidative stress, inflammation and apoptosis by Terminalia arjuna against acetaminophen–induced hepatotoxicity in Wistar albino rats. Indian J. Biochem. Biophys. [Internet]. 2020; 57(1):51–57. doi: https://doi.org/mppw
Güvenç M, Cellat M, Gökçek İ, Özkan H, Arkalı G, Yakan A, Özsoy ŞY, Aksakal M. Nobiletin attenuates acetaminophen‐induced hepatorenal toxicity in rats. J. Biochem. Mol. Toxicol. [Internet]. 2020; 34(2):e22427. doi: https://doi.org/mmw5
Tripathi SS, Singh S, Garg G, Kumar R, Verma AK, Singh AK, Bissoyi A, Rivzi SI. Metformin ameliorates acetaminophen–induced sub–acute toxicity via antioxidant property. Drug Chem. Toxicol. [Internet]. 2022; 45(1):52–60. https://doi.org/mpp2
Aycan İÖ, Tüfek A, Tokgöz O, Evliyaoğlu O, Fırat U, Kavak GÖ, Turgut H, Yüksel MU. Thymoquinone treatment against acetaminophen–induced hepatotoxicity in rats. Intern. J. Surg. [Internet]. 2014; 12(3):213–218. doi https://doi.org/gjr2q7
Eroğlu H, Makav M, Adali Y, Citil M. Effects of ozone and L–carnitine on kidney MDA, GSH, and GSHPx levels in acetaminophen toxicity. Kafkas Univ. Vet. Fak. Derg. [Internet]. 2020; 26(1): 127–134. doi: https://doi.org/mpp3
Ucar F, Taslipinar MY, Alp BF, Aydin I, Aydin FN, Agilli M, Toygar M, Ozkan E, Macit E, Oztosun M, Cayci T, Ozcan A. The effects of N–acetylcysteine and ozone therapy on oxidative stress and inflammation in acetaminophen–induced nephrotoxicity model. Renal Fail. [Internet]. 2013; 35(5):640–647. doi: https://doi.org/mpp4
Pivotto AP, Banhuk FW, Staffen IV, Daga MA, Ayala TS, Menolli RA. Clinical Uses and Molecular Aspects of Ozone Therapy: A Review. Online J. Biol. Sci. [Internet]. 2020; 20(1):37–49. doi: https://doi.org/mpp5
Weast RC, editor. Handbook of Chemistry and Physics: 1st student ed. Boca Raton, FL, USA: CRC Press; 1988.
Clavo B, Rodríguez–Esparragón F, Rodríguez–Abreu D, Martínez–Sánchez G, Llontop P, Aguiar–Bujanda D, Fernández–Pérez L, Santana–Rodríguez N. Modulation of Oxidative Stress by Ozone Therapy in the Prevention and Treatment of Chemotherapy–Induced Toxicity: Review and Prospects. Antioxidants [Internet]. 2019; 8(12):588. doi: https://doi.org/gntgh7
Sciorsci RL, Lillo E, Occhiogrosso L, Rizzo A. Ozone therapy in veterinary medicine: a review. Res. Vet. Sci. [Internet]. 2020; 130:240–246. https://doi.org/gnqvpw
Van der Zee J, Mulder GJ, Van Steveninck J. Acetaminophen protects human erythrocytes against oxidative stress. Chem–Biol. Interact. [Internet]. 1988; 65(1):15–23. doi: https://doi.org/ddhv5q
Derechos de autor 2024 Emre Kaya, Seval Yilmaz, Feyza Aksu, Ahmet Kavaklı
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