Document Type : Original Article
Authors
1 Department of Biochemistry, Faculty of Medicine, Cairo University
2 Department of Physiology, Faculty of Medicine for Girls, Al-Azhar University
Abstract
Keywords
NEUROPROTECTIVE EFFECTS OF CHRYSIN ON ADULT MALE ALBINO RATS EXPOSED TO ACRYLAMIDE AND RADIATION
By
Laila A. Rashed*, Hanan F. Al-Saeed* and Mohammad M. El-Shawwa*
Department of Biochemistry, Faculty of Medicine, Cairo University and Department of Physiology,
Faculty of Medicine for Girls, Al-Azhar University*
+
ABSTRACT
Background: Acrylamide is a well-known industrial toxic substance that produces neurotoxicity, which is characterized by neuronal degeneration. In addition, radiation derived-brain injury is a prominent side effects of brain radiotherapy. On the other hand, chrysin (CN) is a natural biologically active compound with antioxidant and neuroprotective.
Objective: Determination of the neuroprotective effects of chrysin on brain tissue of adult male albino rats exposed to acrylamide toxicity and radiation.
Material and Methods: Seventy adult male albino rats of local strain weighed 140-160 g were used in this study. They were divided into six equal groups: Control group (A), acrylamide group (B), radiation group (C), acrylamide and radiation group (D), acrylamide and chrysin group (E), radiation and chrysin group (F) and acrylamide, radiation and chrysin group (G). By the end of the experimental period (4 weeks), sera were separated for measurement of tumor necrosis factor alpha (TNF-α) and brain derived neurotrophic factor (BDNF) level. Brain of each rat was dissected out carefully for measurement of gamma-aminobutyric acid (GABA), malondialdehyde (MDA) and glutathione (GSH) content.
Results: Chrysin increased GSH and decreased both MDA and TNF-α levels in ACR-treated rats. Moreover, it decreased the level of GABA, while it increased the BDNF level. On the other hand, adding radiation to ACR did not reduce the protective effects of chrysin regarding to all parameters except BDNF.
Conclusion: Chrysin reverses the oxidative stress and pro-inflammatory status in rats exposed to both acrylamide and radiation. Therefore, it might be used as a supportive treatment for persons frequently exposed to these environmental hazards.
Keywords: Acrylamide, radiation, chrysin, GSH, TNF-α, BDNF, GABA and MDA.
INTRODUCTION
Acrylamide is incorporated into grout and soil-stabilizer products that are used to plug leaks in dams, tunnels, and other structures. It is also transformed into polyacrylamides, which are used exten-sively in chemical industries including cosmetics, waste water management, road construction, papermaking and gel electro- phoresis for laboratory research (Mehri et al., 2015).
Acrylamide can be absorbed into the body by many ways, such as the respiratory system, digestive system, skin, and muscles. Additionally, long exposure to acrylamide may lead to toxic accumulations and result in toxic symptoms (Tian et al., 2015). The single (monomer) form of acrylamide, is discovered to be present in food e.g. french-fries, potato chips, jarred baby foods and infant biscuits (Mojska et al., 2010 and 2012). Moreover, acrylamide is formed through Maillard reaction when carbohydrate-rich food is cooked in high temperature as in baking, frying, and roasting (Krishnakumar and Visvanathan, 2014). Thus, diet is another main source of environmental ACR exposure in human (Mehri et al., 2015).
Radiation therapy has been commonly used as the standard treatment for brain tumors (Kantor et al., 2008). Controlled high energy rays such as x-ray and γ-ray are used to either kill cancer cells directly or interfere with their ability to grow. However, the use of radiation therapy for treatment of brain tumors is limited by the risk of radiation-induced damage to the normal, healthy brain tissue that can subsequently lead to devastating functional deficits (Moulder and Cohen, 2007).
Both radiations and acrylamide are present in the general environment and workplaces. Therefore, combined exposure to both agents is possible, especially at low doses (Dobrzynska, 2007 and Rao et al., 2015). The pro-oxidative and pro-inflammatory environments caused by exposure to either radiations or ACR could be implicated in the pathophysio-logical process of brain injury, and subsequent development of various neurodegenerative diseases (Dheen et al., 2007 and Kim et al., 2014).
Chrysin (5,7-dihydroxyflavone) is a natural flavonoid extracted from many plants, honey and propolis (Williams et al., 1997). It is also present in chamomile and mushroom (Anandhi et al., 2013). Several studies have shown that chrysin has multiple biological activities, such as anti-inflammatory, antioxidant and vaso-relaxant (Lapidot et al., 2002). Some studies suggested that chrysin could be considered as a neuroprotective agent in different animal models (Mercer et al., 2005 and He et al., 2012).
The present study was performed to investigate the neuroprotective effects of chrysin on rats exposed to ACR and/or exposure to radiation and the possible underlying mechanisms of all these effects.
MATERIALSAND METHODS
Animals and experimental design: This study was performed on 70 adult male albino rats of local strain weighing 140–160 gm. The animals were housed in laboratory animal cages (45 x 40 x 25 per 5 rats) They were kept at room temperature in normal day/night rhythm with free access to food and water all over the period of the work (4 weeks) in the animal house of National Center for Radiation Research and Technology, Cairo, Egypt. After seven days of acclimatization the rats were randomized into 6 equal groups as follows:
1. Control group (A): Each rat received 1ml normal saline (0.9%) by oral gavage for 4 weeks.
2. Acrylamide group (B): Each rat received 40 mg/kg/day of ACR in a volume of 1 ml normal saline day by oral gavage for 4 weeks (Pan et al., 2015).
3. Radiation group (C): Rats were given fractionated brain radiation 5 Gy/day for 5 days/week for 4 weeks (Zhoua et al., 2011 and Martin et al., 2013).
4. Acrylamide and radiation group (D): Rats were given both ACR (40 mg/kg/day) and fractionated radiation (5 Gy/day for 5 days/week) for 4 weeks.
5. Acrylamide and chrysin group (E): Rats were given ACR (40 mg/kg/day) and treated with chrysin (100 mg/kg/day) by oral gavage (Wang and Morris, 2007).
6. Radiation and chrysin group (F): Rats were given fractionated radiation (5 Gy/day for 5 days/week) and chrysin (100 mg/kg/day by oral gavage) for 4 weeks.
7. Acrylamide, radiation and chrysin group (G): Rats were exposed to ACR (40 mg/kg/day by oral gavage), radiation (5 Gy/day for 5days/week) and chrysin (100 mg/kg/day by oral gavage) for 4 weeks.
Drugs and chemicals: ACR and chrysin were purchased from Sigma chemical company (USA).
Irradiation processing: Irradiation was performed using Canadian gamma cell-40, (137Cs) at the National Center for Radiation Research and Technology, Cairo, Egypt. Animals were exposed to fractionated whole body γ-radiation delivered as 5 Gy/day for 5 days/week at a dose rate of 0.61 Gy/minute (Zhoua et al., 2011 and Martin et al., 2013).
Sample collection and biochemical assays: The animals were anesthetized at the end of the experiments and blood samples were obtained from the orbital sinus of overnight fasted rats. Blood was immediately centrifuged at 3000 rpm for 20 minutes. Sera were separated and stored at -80◦C for measurement of TNF- α and BDNF levels. Brain of each rat was dissected out carefully, wrapped with aluminum foil and kept frozen at -80◦ C for measurement of GABA, MDA and GSH contents.
Estimation of MDA in brain tissue (Tükӧzkan et al., 2006).
Estimation of GSH in brain tissue (Khan et al., 2012).
Statistical analysis: Data were expressed as means ± standard deviation (SD). Statistical comparison between different groups were done using one-way analysis of variance (ANOVA) followed by Tukey HSD multiple comparison test to judge the difference between various groups. All calculations were performed using the SPSS 16.0 software package. Significance was accepted at P< 0.05.
RESULTS
The brain tissue TNF-α level in control group (A) was significantly lower than all other groups, while in acrylamide and radiation group (D) was significantly the highest among the all groups. The TNF-α levels in acrylamide and chrysin group (E), radiation and chrysin group (F) and acrylamide, radiation and chrysin group (G) were significantly lower than acrylamide group (B), radiation group (C) and (D). There were no significant changes between (B)and (C). Also, there were no significant changes between (E), (F) and (G) regarding to brain tissue TNF-α level.
The brain tissue MDA level in (A) was significantly lower than all other groups and in (E)and (F) was significantly lower than (B), (C) and (D). There were no significant changes between (B), (C) and (D). Also, there were no significant changes between (E), (F) and (G) regarding brain tissue MDA level.
The brain tissue GSH level in (A) was significantly higher than all other groups, while in groups (E) and (F) were significantly higher than (B), (C) and (D). There were no significant changes between (B), (C) and (D). Also, there were no significant changes between (E), (F) and (G) regarding brain tissue GSH level.
The brain tissue BDNF level in (A) was significantly higher than in all other groups, and in (E) and (F) was significantly higher than (B), (C) and (D). BDNF level was significantly lower in (D) compared to (B) and (C), while no significant difference was observed between (B) and (C). Also, they decreased significantly in (G) compared to (E) and (F) .
The brain tissue GABA level in (A) was significantly lower than in other groups, and in (E) and (F) was significantly lower than (B), (C) and (D). GABA level was significantly higher in (D) compared to (B) and (C), while no significant difference was observed between (B) and (C). Also, there were no significant changes between (E), (F) and (G) regarding brain tissue GABA level (Table 1).
DISCUSSION
In this study, the brain tissue TNF-α level increased after exposure to either ACR or irradiation compared to control group with no significant difference between either ACR or irradiation groups. TNF-α level in rats co-exposed to ACR and irradiation was significantly the highest among the all groups. Many intracellular pathways are set in motion by the binding of TNF to its cell surface receptors. Major steps in the TNF-mediated cytotoxicity cascade include G protein-coupled activation of phospho-lipases, generation of free radicals, and damage to nuclear DNA by endonuc-leases. Eventually the cells undergo apoptosis and die (Wang et al 2015).
The result of this work is compatible with the study of Xue et al., (2014).
In this study, rats exposed to ACR and/or irradiation showed significant increase in brain content of MDA. On the other hand, the brain content of GSH decreased significantly in the same groups. There were no significant
changes between these groups regarding to both parameters. These results indicated that ACR induces oxidative stress leading to protein and lipid peroxidation (Venkataswamy et al., 2013).
ACR is metabolized by 2 main pathways-conjugation with glutathione and excretion as mercapturic acids and by oxidation to glycidamide, a reactive epoxide. Glycidamide undergoes further metabolism by conjugation with glutathione, to form several mercapturic acids, and by hydrolysis (Fennell et al., 2015). This conjugation leads to depletion of GSH compounds that have a role in neutralization of free radicals that is produced by ACR and its metabolite glutathione (Swaran and Flora, 2009).
Increased MDA is associated with increased oxidative stress, declined antioxidant capacity in nervous tissue and sciatic nerve and induced apoptosis in cerebral cortex of rats (Lakshmi et al., 2012 and Nixon et al., 2012). Matveychuk et al. (2011) reported thatlipid and protein peroxidation play a significant role in neurodegenerative disorders including Alzheimer’s disease.
The result of this work was compatible with the study of Guney et al. (2005). They reported that the decline of GSH level in the brain after irradiation might be due to its consumption during the oxidative stress induced by irradiation. Moreover, Listy (2014) reported that oxidative stress caused by radiation elevates MDA level in brains of rats due to increase lipid peroxidation. Irradiation caused the oxidative stress as an outcome of a disturbance between production of ROS and antioxidant defense mecha-nisms. Irradiation activates microglia and causes infiltration of the brain. Upon activation, these cells produce ROS and activate more microglia and immune cells that can increase the level of oxidative stress (Balentova and Adamkov, 2015).
Accordingly, several studies reported that oxidative stress and inflammation
in brain are the key mechanisms in ACR and irradiation induced cell injuries. (Prasad and Muralidhara, 2014; Balentova & Adamkov, 2015 and Santhanasabapathy et al., 2015). Interestingly, the results of this work may support this interpretation.
In the present work, the level of BDNF in rats exposed to both ACR and radiation decreased significantly compared to those exposed to only ACR or radiation suggesting additive effects of both hazards, which provide some insights to the toxicological mechanism of them. Woehrling et al., (2013) reported that BDNF release is decreased due to ACR toxicity in some neuronal cell culture models. It has been reported that radiation-induced brain injury can damage neuronal, glial and vascular compartments of the brain. Interference with the cell cycle regulatory proteins and consequent apoptosis are the primary mechanisms responsible for cell death that occurs within several hours after irradiation (Balentova and Adamkov, 2015).
Gamma-aminobutyric acid is one of the most important inhibitory neuro-transmitters in the CNS. It plays the principal role in reducing neuronal excitability throughout the nervous system (Watanabe et al., 2002). Either low GABA level or decreased GABA function in the brain is associated with several psychiatric and neurological disorders, including anxiety, depression, insomnia, and epilepsy (Kendell et al., 2005). High level of GABA may cause synaptic depression and be involved in slow, long-term neuronal damage (Tian et al., 2015).
In this study, the brain tissue GABA level increased after exposure to either ACR or irradiation compared to control group with no significant difference between either ACR or irradiation groups. GABA level in rats co-exposed to ACR and irradiation were significantly the highest among the all groups.
The results of this work regarding GABA level in brain is compatible with work of Tian et al., (2015). They found that brain content of GABA increased in rats after induction of ACR neurotoxicity, which provides an experimental evidence of the mechanism of neurotoxicity induced by ACR. Others noticed that the toxic effects of ACR on the cerebellum of rats is associated with the increased expression of GABA (Shi et al., 2016).
Regarding to radiation-induced changes in GABA function, Vlkolinský et al. (2008) reported that fractionated irradia-tion produces changes in expression of GABA receptors in brain of mice. Others noticed that radiation increases the surface expression of inhibitory gamma-aminobutyric acid receptors (Wu et al., 2012). On the other hand,
The present study demonstrated the neuroprotective effects of chrysin which led to reverse of oxidative stress and pro-inflammatory status in rats exposed to either acrylamide or radiation or both through increasing GSH and decreasing both MDA and TNF-α levels. Moreover, it decrease the level of the inhibitory neurotransmitter GABA, while it increase the BDNF level returning all parameters towards normal levels. On the other hand, adding radiation to ACR and chrysin did not reduce the protective effects of chrysin regarding to all parameters except BDNF.
Studies suggested that chrysin could be as a neuroprotective agent in different models. Mehri et al., (2014) reported that chrysin was able to prevent cell death and the gait abnormalities induced by ACR.
In this study, treatment of acrylamide group with chrysin led to lowering of TNF-α which is compatible with the study of Gresa-Arribas et al., (2010).
The result of this work was also compatible with Souza et al., (2015) who reported that chrysin prevents age-related cognitive decline via attenuation of oxidative stress and modulation of BDNF level. In addition, the potential anti-inflammatory and antioxidant properties of chrysin have been reported in several researches. Anand et al., (2012) showed that CR reduces the disturbances of redox status, named superoxide dismutase (SOD), catalase (CAT), glutathione peroxidase (GPx), and glutathione in liver, kidney, and brain tissues of rats treated with D-galactose. Moreover, chrysin significantly improves memory impair-ment and neuronal cell apoptosis induced by chronic cerebral hypoperfusion in rats. It decreased lipid peroxide, reduced the increased activities of superoxide dismutase, and attenuated the activities of glutathione peroxidase in these rats (He et al., 2012 and Yao et al., 2014). Pushpavalli et al. (2010) showed that chrysin acts as a hepato-protective and antioxidant agent against d-galactosa-mine-induced hepatotoxicity.
The results of this work was also supported by Benkovic et al. (2008) and Ozgur et al. (2016).
In conclusion, the present study demonstrated the anti-inflammatory and antioxidant protective effects of chrysin, which reversed the oxidative stress in rats exposed to acrylamide and radiation. Adding radiation to ACR and chrysin carrying no significant differences regarding all the parameters except BDNF compared to ACR and chrysin. Therefore, chrysin might be used as a supportive treatment for those frequently exposed to ingested acrylamide and/or radiation. Further studies are required to clarify the effects and mechanisms of action of chrysin on hazards of brain radiation.
REFERENCES
1. Al-Serwi RH and Ghoneim FM (2013): The impact of vitamin E against acrylamide induced toxicity on skeletal muscles of adult male albino rat tongue: Light and electron microscopic study. Journal of Microscopy and Ultrastructure, 3(3):137–147.
2. Anand KV, Jaabir MM, Thomas PA and Geraldine P (2012): Protective role of chrysin against oxidative stress in d-galactose-induced aging in an experimental rat model. Geriatrics and Gerontology International, 12(4):741–750.
3. Anandhi R, Annadurai T, Anitha TS, (2013): Antihypercholesterolemic and anti-oxidative effects of an extract of the oyster mushroom, Pleurotus ostreatus, and its major constituent, chrysin, in Triton WR-1339-induced hypercholesterolemic rats. J Physiol., Biochem., 69: 313–323.
4. Balentova S and Adamkov M (2015): Molecular, Cellular and Functional Effects of Radiation-Induced Brain Injury: A Review. Int J Mol Sci., 16(11):27796-27815.
5. Benkovic V, Horvat-Knezevic A and Orsolic N (2009): Evaluation of radio protective effects of propolis and its flavonoid constituents: in vitro study on human white blood cells. Phyto Research, 23(8):1159-1168.
6. Cai HL, Zhu RH, Li HD, Zhang XH, Hu L, Yang W and Ye HS (2010): Elevated plasma γ-aminobutyrate/glutamate ratio and responses to risperidone antipsychotic treatment in schizophrenia. Prog Neuropsychopharmaco Biol Psychiatry, 1:34(7):1273-8.
7. Dheen, S.T., Kaur C and Ling EA. (2007): Microglial activation and its implications in the brain diseases. Curr Med Chem, 14:1189-97.
8. Dobrzyn´ska, MM. (2007): Assessment of DNA damage in multiple organs from mice exposed to x-rays or acrylamide or a combina-tion of both using the comet assay. In vivo, 21:657-662.
9. Fennell TR Snyder R, Hansen B and Friedman M (2015): Dosimetry of Acrylamide and Glycidamide Over the Lifespan in a 2-Year Bioassay of Acrylamide in Wistar Han Rats. Toxicological Sciences, 146(2):386-394.
10. Gresa-Arribas N, Serratosa J, Saura J and Solà, C (2010): Inhibition of CCAAT/enhancer binding protein δ expression by chrysin in microglial cells results in anti-inflammatory and neuroprotective effects. J Neurochem, 115(2): 526-36.
11. Guney Y, Bilgihan A, Hicsonmez A, Dizman A. Ozogul C, Andrieu MN and Kurtman C (2005): Influence of Different Doses of Irradiation on Oxidant and Antioxidant Systems in the Brain of Guinea Pigs. American Journal of Immunology, (3):114-118.
12. He XL, Wang YH, Bi MG and Du GH (2012): Chrysin improves cognitive deficits and brain damage induced by chronic cerebral hypoperfusion in rats. Eur J Pharmacol, 680 (1-3):41–8.
13. Kantor G, Laprie A, and Huchet A (2008): Radiation therapy for glial tumors: technical aspects and clinical indications. Cancer Radiother, 12:687-94.
14. Kendell SF, Krystal JH and Sanacora (2005): GABA and glutamate systems as therapeutic targets in depression and mood disorders. Expert Opin Ther Targets, 9:153-168.
15. Khan, RA, Khan, MR. and Sahreen, S. (2012): Brain antioxidant markers, cognitive performance and acetylcholinesterase activity of rats: efficiency of Sonchus asper. Behav Brain Funct. 8:21.
16. Kim HS, Bernitz J, Lee DF and Lemischka IR (2014): Genomic editing tools to model human diseases with isogenic pluripotent stem cells. Disease Models & Mechanisms, 6: 896-904.
17. Krishnakuma T and Visvanathan R (2014): Acrylamide in Food Products: A Review Food Processing & Technology, 5(7):5-7.
18. Lakshmi D, Gopinath K, Jayanthy G, Anjum S, Prakash D and Sudhandiran G (2012): Ameliorating effect of fish oil on acrylamide induced oxidative stress and neuronal apoptosis in cerebral cortex. Neurochem Res, 37(9):1859-67.
19. Lapidot T, Walker MD and Kanner J (2002): Antioxidant and prooxidant effects of phenolics on pancreatic beta-cells in vitro. J Agric Food Chem, 50:7220–7225.
20. Listy B. (2014): Evaluation of oxidant stress and antioxidant defense in discrete brain regions of rats exposed to 900 MHz radiation. Bratisl Lek Listy, 115(5):260-6.
21. Martin LM, Marples B, Lynch TH, Hollywood D and Marignol L (2013): Exposure to low dose ionising radiation: Molecular and clinical consequences. Cancer Lett, 338:209–218.
22. Matveychuk D, Dursun SM Wood PL and Baker GB (2011): Reactive aldehyde and neurodegenerative disorders. Bull Clin Psychopharm., 21:277-288.
23. Mehri S, Abnous K, Khooei A, Mousavi SH, Shariaty VM and Hosseinzadeh H (2015): Crocin reduced acrylamide‐induced neuro-toxicity in Wistar rat through inhibition of oxidative stress. Iran J Basic Med Sci, 18 (9): 902-8.
24. Mehri S, Karami HV, Hassani FV and Hosseinzadeh H (2014): Chrysin reduced acrylamide-induced neurotoxicity in both in vitro and in vivo assessments. Iran Biomed J 18:101-106.
25. Mercer LD, Kelly BL, Horne MK and Beart PM (2005): Dietary polyphenols protect dopamine neurons from oxidative insults and apoptosis: investigations in primary rat mesencephalic cultures. Biochem Pharmacol, 69:339–345.
26. Mojska H, Gielecińska I, Szponar L and Ołtarzewski M (2010): Estimation of the dietary acrylamide exposure of the Polish population. Food Chem Toxicol, 48:2090-2096.
27. Moulder JE and Cohen EP (2007): Future Strategies for Mitigation and Treatment of Chronic Radiation-Induced Normal Tissue Injury. Seminars in Radiation Oncology, 17(2):141-148.
28. Nixon BJ, Stanger SJ, Brett, Nixon B and Roman SD (2012): Chronic Exposure to Acrylamide Induces DNA Damage in Male Germ Cells of Mice. Toxicol Sci, 129:135-145.
29. Ozgur Y, Aliyazicioglu Y, Demir S, Turan I, Bahat Z, Misir S and Deger O (2016): Evaluation of the radioprotective effect of Turkish propolis on foreskin fibroblast cells. Journal of Cancer Research and Therapeutics, 12:2-8.
30. Pan, X, Zhu L, Lu H., Wang D., Lu Q and Yan H. (2015): Melatonin Attenuates Oxidative Damage Induced by Acrylamide In Vitro and In Vivo. Oxidative Medicine and Cellular Longevity. 2015:1-12.
31. Prasad SN and Muralidhara (2014): Mitigation of acrylamide-induced behavioral deficits, oxidative impairments and neuro-toxicity by oral supplements of geraniol (a monoterpene) in a rat model. Chem Biol Interact, 223:27-37.
32. Pushpavalli G, Kalaiarasi P, Veeramani C and Pugalendi KV (2010): Effect of chrysin on hepatoprotective and antioxidant status in D-galactosamine-induced hepatitis in rats. Eur J Pharmacol, 631:36-41.
33. Rao A, Verma A and Singh BR (2015): Ionizing radiation effects on electrical and reliability characteristics of sputtered Ta2O5/Si interface. Radiation Effects and Defects in Solids, 6(170):510-518.
34. Rios M, Fan G, Fekete C, Kelly J, Bates B, Kuehn R, Lechan RM and Jaenisch R (2001): Conditional deletion of brain-derived neurotrophic factor in the postnatal brain leads to obesity and hyperactivity. Molec Endocr, 15:1748-1757.
35. Santhanasabapathy R, Vasudevan S, Anupirya K, Pabitha R and Sudhandiran G (2015): Farnesol quells oxidative stress, reactive gliosis and inflammation during acrylamide-induced neurotoxicity: Behavioral and biochemical evidence. Neuroscience, 308:212-27.
36. Shi J, Ma Y, Zheng M and Ruan Z, Liu J, Tian S, Zhang D, He X and Li G (2016): Effect of sub-acute exposure to acrylamide on GABAergic neurons and astrocytes in weaning rat cerebellum. Toxicology and Industrial Health, 28(1):10-20.
37. Souza LC, Antunes M., Filho CB, Del Fabbro L, de Gomes MG, Goes AT, Donato F, Prigol M, Boeira SP and Jesse CR (2015): Flavonoid Chrysin prevents age-related cognitive decline via attenuation of oxidative stress and modulation of BDNF levels in aged mouse brain. Pharmacol Biochem Behav, 134:22-30.
38. Swaran JS and Flora S (2009): Structural, chemical and biological aspects of antioxidants strategies against metal and metalloids exposure. Oxid Med Cell Longev, 2:191-206.
39. Tian, B, Nowak DE, Jamaluddin M, Wang S and Brasier AR. (2005): Identification of direct genomic targets downstream of the nuclear factor-kappaB transcription factor mediating tumor necrosis factor signaling. J. Biol. Chem. 280(17):17435-7448.
40. Tian S, Ma Y, Shi J, Lou T, Liu S and Li G (2015): Acrylamide neurotoxicity on the cerebrum of weaning rats. Neural Regen Res, 10(6): 938–943.
41. Tükӧzkan N, Erdamar, H. and Seven, I. (2006): Measurement of total malondialdehyde in plasma and tissues by high-performance liquid chromatography and thiobarbituric acid assay. Experimental Research. Fırat Tıp Dergisi.11(2): 88-92
42. Venkataswamy M, Divya K, Pallavi C and Thyagraju C (2013): characterization of glutathione-s-transferase-suppression of anti-oxidant enzyme by acrylamide in developing chick embryonic brain. Int J Pharmacol, Biol Sci, 4:668-677.
43. Vlkolinský R, Krucker T, Nelson GA and Obenaus A (2008): 56Fe-particle radiation reduces neuronal output and attenuates lipopolysaccharide-induced inhibition of long-term potentiation in the mouse hippocampus. Radia. Res, 169:523-530.
44. Wang X and Morris ME (2007): Effects of the flavonoid chrysin on nitrofurantoin pharmacokinetics in rats: potential involvement of ABCG2. Drug Metab Dispos, 35:268-274.
45. Wang JS, Wu D, Huang DY and Wan W (2015): TAK1 inhibition-induced RIP1-dependent apoptosis in murine macrophages relies on constitutive TNF-α signaling and ROS production. Journal of Biomedical Science, 22:76-89.
46. Watanabe M, Maemura K, Kanbara K, Tamayama T and Hayasaki (2002): GABA and GABA receptors in the central nervous system and other organs. Int Rev Cytol International Review of Cytology, 213:1–47.
47. Williams, CA, Harborne, JB, Newman, Greenham, J and Eagles, J. (1997): Chrysin and other leaf exudate flavonoids in the genus Pelargonium. Phytochemistry., 46:1349–1353.
48. Woehrling EK, Hill EJ, Nage D and Coleman MD (2013): Brain-derived Neurotrophic Factor as an Indicator of Chemical Neurotoxicity: An Animal-free CNS Cell Culture Model. ATLA, 41:503–511.
49. Wu PH, Coultrap S, Pinni, C, Davies KD, Tailor R, Ang KK, Browning MD and Grosshans DR (2012): Radiation induces acute alterations in neuronal function. PLOS ONE, 7:76-77.
50. Xue J, Dong JH, Huang GD, Qu XF, Wu G and Dong XR (2014): NF-κB signaling modulates radiation-induced microglial activation. Oncol. Rep, 31:2555–60.
51. Yao X, Yan L, Yao L, Guan W, Zeng F, Cao F and anshu Zhang Y (2014): Acrylamide exposure impairs blood-cerebrospinal fluid barrier function. Neural Regen Res. 9:555-560.
52. Zhoua H, Liua, Liua J, Wangb J, Zhoud D, Zhaoa Z, Xiaoa S, Taoa E and Suoe WZ (2011): Fractionated Radiation-Induced Acute Encephalopathy in a Young Rat Model: Cognitive Dysfunction and Histologic Findings. AJNR, 32:1795.
تأثیرات الحمایة العصبیة لعقارالکریسین على تسمم الجرذان الذکور البیضاء البالغة المتعرضة للأکریلامید والإشعاع
لیلى أحمد راشد - حنان فتحیالسعید* - محمد محمد الشوا*
قسم الکیمیاء الحیویة- کلیة الطب – جامعة القاهرة
قسم الفسیولوجیا - کلیة الطب (بنات) - جامعة الأزهر*
خلفیة البحث: الأکریلامید مادة صناعیة سامة معروفة جداً تؤدی الی تسمم الخلایا العصبیة الذى یتمیز بتآکل الخلایا العصبیة. بالإضافة إلی ذلک، فإن إصابات المخ الناجمة عن الإشعاع تعد من الآثار الجانبیة البارزة للعلاج الإشعاعی للمخ. یعتیر الکریسین من المواد الطبیعیة النشطة بیولوجیاً وله خصائص مضادة للأکسدة وذات طبیعة علاجیة للأعصاب.
الهدف من البحث:تحدید التأثیرات العصبیة العلاجیة لعقار الکریسین على نسیج مخ ذکور الجرذان البیضاء المتعرضة للتسمم بالأکریلامید والإشعاع.
مواد وطرق البحث: إستخدم فی هذا البحث سبعون من ذکور الجرذان البیضاء البالغة من سلالة محلیة تتراوح أوزانها بین ١٤۰-١٦۰جراماً. وقد تم تقسیم الجرذان إلى سبع مجموعات متساویة: المجموعة الضابطة، مجموعة الأکریلامید، مجموعة الإشعاع، مجموعة الأکریلامید والإشعاع، مجموعة الأکریلامید والکریسین، مجموعة الإشعاع والکریسین، مجموعة الأکریلامید والإشعاع والکریسین. وفی نهایة فترة التجربة (٤ أسابیع) تم جمع عینات الدم لقیاس عامل نخر الورم والعامِلَ التغذویّ العصبیّ المُشتقّ من الدِّماغ. وقد تم استخراج المخ لکل فأر بعنایة لقیاس محتویاته من حامض جاما أمینو بیوتریک و المالوندایالدهید والجلوتاثیون.
النتائج: أدى استعمال مادة الکریسین فی الجرذان التی تلقت أکریلامید إلى إرتفاع مستوى الجلوتاثیون وإنخفاض مستوى المالوندایالدهید وعامل نخر الورم. إضافة إلى ذلک، إرتفع العامِلَ التغذویّ العصبیّ المُشتقّ من الدِّماغ وإنخفض حامض جاما أمینو بیوتریک. على الجانب الآخر: عند إضافة الإشعاع: لم تقل التأثیرات العلاجیة لمادة الکریسین لکل القیاسات بإستثناء العامِلَ التغذویّ العصبیّ المُشتقّ من الدِّماغ.
الإستنتاج:عکس الکریسین آثار کلا من الإجهاد التأکسدی والحالة المنشطة للإلتهابات فی الجرذان المعرضة للأکریلامید والإشعاع. ولذلک یمکن إستخدام الکریسین کعلاج داعم عند التعرض لهذه الأخطار البیئیة.