Hematobiochemical changes of lead Poisoning and amelioration with Coconut ( Cocos nucifera L.) Water in wistar albino rats

To determine the ameliorative effect of coconut water on haematobiochemical changes due to lead poisoning in wistar albino rats for six weeks, sixty rats were assigned to four groups. 0.10g/l of lead and 75ml coconut ( cocus nucifera l.) water were given orally for six weeks. The mean values of red blood cells, mean corpuscular volume, mean corpuscular haemoglobin, mean corpuscular haemoglobin concentration, red blood cell distribution width and platelets (8.10±0.63(×106μl), 52.7±0.87(μm3), 17.9±0.56(pg), 34.73±0.65(g/dl), 17.90±0.67(%) and 670.00±42.22(×103μl) respectively) reduced in lead treated rats when compared with control mean values (8.41 ± 0.90(×106μl), 56.60 ± 1.55(μm3), 19.33 ± 0.82(pg), 34.93 ± 0.90(g/dl), 18.27 ± 0.73(%) and 818.33± 123.68(×103μl) respectively ) and these values increased in75ml coconut water only group and the group of 0.10g/l lead + 75ml coconut water except mean corpuscular haemoglobin, mean corpuscular haemoglobin concentration, and red blood cell distribution width of the 75ml coconut water only. The mean values of white blood cells, lymphocytes, total cholesterol, triglyceride, high density lipoprotein-cholesterol, low density lipoprotein-cholesterol, low density lipoprotein-cholesterol/high density lipoproteincholesterol and total cholesterol/high density lipoprotein-cholesterol increased (12.23±0.57(×103μl), 79.83±3.87(%), 64.66±6.01(mg/dl), 89.00±7.94(mg/dl), 22.67±6.93(mg/dl), 21.00±4.58(mg/dl), 1.29±0.62 and 3.36±0.83 respectively ) in the lead group when compared with mean values of control group (5.83±0.74(×103μl), 69.07±10.57(%), 54.00±4.04(mg/dl), 97.33±11.34(mg/dl), 20.00±3.06(mg/dl), 17.00±6.51(mg/dl), 0.97±0.41 and 2.87±0.55 respectively) but the mean values decreased when compared with the mean values of group of 75ml coconut water only and group of 0.10g/l lead + 75ml coconut water, except the mean values of high density lipoprotein-cholesterol. These results indicate that coconut water could ameliorate effects of lead toxicity

Evaluation of the protective effects of kolaviron on Kolanut-induced oxidative stress in developing rat brain

The brain is exposed throughout life to oxidative stress, and certain diseases of the brain and nervous system are thought to involve free radical processes and oxidative damage. This study is aimed at evaluating the effect of kolaviron on kolanut-induced oxidative stress in developing rat brain. Twenty-five adult pregnant Wistar rats weighing between 160 and 180g were used for the experiment. They were randomly divided into five groups of five animals each. The animals were fed with standard diets of mice cubes and water provided ad libitum. The control rats received water and cornoil, while the experimental animals received 200 mg/kg body weight of kolanut (kn), 200 mg/kg of kolaviron (kv), and 200 mg/kg body weight of vitamin E which served as a standard antioxidant with cornoil as vehicle orally in pre- and post-natal life. After birth, gross morphometry and behavioural changes of the pups of days 1, 7, 14, 21 and 28 postpartum were evaluated. Blood samples were collected from pups of day 21 for hematological, liver and renal function analyses, while the brains of pups of day 21 postpartum were preserved in phosphate buffer at a temperature of 4oC and pH 7.4 for biochemical analysis. There were significant alterations in the gross morphometry and behavioural parameters studied in the treated animals compared with the control at p< 0.05. There were elevated levels of RBC, WBC and platelets in the treated group compared with the control at p< 0.05. However, no significant change was observed in the PCV, Hb, liver and renal function parameters studied at p>0.05. A non-significant increase in levels of malondialdehyde, MDA, a bye-product of lipid peroxidation in the kolanut group was observed. However, administration of kolaviron and vitamin E non-significantly (p>0.05) reversed these changes. In conclusion, maternal consumption of kolanut induced mild oxidative stress and the administration of kolaviron and vitamin E decreased the rate at which kolanut induced oxidative stress in developing rat brain.

A pilot study to determine the normal haematological indices for young Malawian adults in Blantyre, Malawi

Aim To determine the distribution of haematological parameters in healthy individuals residing in Blantyre, Malawi. We also examined the effect of sociodemographic and nutritional factors on the haematological variables. Methods We conducted a proof-of-concept cross-sectional study, involving 105 healthy blood donors at Malawi Blood Transfusion Service in Blantyre. Eligible participants were HIV-negative males and females, aged 19 to 35 years, who did not have any evidence of acute or chronic illness, or bloodborne infection. We performed the haematological tests at the Malawi-Liverpool Wellcome Trust laboratory in Blantyre, and the screening tests at Malawi Blood Transfusion Service laboratories. Results Out of 170 consenting healthy volunteers, haematological results were available for 105 participants. The proportions of results which were below the lower limit of the manufacturer’s reference ranges were 35.2% (37/105) for haemoglobin, 15.2% (16/105) for neutrophils, 23.8% (25/105) for eosinophils, and 88.6 % (93/105) for basophils. The proportions of results that were above the upper limit of the manufacturer’s reference ranges were 9.5% (10/105) for platelets and 12.4% (13/105) for monocytes. We also observed that the mean leucocyte and basophil counts were significantly higher in males than females (p = 0.042 and p = 0.015, respectively). There were no statistically significant differences in haematological results observed among different ethnic, age, and body mass index groups. Conclusions Over half of otherwise healthy study participants had at least one abnormal haematological result, using previously established foreign standards. More detailed studies are needed to establish locally relevant normal ranges for different age groups and other demographic characteristics of the Malawian population. This will lead to accurate interpretation of laboratory results.