|تعداد مشاهده مقاله||108,025,222|
|تعداد دریافت فایل اصل مقاله||84,454,760|
Effect of Ginkgo biloba Leaf Extract (EGb 761) on Changes in Haematological Parameters and Erythrocyte Osmotic Fragility in Hypotonic and Chlorpyrifos Exposed Rats
|Iranian Journal of Veterinary Medicine|
|مقاله 1، دوره 13، شماره 4، دی 2019، صفحه 332-341 اصل مقاله (324.19 K)|
|نوع مقاله: Physiology- Pharmacology-Biochemistry -Toxicology|
|شناسه دیجیتال (DOI): 10.22059/ijvm.2019.279519.1004980|
|Sani Abdulrazak* 1؛ Adulmumin Abdulkabir Nuhu2؛ Zakka Yashim2|
|11Department of Veterinary Physiology, Ahmadu Bello University, P.M.B. 1069, Zaria, Kaduna, Nigeria. 2Department of Chemistry, Ahmadu Bello University, P.M.B. 1069, Zaria, Kaduna, Nigeria.|
|2Department of Chemistry, Ahmadu Bello University, P.M.B. 1069, Zaria, Kaduna, Nigeria.|
|BACKGROUND: Canine low-dose sepsis model provides a reliable setting to study innovative drugs. Lipopolysaccharides (LPS), a major constituent of bacterial outer membrane, have been demonstrated to play a critical role in the initiation of pathogenesis. Lipopolysaccharide-induced sepsis has been extensively studied in laboratory animals; but its importance has mainly remained unknown in dogs. OBJECTIVES: The aim of the present survey was to examine the effectiveness of quercetin, along with hydrocortisone on clinical and hematological alterations, and organ failure (liver and heart) in low-dose lipopolysaccharide-induced canine sepsis model. METHODS: For this purpose, fifteen clinically healthy mixed dogs were randomly divided into three equal groups. Lipopolysaccharide (0.1 μg/kg, IV) was injected to dogs in group A (control). Group B was similar to group A, but quercetin bolus (2 mg/kg, IV, once) was injected 40 minutes after LPS injection. Group C was similar to group B; however, hydrocortisone bolus (2 mg/kg, IV, once) was administered instead of quercetin. Serum levels of glucose, total protein, albumin, alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (ALP), creatine kinase isoenzyme muscle/brain (CK-MB), lactate dehydrogenase (LDH) and cardiac troponin I (cTn-I) concentration were measured by commercial kits. RESULTS: In control group, red blood cells (RBCs), hemoglobin (Hb), and hematocrit (HCT) significantly decreased and serum activities of AST, ALP, LDH, CK-MB, and plasma cTn-I significantly increased (p <0.05). RBCs, Hb, and HCT significantly increased in quercetin group, compared with hydrocortisone and control groups (p <0.05). Quercetin group significantly decreased LDH, CK-MB, and cTn-I compared with hydrocortisone and control groups (p <0.05). Quercetin significantly decreased AST in comparison to control group and ALP in comparison to hydrocortisone group, also (p <0.05). CONCLUSIONS: These results suggest that quercetin protects RBCs in the early stages of sepsis and decreases organs dysfunction (heart and liver), therefore it has a positive influence on sepsis and may be more effective than routine corticosteroid (hydrocortisone) therapy.|
|Chlorpyrifos؛ Ginkgo biloba؛ haematology؛ rats؛ vitamin E|
|عنوان مقاله [English]|
|اثر عصاره برگ گیاه کهن دار(EGb 761) برروی تغییرات پارامترهای هماتولوژیک و شکنندگی اسمزی گلبولهای قرمز خون رت های مواجهه داده شده با سم کلرپریفوس|
|سانی عبدالرزاق1؛ عبدالمومن عبدالکریم نوهو2؛ زاکا یاشیم2|
|1گروه فیزیولوژی دامپزشکی،دانشگاه احمدوبلو،زاریا ،کادونا،نیجریه|
|2گروه شیمی،دانشگاه احمدو بلو،زاریا ،کادونا،نیجریه|
|کلرپریفوس, گیاه کهن دار, هماتولوژی, موش, ویتامین E|
Ginkgo biloba has existed for millions of years. The plant belongs to the family Gink- goaceae and it originated from Asia (Nuhu, 2014). The standardised extract of Ginkgo biloba (EGb 761®) with well defined com- ponents used in this study is one of the most accepted and widely used herbal medici- nal products in the world (Xie et al., 2014). The extract is considered relatively non-tox- ic and safe for consumption (Abdulrazak et al., 2018). The major constituents of the ex- tract are flavonoids (Nuhu et al., 2017) and terpenoids (Van beek, 2002). The flavonoid fraction is composed of quercetin, kaemp- ferol, isorhamnetin and glycosides, while the terpenoid fraction contains the ginkgolides A, B, C and J, as well as bilobalide. These com- pounds in EGb 761® are actively involved in the regulation of cellular metabolism, cell protective effect against toxins, and assist in balancing physiological status under oxida- tive stress (Yoshikawa et al., 1999), unlike most synthesized drugs with only one target function in their mechanism of action (He et al., 2009). The mechanisms of action of the extract are related to its antioxidant effect, and anti-platelet activating factor (Anti-PAF) ac- tivity (Smith and Luo, 2004). He et al. (2009) investigated the effects of EGb 761 on the properties of human red blood cells in the presence and absence of amyloid peptide (A β 25-35), peroxide and hypotonic stress. The findings reported that the protective effect of EGb 761® on red blood cells was dependent on the type of external stress present. Accord- ing to Chan et al. (2007), antioxidant protec- tive ability of EGb 761® is related to its ability to inhibit nitric oxide-stimulated protein ki- nase C (PKC) activity.
Chlorpyrifos is widely used today espe- cially in northern Nigeria, as a pesticide,
and it has been known to induce oxidative stress (Nuhu et al., 2017). Exposure in both humans and animals is commonly via food products. It elicits many adverse effects, some of which are: haemotoxicity, genotox- icity, neurochemical and neurobehavioural changes (Uchendu et al., 2012). United States Environmental Protection Agency restricted some of its domestic use in 2000 based on human health risk (Uchendu et al., 2012). Some of the symptoms of chlorpyrifos poi- soning in human and animals include head- ache, dizziness, salivation, unconsciousness, convulsion and death (Akhtar et al., 2009).
The underlying principle behind the ther- apeutic action of the Ginkgo leaf extract on chronic ailments (such as oxidative stress, poisoning, neurodegenerative and cardiovas- cular diseases) has focused on its antioxidant effects (Xie et al., 2014), which are elicited via two mechanisms of action; inhibition of free radical formation, and free radical scav- enging activity. It scavenges reactive oxy- gen species (ROS) such as hydroxyl radicals (OH˙), peroxyl radical (ROO˙), superox- ide anion radical (O2−˙), nitric oxide radical (NO˙), hydrogen peroxide (H2O2), and ferryl
ion species (Mahadevan and Park, 2007). The
extract can also enhance activities of antioxi- dant enzymes such as superoxide distmutase (SOD), glutathione peroxidase, catalase, and/or heme oxygenase-1, thereby indirectly contributing as an antioxidant (Mahadevan and Park, 2007). It has been suggested that Ginkgo leaf extract increases expression of mitochondrial enzymes, NADH dehydroge- nases, which can influence ROS generation in the mitochondria.
This study aimed to evaluate the phyto- chemical constituents of EGb 761®, effect of the extract on haematological parameters and
erythrocyte osmotic fragility in rats exper- imentally exposed to chlorpyrifos-induced oxidative stress, and also to determine the effect of the extract on erythrocyte osmotic fragility under hypotonic stress.
Materials and Methods
Phytochemical Screening of the Extract Phytochemical screening of the stan- dardised extract of Ginkgo biloba leaf extract (EGb 761®) (Nutra Green Biotechnology Co. Ltd, United Kingdom) was carried out using standard methods (Silva et al., 1998; Trease
and Evans 2002).
Experimental Animals and Management Albino rats, weighing between 180 - 200 g, were acclimatised for 2 weeks prior to the experiments; the rats were given access to pellets of feed prepared from grower’s mash, maize bran and groundnut cake at the ratio of 4:2:1 and water was provided ad libitum. The feed was produced in the Animal section of the Department of Veterinary Physiology, Faculty of Veterinary Medicine, Ahmadu Bello University, Zaria. All animal experi- mentation was done in accordance with Ah- madu Bello University Animal Use and Care Guidelines. Ethical clearance was obtained with approval number ABUCAUC/2016/015 from Committee on Animal Use and Care,
Ahmadu Bello University, Zaria.
The method of Ambali et al. (2012) was used with modifications to accommodate both the pre-treatment and post-treatment activity of EGb 761® vis-à-vis the treated control. The dosages for Vitamin E (100 mg/ ml), Ginkgo biloba leaf extract (100 mg/ml), and chlorpyrifos (10.6 mg/ml) used for this study were 100 mg/kg, 100 mg/kg, and 10.6 mg/kg, respectively. Timing and the choice of treatment doses for the study were in-
formed by the acute toxicity study (L.D50 > 5000 mg/kg) and several trial experiments, as supported by previous studies (Sarikçio- glu et al., 2004, Biddlestone et al., 2007 and Ambali et al. 2012) .
For the effects of the extract on haemato- logical parameters and on erythrocyte osmot- ic fragility in chlorpyrifos-exposed rats, thir- ty-five albino rats were divided into seven groups of five rats each; Group A (Distilled water, 5 ml/kg) served as untreated control and administered only distilled water. Group B (VE+CPF) was pre-treated with vitamin E and then administered chlorpyrifos 30 min later, Group C (CPF+VE) was administered with chlorpyrifos and then vitamin E 30 min later, Group D (Extract+CPF) was pre-treat- ed with the extract, and then with chlorpy- rifos 30 min later, Group E (CPF+Extract) was administered with chlorpyrifos and the extract 30 min later, Group F (Extract only) was administered with the extract only and Group G (CPF only) was administered with chlorpyrifos only. The regimens were ad- ministered orally once daily for two weeks. The administered doses in ml of vitamin E, Ginkgo biloba leaf extract and chlorpyrifos used for this study were obtained by the for- mula;
Consequently, each animal received 0.18-
0.20 ml dose of the respective treatment type per day depending on their individual body weight (180-200 g).
In the erythrocyte osmotic fragility study of non-chlorpyrifos-exposed rats, fifteen rats were divided into 3 groups of five animals each. Groups A, B, and C were administered with Ginkgo biloba leaf extract, Vitamin E,
and isotonic saline at a dosage of 100 mg/ kg, 100 mg/kg, and 5 ml/kg respectively. The regimens were administered once daily by oral gavage for a period of 2 weeks.
The animals were sacrificed by jugular venesection at the completion of the ex- periments. Blood samples were collected in clean plastic centrifuge tubes containing heparin as anticoagulant for haematological assay and erythrocyte osmotic fragility test.
Determination of blood cellular components
Determination of packed cell volume (PCV) was done as described by Weiss and Wardrop (2010), with increased centrifuga- tion time as a slight modification. Erythro- cytes and leucocytes counts were done using a haemocytometer. Haemoglobin meter (XF- 1C-China) was used to determine haemoglo- bin concentration (Hb), and the mean cor- puscular volume (MCV), mean corpuscular haemoglobin (MCH) and mean corpuscu- lar haemoglobin concentrations (MCHC) were then calculated.
Determination of Erythrocyte Osmotic Fragility
Erythrocyte osmotic fragility was deter- mined according to the method as described by Buhari et al. (2014). Exactly 5 ml of varying concentrations of sodium chloride (NaCl) solutions with phosphate buffer (3.22 g/L) at a pH of 7.4 (0.0, 0.1, 0.3, 0.5, 0.7,
and 0.9%) were prepared in sets of 6 centri- fuge tubes each. Blood (20 µL) was added to each concentration of the test solution in each tube. The contents were mixed and in- cubated at room temperature for 30 min and then centrifuged at 3000 × g for 10 min. The concentration of haemoglobin in the super- natant solution of each tube was measured at 540 nm using a spectrophotometer (Spec- tronic-20, Philip Harris Limited, Shenstone,
England) by reading the absorbance. By assuming that the haemolysis of haemoglo- bin in 0.0% NaCl solution was 100%, per- centage haemolyses of the various treatment groups were then calculated, as described by Deriyeli et al. (2004).
Data were expressed as mean ± standard error of mean (SEM) and then analysed by one-way analysis of variance (ANOVA) fol- lowed by Tukey’s post-hoc test. The analy- ses were done using Graphpad Prism version
5. Values of P < 0 .05 were considered sig- nificant.
Phytochemical Screening of the Extract The result of phytochemical screening is presented in Table 1. Phytochemical screen- ing of EGb 761® revealed the presence of carbohydrates, glycosides, saponins, triter- penes, tannins, flavonoids, and alkaloids. However, the result shows that the extract did not contain anthraquinones and steroids. Effect of Gingko biloba Leaf Extract on
The results of haematological parameters are presented in Tables 2 and 3. Packed cell volume and haemoglobin were significantly (P˂0.05) higher in Group D when compared to Groups A, B, and C. Similarly, total red blood cell count was significantly (P˂0.05) higher in Group D when compared to Groups A, B, C, and F. Total protein was significant- ly (P˂0.05) higher in Group D and E, com- pared to Group A. There was no significant (P˂0.05) effect of EGb 761® administration on total and differential leucocyte counts.
Table 1. Phytochemical Screening of Ginkgo biloba Leaf Extract (EGb 761)
RED BLOOD INDICES
Tukey's test: Means having different superscript (a,b) letters are significantly (P˂0.05) different
PCV= Packed cell volume, HGB=haemoglobin, TP=total protein, TRBC=total red blood cell count, MCV= mean corpuscular volume, MCH= mean corpuscular haemoglobin, MCHC= mean corpuscular haemoglobin concentration
Table 3. Effect of Ginkgo biloba Leaf Extract on White Blood Cells and Differential Count Parameters (Mean ± Standard Error of Mean)
Means within the same column are not statistically different at 95% CL (α=0.05)
TWBC= Total white blood cell count, Lymp= lymphocytes, Neutro= Neutrophils, Eosino=Eosinophils, Mono= Mono- cytes, Band=Band cells.
Effect of Gingko biloba Leaf Extract Erythrocyte Osmotic Fragility
The result of the effect of EGb 761 on erythrocyte osmotic fragility in chlorpyrifos induced oxidative stress in rats is presented in Table 4. This result indicated that the dif- ferences in percentage haemolysis were not statistically significant (P>0.05) between all compared groups. All groups have the same minimum erythrocyte osmotic fragil- ity level at 0.9% NaCl concentration which is isotonic, with Group F having the low- est percentage haemolysis vis-à-vis other groups. Group G has the highest erythro- cyte osmotic fragility level at 0.1% NaCl concentration while the other groups have the highest erythrocyte osmotic fragility
level at 0.0% NaCl concentration, both of which are hypotonic.
Table 5 shows the results of the effect of Ginkgo biloba leaf extract on erythrocyte osmotic fragility. Results of this study in- dicated that Groups A and B have lowest percentage haemolysis at 0.9% NaCl con- centration which was isotonic and served as reference in this study, with Group A having the overall lowest value compared to oth- er groups. Also, Group A has significantly (P˂0.05) lower percentage of haemolysis in hypotonic medium at 0.5, 0.3, and 0.1% NaCl concentration respectively, when compared to Group C. Group B has sig- nificantly (P˂0.05) lower percentage hae- molysis at 0.5% NaCl concentration when
compared to Group C. Group A has signifi-
cantly (P˂0.05) lower percentage haemoly-
sis at 0.7, 0.3, and 0.1% NaCl concentration respectively when compared to Group B.
Table 4. Effect of Ginkgo biloba Leaf Extract on Erythrocyte Osmotic Fragility of Chlorpyrifos-Ex- posed Albino Rats, Measured as Percent Haemolysis (Mean ± Standard Error of Mean)
Means within the same column are not statistically different at 95% CL (α=0.05)
Table 5. Effect of Ginkgo biloba Leaf Extract on Erythrocyte Osmotic Fragility of Non- Chlorpyri- fos-Exposed Albino Rats, Measured as Percentage Haemolysis (Mean ± Standard Error of Mean).
Tukey's test: Means having different superscript (a,b) letters are significantly different (P˂0.05)
Phytochemical Screening of the Extract Phytochemical screening of Ginkgo bi- loba leaf extract in this study showed the presence of carbohydrates, glycosides, sa- ponins, triterpenes, tannins, flavonoids, and alkaloids. This is also consistent with the findings of other investigators (Ibrahim and Nuhu, 2016; Goh and Barlow 2002; DeFeu- dis and Drieu 2000). The medicinal values of Ginkgo biloba lie in the presence of these ac- tive compounds which have been reported to have protective effect against ailments such as cardiovascular diseases, diabetes, and ox- idative stress (Abdulrazak et al., 2018; Chan
et al., 2007; Saw et al., 2006).
Effect of Gingko biloba Leaf Extract on Haematological Parameters
In this study, Ginkgo biloba leaf extract significantly (P˂0.05) increased total red blood cell counts (8.35±0.29 ×1012/L), haemoglobin concentration (16.23±0.63 g/ dL) and packed cell volume (49.25±1.70 %) when compared with group pre-treated with Vitamin E (39.50±2.59 %, 13.13±0.86 g/dL,
6.65±0.37 ×1012/L respectively) and control (39.60±0.92 %, 13.16±0.31 g/dL, 6.62±0.15
×1012/L respectively). This, therefore, sug- gests that EGb 761® has more prophylactic protective effect on erythrocyte parameters in rats exposed to oxidative stress than vi- tamin E. Also, post treatment with EGb 761® significantly increased total protein (10.20±0.36 g/dL) when compared to con- trol (7.65±0.89 g/dL). These findings sug- gest that EGb 761® has more prophylactic than therapeutic protective effect on erythro- cyte parameters in rats exposed to oxidative stress. This effect may be due to accelerated erythropoiesis. However, further investiga- tion is required to confirm this. These find- ings are in accordance with those reported
by Khafaga and Bayad, (2016), He et al., (2009), Abdel Baieth (2009) and He et al., (2008) that EGb 761® caused an increase in blood cellular components.
Effect of Gingko biloba Leaf Extract Erythrocyte Osmotic Fragility
The prophylactic and therapeutic antiox- idant activities of EGb 761 on erythrocyte osmotic fragility in chlorpyrifos-induced oxidative stress were not significant when compared to vitamin E and control. Also, the prophylactic antioxidant activity of EGb 761 was not statistically significant vis-a-vis the therapeutic antioxidant activity of the ex- tract. Therefore, this study suggests that the percentage of haemolysis was not statistical- ly significant between all the groups.
However, the osmotic fragility of non-chlorpyrifos-exposed rats showed that rats treated with Ginkgo biloba leaf extract markedly afforded red blood cells an increased erythrocyte osmotic resistance against hypo- tonic stress (i.e. 0.7 % NaCl concentration has 3.30±0.79 % haemolysis, 0.5% NaCl concentration has 47.58±4.85% haemolysis, 0.3% NaCl concentration has 62.68±2.69 % haemolysis and 0.1% NaCl concentration has 58.84±10.22 % haemolysis ) when compared to the control group (4.91±0.50 %, 78.07±5.55
%, 92.80±7.20 %, 95.03±4.63 % haemolysis
at 0.7, 0.5, 0.3, and 0.1 % NaCl respectively) (Table 5). In the same vein, the extract also markedly increased red blood cell resistance to hypotonic stress (i.e. at 0.7 % NaCl con- centration was 3.30±0.79 % haemolysis, 0.3
% NaCl concentration was 62.68±2.69 % haemolysis and at 0.1 % NaCl concentration was 58.84±10.22 % haemolysis respectively) when compared to vitamin E (11.18±0.94, 87.54±5.33 and 97.57±2.34 % haemolysis
at 0.7, 0.3, and 0.1 % NaCl concentration re- spectively). Furthermore, vitamin E increased
red cell resistance in hypotonic medium (at
0.5 % NaCl concentration was 57.19±2.42
% haemolysis) when compared to the control group (78.07±5.55 % haemolysis).
These results revealed beneficial effect of EGb 761 on erythrocyte parameters; the results demonstrate that Ginkgo biloba leaf extract has a more protective action on red blood cells against hypotonic stress than vi- tamin E. Quercetin, a flavonoid and a major constituent of Ginkgo biloba leaf extract, and triterpenes have been reported to be respon- sible for this protective effect (Chan et al., 2007; He et al., 2008). However, this study disagrees with Abdel Baieth (2009), who re- ported that Ginkgo biloba leaf extract caused an increase in red cell osmotic fragility in hy- potonic medium; the electromagnetic field exposure in that study as well as high dos- age of EGb 761 used is likely responsible for the contrasting results. These findings are in agreement with Khafaga and Bayad (2016), Zhou et al. (2015), Furman et al. (2012) and He et al. (2008), who reported that Ginkgo biloba leaf extract has both a protective and disruptive action on red blood cells depend- ing on whether an exogenous stress is pres- ent or not.
This study shows that EGb 761® has more prophylactic than therapeutic amelio- rative effects on blood cellular components exposed to chlorpyrifos-induced oxidative stress, but the extract did not show any pro- phylactic or therapeutic effect on erythrocyte osmotic fragility in erythrocytes exposed to chlorpyrifos-induced oxidative stress when compared to vitamin E and control. How- ever, EGb 761 has afforded red blood cells an increased osmotic resistance against hy- potonic solution only. This result was better than that obtained for vitamin E, a reference antioxidant, at the same dosage. These find-
ings further justify the use of Ginkgo biloba leaf extract in both medical and ethnomed- ical practices as herbal remedy and dietary supplement.
We appreciate Abdulwahab Hashimu Yau and Yusuf Abdulraheem Oniwapele of the Department of Veterinary Pharmacology and Toxicology, Ahmadu Bello University, Zaria for their technical support.
Conflict of Interest
The authors declare that there is no con- flict of interest.
Abdel Baieth, H.E. (2009) Evaluation of Ginkgo biloba extract on hematological changes affect- ed with Hazards of Electromagnetic Field Ex- posure. Inte J Biomed Sci. 5: 229-236. PMID: 23675142
Abdulrazak, S., Nuhu, A.A., Yashim, Z.I. (2018) Prophylactic administration of Ginkgo biloba leaf extract (EGb 761) inhibits inflammation in carrageenan rat paw edema model. J Life Sci. Biomed. 8: 31-36.
Akhtar, N., Srivastava, M.K., Raizada, R.B. (2009) Assessment of chlorpyrifos toxicity on certain organs in rats, Rattus norvegicus. J Env Biol. 30: 1047-1053. PMID:20329403
Ambali, S.F., Ayo, J.O., Ojo, S.A., Esievo, K.A.N. (2012). Chronic chlorpyrifos-induced senso- rimotor and cognitive deficits in wistar rats- reparation by vitamin C. Journal of Research in Environmental Science and Toxicology. 1: 221-232.
Biddlestone, L., Corbett, A.D. Dolan, S. (2007) Oral administration of Ginkgo biloba extract, EGb-761 inhibits thermal hyperalgesia in ro- dent models of inflammatory and post-surgical pain. Br J Pharmacol. 151: 285–291. https://doi. org: 10.1038/sj.bjp.0707220. PMID: 17375081
Buhari, H., Kawu, M.U., Makun, H.J., Aluwong,
T., Yaqub, L.S., Ahmad, M.S., Tauheed, M.,
Buhari, H.U. (2014). Influence of sex, repro- ductive status and foetal number on erythrocyte osmotic fragility, haematological and physi- ologic parameters in goats during the hot-dry season. Veterinarni Medicina. 59: 479–490.
Chan, P.C., Xia, Q., Fu, P.P. (2007) Ginkgo biloba leave extract: biological, medicinal, and toxi- cological effects. J Environ Sci Health C En- viron Carcinog Ecotoxicol Rev. 25: 211–44. http:// doi.org/10.1080/10590500701569414. PMID:17763047
Dariyerli, N.S., Toplan, M.C., Akyolcu, H., Ha- temi, G. (2004) erythrocyte osmotic fragility and oxidative stress in experimental hypo- thyroidism. endocrine. 25: 1-5. http:// doi. org/10.1385/ENDO:25:1:01. PMID:15545699
DeFeudis, F.V., Drieu, K. (2000) Ginkgo biloba ex- tract (EGb 761) and CNS functions: basic studies andclinicalapplications.CurrDrugTargets.1:25–
58. http:// doi.org/10.2174/1389450003349380. PMID:11475535
Furman, A.E.F., Henneberg, R., Hermann, B.P., Leonart, M.S.S., Nascimento, A.J. (2012) Ginkgo biloba leaf extract (EGb 761) attenu- ates oxidative stress induction in erythrocytes of sickle cell disease patients. Braz J Pharm- Sci. 48: 4. http:// doi.org/10.1590/S1984-
Goh, L.M., Barlow, P.J. (2002) Antioxidant capaci- ty in Ginkgo biloba. Food Res Int. 35: 815–820. https://doi.org/10.1016/S0963-9969(02)00084-4
He, J., Lin, J., Li, J., Zhang, J.H., Sun, X.M.,
Zeng, C.M. (2008) Dual effects of Ginkgo biloba leaf extract on human red blood cells. Nordic Pharmacol Soc. 104: 138-144. http:// doi.org/10.1111/j.1742-7843.2008.00354.x. PMID:19143753
He, L., Vasiliou, K., Nebert, D.W. (2009) Analysis and update of the human solute carrier (SLC) gene superfamily. Hum Genomics. 3: 195-206. PMID:19164095
Ibrahim, M.P., Nuhu, A.A. (2016) phytochemical screening and antibacterial/antifungal activi- ties of Ginkgo biloba extract EGb 761. IOSR J Pharm Biol Sci. 11: 43-49. http:// doi.org/: 10.9790/3008-11124349
Khafaga, A.F., Bayad, A.E. (2016) Ginkgo bilo-
ba extract attenuates hematological disorders, oxidative stress and nephrotoxicity induced by single or repeated injection cycles of cisplatin in rats: physiological and pathological stud- ies. Asian J Anim Sci. 10: 235-246. https://doi. org/10.3923/ajas.2016.235.246
Mahadevan, S., Park Y. (2007) Multifaceted thera- peutic benefits of Ginkgo biloba L.: chemistry, efficacy, safety, and uses. J Food Sci. https:// doi.org/10.1111/j.1750-3841.2007.00597.x
Nuhu, A.A. (2014) Ginkgo biloba: A ‘living fossil’ with modern day phytomedicinal applications. J Appl Pharm Sci. 4 (3): 96-103. https://doi. org/10.7324/JAPS.2014.40319
Nuhu, A.A., Abdulrazak, S., Yashim, Z.I. (2017) Gingko biloba leaf extract mitigates chlorpyri- fos-induced oxidative stress in albino rat. Asian J Med Pharm Res. 7: 42-47.
Sarikcioglu, S., Oner, G., Tercan, E. (2004) Anti- oxidant effect of EGb 761 on hydrogen perox- ide-induced lipoperoxidation of G-6-PD defi- cient erythrocytes. Phytother Res. 18: 837-840. PMID:15551377
Saw, J.T., Bahari, M.B., Ang, H.H., Lim, Y.H.
(2006) Potential drug-herb interaction with antiplatelet/anticoagulant drugs. Com- plimen Therap Clin Pract. 12: 236-241. https://doi.org/10.1016/j.ctcp.2006.06.002. PMID:17030294
Silva, G.L., Lee, I., Kinghorn, A.D. (1998) Special Problems with the Extraction of Plants. In: Nat- ural Products Isolation, Cannel, RJP. (Eds). 1st Edition. (pp. 354-360). Humana Press Totowa, New Jersey,USA.
Smith, J.V., Luo, Y. (2004) Studies on molec- ular mechanisms of Ginkgo biloba extract. Appl Microbiol Biotechnol. 64: 465–72. https://doi.org/10.1007/s00253-003-1527-9 . PMID:14740187
Trease, G.E., Evans, W.C. (2002) Textbook of Pharmacognosy. (15th Ed), W.B. Saunders Company Ltd. London,UK.
Uchendu, C., Ambali, S.F., Ayo, J.O. (2012) The organophosphate, chlorpyrifos, oxidative stress and the role of antioxidants: a review. Afr J Ag- ric Res, 7: 2720-2728.
Van Beek, T.A. (2002) Chemical analysis of Gink-
go biloba leaves and extracts. J Chromatogr A. 967: 21–55.
Weiss, D.J., Wardrop, K.J. (2010) Schlam’s Veter- inary Haematology. 6th ed. Wiley Blackwell, Iowa, USA.
Xie, H., Wang, J.R., Yau, L.F., Liu, Y., Liu, L.,
Han, Q.B., Jiang, Z.H. (2014) Catechins and procyanidins of Ginkgo biloba show potent activities towards the inhibition of β-amyloid peptide aggregation and destabilization of preformed fibrils. Molecules. 19: 5119-5134. https://doi.org/10.3390/molecules19045119 . PMID:24759072
Yoshikawa, T., Naito, Y., Kondo, M. (1999) Gink- go biloba leaf extract: review of biological actions and clinical applications. Antioxid Re- dox Signal. 1: 469–80. https://doi.org/10.1089/ ars.1999.1.4-469 .PMID:11233145
Zhou, H., Wang, C., Ye, J., Chen, H., Tao, R. (2015)
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