1.
Assessing The Efficacy Of Aqueous Garlic Extract Against Cyanide Toxicity In Mice Using Righting Reflex Recovery
by Sajid Ali | Dr. Muhammad Avais | Dr. Aneela Zameer Durrani | Prof. Dr.
Material type: ; Format:
print
; Literary form:
not fiction
Publisher: 2013Dissertation note: The KCN intake has been linked to central nervous system (CNS) syndromes and thyroid in animals as well as humans. It is very potent toxin even at very narrow dose ranges. Prolonged KCN exposure has also been associated with reduced growth rate in animals, disturbance in thyroid metabolism, lesions in liver, kidneys, lungs and also CNS pathology.
Male mice weighting about 20-40 grams were purchased from Veterinary Research Institute, Lahore, National Institute of Health, Islamabad, Animal house, University of Veterinary and Animal Sciences, Lahore and divided into 30 treatment groups. After acclimatization of mice, carefully, the mice were grouped as follows:
Control group
A group of 6 mice were treated with potassium cyanide (KCN) intra-peritoneally at 5.5mg/kg that induced a knock down state with recovery period of approximately 1 hour. Prior to each experiment, three or more mice were treated with KCN at this dose to verify that the recovery time was close to 1 hour.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 250 mg/kg: Group 1 (5-min pre-KCN)
A group of 6 mice was given AGE intraperitoneally (i.p) at 250 mg/kg. After 5 minutes of AGE injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 250 mg/kg: Group 2 (5-min post-KCN)
A group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse was treated with AGE at 250 mg/kg i.p. and righting reflex recovery time was noted.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 500 mg/kg: Group 3 (5-min pre-KCN)
A group of 6 mice was given AGE intraperitoneally (i.p) at 500 mg/kg BW. After 5 minutes of AGE injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 500 mg/kg: Group 4 (5-min post-KCN)
A group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse was treated with AGE at 500 mg/kg i.p. and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 750 mg/kg: Group 5 (5-min pre-KCN)
A group of 6 mice was treated with AGE intraperitoneally (i.p) at 750 mg/kg. After 5 minutes of AGE injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 750 mg/kg: Group 6 (5-min post-KCN)
A group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse was treated with AGE at 750 mg/kg i.p. and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 250 mg/kg: Group 7 (30-min post-KCN)
One more group of 6 mice was given AGE at 250 mg/kg orally. After 30 minutes of AGE administration, an intraperitoneal (i.p) injection of KCN at 5.5 mg/kg was given and righting refelx recovery time was noted.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 500 mg/kg: Group 8 (30-min post-KCN)
A group 6 mice was given AGE at 500 mg/kg orally. After 30 minutes of AGE administration, an intraperitoneal (i.p) injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was noted.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) at 750 mg/kg: Group 9 (30-min post-KCN)
One more group of 6 mice was given AGE at 750 mg/kg orally. After 30 minutes of AGE administration, an intraperitoneal (i.p) injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Garlic Extract Group: (Group 10-15)
Three groups 10 - 12 each with 6 mice were injected intraperitoneally (i.p) with AGE at 250, 500 and 750 mg/kg respectively and righting reflex recovery time of each mouse in respective dose group was noted to observe any effects of AGE on righting reflex recovery time. Three groups 13 - 15 each with 6 mice were treated with AGE orally at 250, 500 and 750 mg/kg respectively and righting reflex recovery time of each mouse in respective dose group was noted to observe any effects of AGE on righting reflex recovery time.
Potassium Cyanide (KCN) + Sodium Nitrite (SN): Group 16 (5-min pre-KCN)
A group of 6 mice was given SN at 20 mg/kg intraperitoneally (i.p). After 5 minutes of SN injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Sodium Nitrite (SN): Group 17 (5-min post-KCN)
Another group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse was treated with SN at 20 mg/kg i.p. and righting reflex recovery time was noted.
Potassium Cyanide (KCN) + Sodium Thiosulphate (ST): Group 18 (5-min pre-KCN)
A group of 6 mice was given ST at 600 mg/kg intraperitoneally (i.p). After 5 minutes of ST injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Sodium Thiosulphate (ST): Group 19 (5-min post-KCN)
A group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse was treated with ST at 600 mg/kg i.p. and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Sodium Nitrite (SN) & Sodium Thiosulphate (ST): Group 20 (5-min pre-KCN)
A group of 6 mice was given SN and ST at 20 mg/kg and 600 mg/kg intraperitoneally (i.p) respectively. After 5 minutes SN and ST injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Sodium Nitrite (SN) & Sodium Thiosulphate (ST): Group 21 (5-min post-KCN)
A group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse was treated with SN and ST at 20 mg/kg and 600 mg/kg i.p. respectively and righting reflex recovery time was noted.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) & Sodium Nitrite (SN): Group 22 (5-min pre-KCN)
A group of 6 mice was given AGE at 750 mg/kg and SN at 20mg/kg intraperitoneally (i.p). After 5 minutes of AGE and ST injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was noted.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) & Sodium Nitrite (SN): Group 23 (5-min post-KCN)
A group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse was treated with AGE at 750 mg/kg and SN at 20 mg/kg i.p. and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) & Sodium Thiosulphate (ST): Group 24 (5-min pre-KCN)
A group of 6 mice was given AGE at 750 mg/kg and ST at 600mg/kg intraperitoneally (i.p). After 5 minutes of AGE and ST injection, an i.p. injection of KCN at 5.5 mg/kg was given and righting reflex recovery time was recorded.
Potassium Cyanide (KCN) + Aqueous Garlic Extract (AGE) & Sodium Thiosulphate (ST): Group 25 (5-min post-KCN)
A group of 6 mice was administered with KCN intraperitoneally (i.p) at 5.5 mg/kg. After 5 minutes of KCN injection, each mouse will be treated with AGE at 750 mg/kg and ST at 600 mg/kg i.p. and righting reflex recovery time was noted.
Sodium Nitrite (SN) alone (Group 26)
6 mice in this group were treated with SN at 20 mg/kg intraperitoneally (i.p) and any effects on righting reflex recovery time were noted.
Sodium Thiosulphate (ST) alone (Group 27)
A group of 6 mice in group 27 were treated with ST at 600 mg/kg intraperitoneally (i.p) and any effects on righting reflex recovery time were noted.
Aqueous Garlic Extract (AGE) + Sodium Nitrite (SN) (Group 28)
The mice in group 28 were treated with AGE + SN at 750 mg/kg and 20 mg/kg intraperitoneally (i.p) respectively and righting reflex recovery time was noted.
Aqueous Garlic Extract (AGE) + Sodium Thiosulphate (ST) (Group 29)
A group of 6 mice in this group were treated with AGE at 750 mg/kg and ST at 600 mg/kg intraperitoneally (i.p) and righting reflex recovery time was recorded.
Sodium Nitrite (SN) + Sodium Thiosulphate (ST) (Group 30)
A group of 6 mice in group 30 were treated with SN and ST at 20 mg/kg and 600 mg/kg intraperitoneally (i.p) respectively and righting reflex recovery time was recorded.
The efficacy of the antidote estimated was based upon the reduction in righting reflex recovery time.
The righting reflex recovery time that was close to 1 hour was determined against KCN regimen. AGE was tested as potential antidote against sub-lethal KCN toxicity at dose regimens 250, 500 and 750 mg/kg intraperitoneally as well as orally at dose regimens 250, 500 and 750 mg/kg 5 minutes before and 5 minutes after KCN administration. SN and ST were tested at 20, and 600 mg/kg respectively as antidotes against sub-lethal KCN toxicity, 5 minutes before and 5 minutes after KCN administration. These were also tested in comparison and a dose with minimum recovery time was noted. A comparison was made between the efficacy of AGE and SN or ST or SN + ST as potential antidote against sub-lethal KCN toxicity. After 48 hours 3 mice from each group was sacrificed for postmortem examination.
For this purpose the righting reflex recovery time and survival data was collected for each mouse challenged with KCN. A group of 3 mice was tested with each increasing dose of KCN to create dose response curves for both righting reflex recovery times and percent survival. Increasing doses of KCN increased the recovery time of the righting reflex. The dose 5.5 mg/kg of KCN showed the righting reflex recocery time mean 64.66 ± .333 min and was selected for trials.
AGE (750 mg/kg) showed the most significant results as compared to ST and SN alone as well as in combination. Second most effective drug was ST as it showed better results than SN. Treatment results were more pronounced in 5 min pre-KCN groups as compared to 5 min post-KCN groups.
From this study it was concluded that the aqueous AGE is an effective antidote against sub-lethal KCN toxicity as the recovery times indicated that its effects are more pronounced than SN and ST, secondly, as it is easily available and very much cheaper in Pakistan and due to easy unavailability of SN and ST, it is effective antidote that could be used in the field against sub-lethal KCN toxicity with comparatively better results both orally and intraperitoneally.
Availability: Items available for loan: UVAS Library [Call number: 1776,T] (1).
2.
Isolation and Identification of Parasites From Available Raw Vegetables
by Sawera Chaudhry (2008-VA-189) | Prof. Dr. Azhar Maqbool | Dr.Sarwat Naz | Dr. Muhammad Latif | Dr. Muhammad Avais.
Material type: ; Literary form:
not fiction
Publisher: 2015Dissertation note: Blank CD. Availability: Items available for loan: UVAS Library [Call number: 2232-T] (1).
3.
Status Of Brucellosis And Its Effect On Hemogram And Serum Biochemistry In Indigenous, Cross-Bred And Exotic Dairy Cattle Herds
by Muhammad Hareem Afzal (2008-VA-250) | Dr. Muhammad Avais | Dr. Jawaria Ali Khan | Prof. Dr. Aftab Ahmad Anjum.
Material type: ; Literary form:
not fiction
Publisher: 2015Dissertation note: Brucellosis mainly infects food animals such as cattle, buffalo, goats and sheep. Brucella abortus is the principal cause of brucellosis in cattle and is shed from the infected animal at or around the time of calving or abortion. The present study was conducted on 450 animals on three different strains/breeds of cattle i.e. Exotic (150), Cross-bred (150) and local cattle (150) from 10 different privately owned livestock farms of varying holdings of district Lahore. An epidemiological questionnaire focusing on herd traits as well as husbandry and sanitary practices that could be associated with the risk of Brucellosis infection was completed. Serum samples were collected and analyzed using Rose Bengal Plate Test (RBPT). The serum samples positive for Brucellosis through RBPT further subjected to Serum Agglutination Test (SAT). To check the effect of Brucellosis on hemogram, blood samples from 18 cattle (n=6 indigenous; n=6 cross-bred; n=6 exotic) positive for Brucellosis and 18 animals (n=6 indigenous; n=6 cross-bred; n=6 exotic) negative for brucellosis were collected and processed for TLC, DLC, RBC, Hb, MCV, MCHC MCH and platelets using automated haematology analysed at UDL, UVAS, Lahore. Similarly, to see the effect of Brucellosis on Serum biochemistry, serum samples from 18 cattle (n=6 indigenous; n=6 cross-bred; n=6 exotic) positive for Brucellosis and 18 animals (n=6 indigenous; n=6 cross-bred; n=6 exotic) negative for brucellosis collected and analysed for glucose, total protein, albumin, Creatinine, Alanine Aminotransferase (ALT), Aspartate Aminotranferase (AST) and Sorbitol Dehydrogenase (SD) using commercially available kits.
Summary
62
RBPT revealed overall prevalence 17.7% higher than SAT 10.6%. Prevalence of brucellosis is higher in Cross-Bred (22.7%) followed by local cattle (18.9%) and exotic (12%).
Hemato-boichemical results showed that increase in TLC, MCV While slight changes in Hb, MCHC, RBC and values of MCV stays within normal range. On the other hand serum biochemistry increase in AST while decrease in ALT and SD found. Availability: Items available for loan: UVAS Library [Call number: 2348-T] (1).
4.
Anthelmintic Activity Of Ginger Against Gastrointestinal Nematodes In Goats
by Muhammad Shahid (2008-VA-127) | Dr. Haroon Akbar | Prof. Dr. Kamran Ashraf | Dr. Muhammad Avais.
Material type: ; Literary form:
not fiction
Publisher: 2016Dissertation note: Gastrointestinal tract nematodes are responsible for wide range of health problems,
economic losses in goats and are characterized by impaired milk production, meat process,
decreased fertility, low kidding rates, decreased working efficiency and even death of the goats.
Gastrointestinal tract nematodes cause economic losses via morbidity and negative effects on
feed intake, nutrient utilization efficacy and also reduce young animal’s growth rate as a result,
leading to decreased productivity and performance of the infected animal. Due to such economic
losses, the control of the helminths is unavoidable which is also possible by herbal products such
as Ginger. Ginger has pharmacological and gastrointestinal prokinetic activities to cure
constipation, indigestion, vomiting, infectious diseases and helminthiasis. In the current study,
anthelmintic activity of Ginger has been tested against gastrointestinal nematodes of goats.
For therapeutic trials, a total of 75 goats positive for nematodes having EPG >150 were
selected randomly and divided into three groups named as Group A, B and C, each group
comprising of 25 animals. The goats of Group A were orally treated with crude powder of ginger
(Zingiber officinale) @ 3 gram/kg body weight, orally. Goats in group B served as positive
control (infected and treated with Oxfendazole). Group C comprised of positive animals which
were not treated during whole the experiment. The fecal samples were collected at day 14 (Posttreatment).
Drug’s efficacy was assessed on the Fecal Egg Count Reduction Test (FECRT) and
was calculated by following formula (Traversa et al. 2007).
[((Pre-treatment EPG – Post-treatment EPG)) / Pre-treatment EPG] × 100
SUMMARY
34
Data regarding therapeutic trails were analyzed by repeated measures one-way ANOVA, using
SPSS version 20.0, p< 0.05 was considered as significant. Trial was analyzed under different
parameters.
Ginger has shown good anthelmintic activity against gastrointestinal nematodes in goats
as evident from 63% reduction in EPG. It is suggested hereby to conduct a dose trial for the use
of ginger against nematodes in goats by using different dose levels including at least 5 different
groups of dosages like 3gram; 3.5grams; 4grams; 4.5grams and 5grams per Kg body weight. The
current study has highlighted the anthelmintic activity of ginger (Zingiber officinale) against
gastrointestinal nematodes in goats. More trials using this herbal product in other animals will
further highlight the importance of using this commonly-available and economical herbal
product in the control of gastrointestinal nematodes in livestock. Availability: Items available for loan: UVAS Library [Call number: 2712-T] (1).
5.
A Study Of Risk Factors And Chemotherapy Of Patent Stongyloides Westeri Infection In Foals In Lahore
by Saima Batool (2015-VA-837) | Dr. Jawaria Ali khan | Dr. Muhammad Avais | Dr. Arfan Ahmed.
Material type: ; Literary form:
not fiction
Publisher: 2017Dissertation note: Data is available on prevalenc of strongyloideswesteri in foals which cause diarrhea and its allopathic treatment is also available but there is no data available on herbal treatment of s. westeri and best protocol of allopathic drugs. So the purpose of the study is to study the incidence of S. westeri in foals. The risk factors associated with S. westeri and to develop the best treatment protocol for S. Westeri. The hypothesis of this study is; Identification of risk factors that was associated with S. westeri and efficacy of Allopathic verse herbal drugs was determined against S. westeri. Fecal samples were collected from foals. Gloves were lubricated with lubricating material before the sampling. Sample will be collected directly from rectum of the foals. The fecal material was collected in the properly labeled plastic jar. The samples were processed and examined in the Medicine Laboratory, University of Veterinary and Animal Sciences Lahore. Direct smear examination was carried out for the of S. westerieggs under microscope. For quantitative analysis, Mac Master Technique was used. The positive foals were divided into three groups A, B and C to check the efficacy of drugs on S. westeri. These groups were going through to chemotherapeutic trials with different groups of medicines including herbal and allopathic. Herbal medicine was Ginger (zingiberofficinale) and allopathic were oxibendazoleand ivermectin. Milk samples were also collected from newly parturated mares then evaluation and biometery of larvae was also done just to study the risk factors that transfer larvae from dam to foal through colostrum. Comparison and Identification of eggs and larvae in milk along with treatment effect were analyzed by Chi Square method using the SPSS software 22 version. The data obtained from this study revealed that:
The main source of S. westeri infection was milk of dams. The larva of S. westeri passed through the dam’s milk to foals.
The prevalence of S. westeri was strongly associated with the risk factor such age, colostrum intake, species, breed, dite, environment, water supply and deworming treatments.
Vaccination had no effect on prevalence of S. westeri.
Allopathic drugs are more efficient against S. westeri infection in foals as compared the herbal drugs.
The efficacy of Ivermectin was more as compared to Oxibendazole.
Availability: Items available for loan: UVAS Library [Call number: 2817-T] (1).
6.
A Study Of Risk Factors And Chemotherapy Of Patent Stongyloides Westeri Infection In Foals In Lahore
by Saima Batool (2015-VA-837) | Dr. Jawaria Ali khan | Dr. Muhammad Avais | Dr. Arfan Ahmed.
Material type: Publisher: 2017Dissertation note: Data is available on prevalenc of strongyloideswesteri in foals which cause diarrhea and its allopathic treatment is also available but there is no data available on herbal treatment of s. westeri and best protocol of allopathic drugs. So the purpose of the study is to study the incidence of S. westeri in foals. The risk factors associated with S. westeri and to develop the best treatment protocol for S. Westeri. The hypothesis of this study is; Identification of risk factors that was associated with S. westeri and efficacy of Allopathic verse herbal drugs was determined against S. westeri. Fecal samples were collected from foals. Gloves were lubricated with lubricating material before the sampling. Sample will be collected directly from rectum of the foals. The fecal material was collected in the properly labeled plastic jar. The samples were processed and examined in the Medicine Laboratory, University of Veterinary and Animal Sciences Lahore. Direct smear examination was carried out for the of S. westerieggs under microscope. For quantitative analysis, Mac Master Technique was used. The positive foals were divided into three groups A, B and C to check the efficacy of drugs on S. westeri. These groups were going through to chemotherapeutic trials with different groups of medicines including herbal and allopathic. Herbal medicine was Ginger (zingiberofficinale) and allopathic were oxibendazoleand ivermectin. Milk samples were also collected from newly parturated mares then evaluation and biometery of larvae was also done just to study the risk factors that transfer larvae from dam to foal through colostrum. Comparison and Identification of eggs and larvae in milk along with treatment effect were analyzed by Chi Square method using the SPSS software 22 version. The data obtained from this study revealed that:
The main source of S. westeri infection was milk of dams. The larva of S. westeri passed through the dam’s milk to foals.
The prevalence of S. westeri was strongly associated with the risk factor such age, colostrum intake, species, breed, dite, environment, water supply and deworming treatments.
Vaccination had no effect on prevalence of S. westeri.
Allopathic drugs are more efficient against S. westeri infection in foals as compared the herbal drugs.
The efficacy of Ivermectin was more as compared to Oxibendazole
Availability: No items available
7.
Determination Of Multiple Anthelmintic Resistance Against Haemonchus Contortus In Sheep In Azad Jammu And Kashmir
by Shoaib Husnain (2015-VA-1337) | Dr. Muhammad Avais | Dr. Asim Shamim | Dr. Jawaria Ali Khan | Dr. Muhammad Oneeb.
Material type: Publisher: 2017Dissertation note: Parasitic problem is a key restriction of ruminant production which leads to reduce production and causes huge financial loss to small ruminant industry by inhibited growth, low production and amplified vulnerability of animals to other infections. The production losses are due to lowered feed intake and reduced efficiency. These economic losses may be due to chronic and subclinical infections in small ruminants. Sheep of different breeds of both sexes from different age groups were included in this study. Fresh fecal samples were collected randomly from sheep and were stored at4°C before microscopic examination. The Eggs per Gram (EPG) was calculated through modified McMaster technique (Coles, 1992). Samples were scanned for the presence of Haemonchus infection and the EPG was done before the administration of anthelmintic. Infected animals having EPG more than 500 were included in the groups for therapeutic trial. 10 animals were added in each group and each group was given different anthelmintics i.e. Albendazole, Oxfendazole, levamisole and ivermectin. A second sampling was done at 7th day post treatment and 3rd sampling was done at 14th day after drug administration to calculate post-treatment EPG to find out the FECR efficiency of the drugs used. The anthelmintics were administered to each group at recommended dose rate as mentioned in table 3.1.Pre-treatment EPG was related to the Post-treatment EPG and the % effectiveness of each anthelmintic was determined by using the efficacy formula. An in vitro egg hatch test was performed by using different preparation of anthelmintic prepared by serial dilutions. Eggs were incubated with these preparations and the percent hatching was determined and the data obtained was analyzed by probit analysis and the LC50 was calculated. The LC50 calculated for albendazole was 0.89ug/ml and that of oxfendazole was 1.09ug/ml which is much higher from the discriminating dose that is 0.1ug/ml which indicated the presence of resistance against these anthelmintics. Low dosing and aggressive use of anthelmintics may have cause the resistance against these anthelmintics. Other factors may include mixed farming and the movement of animals from one place to another which is responsible of dispersal of resistant strains. The present study suggests an alarming situation of anthelmintic resistance in Azad Jammu and Kashmir against common available anthelmintics that is albendazole and oxfendazole. A proper technical knowledge, awareness and alertness is necessary to overcome this problem in order to improve the small ruminants production especially sheep to up raise the livelihood of small livestock farmer. It is the demand of the day to introduce new control strategies by introducing modern anthelmintics and a proper worm control schedule according to the recommendations to avoid such problems in future. Availability: Items available for loan: UVAS Library [Call number: 2819-T] (1).
