Models for testing_activity_of_diuretics
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The document outlines various models and methodologies for testing the diuretic and saluretic activity of compounds in different animals, including rats and dogs. Methods discussed include the Lipschitz test, micropuncture techniques, and clearance methods, focusing on urine and electrolyte excretion analysis. Overall, the document emphasizes the importance of careful experimental design to determine the efficacy and mechanism of diuretics.
Models for testing_activity_of_diuretics
- 1. MODELS FOR TESTING ACTIVITY OF DIURETICS Presented by : MOHANLAL 15PHM2007 M. PHARM mohanlalchoudhary1992@gmail.com 1
- 2. INVIVO METHODS 2 1. Diuretic activity in rats (LIPSCHITZ test) 2. Saluretic activity in rats 3. Diuretic and saluretic activity in dogs 4. Clearance methods 5. Micropuncture techniques in the rats
- 3. DIURETIC ACTIVITY IN RATS (LIPSCHITZ TEST) Purpose and rationale The test is based on water and sodium excretion in test animals as compared to the rats treated with high dose of Urea (control). The “LIPSCHITZ value” = Excretion by test animals Excretion by urea control 3
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- 5. CONTI…. Methodology Speces - Male Wistar rats (100–200 gm) Sex - male rats Three animals in each group both in test and control Procedure 3 animals per group are placed in metabolic cages provided with a wire mesh bottom and funnel to collect the urine. SS sieves are placed in the funnel to retain feces but allow urine to pass. Rats are fed with std diet(Altromin pellets) and water. 17-24 hrs prior to the experinment food and water is withdrawn. For screening,2 groups of 3 animals are used for 1 dose of test compound. Test compound is applied orally at a dose of 50mg/kg in 5mlwater/kg body weight. 2 groups of 3 animals act as control and are treated with urea 5
- 6. PROCEDURE Test compound is applied orally at a dose of 50mg/kg in 5mlwater/kg body weight. 2 groups of 3 animals act as control and are treated with urea. Additionally,5ml of 0.9% Nacl solution/100g body weight are given by gavage. Urine excretion is recorded after 5 and 24 hrs. The Na content of urine is determined by Flame photometry. Active compounds are tested again with lower doses. 6
- 7. EVALUATION Urine volume excreted /100g of body weight is calculated for each group. Lipschitz value= Excretion by test animals is calculated Excretion by urea control Lipschitz value of more than 1 is taken as positive. With potent diuretics Lipschitz value of 2 or more can be found. Calculating this index for 5 and 24 hrs indicates duration of diuretic effect. Quotients can also be calculated for Na excretion. DRC can be established for various doses. Loop diuretics like furosemide are characterized by steep DRC and lipschitz value of 4.0. Saluretic drugs like Hydrochlorthiazide have Lipschitz value of 1.8. 7
- 8. MODIFICATIONS Screening diuretic agents in rats using normal saline as hydrating fluid. Homozygous Brattleboro rats exhibit symptoms of Diabetes insipidus due to failure of hypothalamic neurons to produce vassopressin,which is due to single point deletion in vassopressin gene. 8
- 9. SALURETIC ACTIVITY IN RATS Purpose and Rationale Excretion of electrolytes and water is important for treatment in peripheral oedema and CHF as well as in hypertension. However K loss has to be avoided and therefore saluretic and K sparing diuretics were developed. The diuresis test in Rats was modified in such a way that in addition to determining Na and water content,K and chloride content as well as osmolality can be determined. The ratios between the electrolytes can be calculated indicating CA inhibition or K sparing effect. 9
- 10. METHODOLOGY Speces- Wistar rats (100-200g) Sex - Male Theree animals in each group both in test and in control to test the test compound PROCEDURE Male Wistar rats fed with std diet (Altromin pellets) and water are used. 15 hrs prior to the test food but not water is withdrawn. Test compounds are applied 50mg/kg orally in 0.5ml/100g body weight starch suspension. 3 animals are placed in 1 metabolic cage with a wire mesh bottom and a funnel to collect the urine. 2 groups of 3 animals are used for each dose of the test compound. Urine excretion is registered every hr upto 5 hrs. 10
- 11. The 5 hr urine is analysed by flame photometry Na and K and Argentometrically by potentiometrical end pt. for chloride. To evaluate compounds with prolonged effect 24 hr urine is analysed. Furosemide(25mg/kg) or Hydrochlorthiazide(25mg/kg) is used as standard. Cont…. EVALUATION The sum of Na and Chloride excretion is a measure of saluretic activity. The ratio of Na/K is calculated for natriuretic activity.Values >2 indicate natriuretic effect.Ratios>10 indicate K sparing effect. The ratio of chloride/Na+K is known as ion quotient is calculated for CA inhibition. MODIFICATIONS Adrenolectomized Rats treated with Aldosterone can be used to study the Aldosterone antagonists. 11
- 12. DIURETIC AND SALURETIC ACTIVITY IN DOGS Renal physiology of the dog is claimed to be closer to man than that of rats. Oral absorbability of diuretic substances can appropriately be studied in dogs. Using catheters, interval collections of urine can be made with more reliability than in rats. Simultaneously, blood samples can be withdrawn to study pharmacokinetics. PURPOSE AND RATIONALE Methodology Speces – Dogs Sex - male or female Four animals are used in each group for testing of comp. 12
- 13. PROCEDURE Beagle dogs of either sex have to undergo intensive training to be accustomed to accept gavage feeding and hourly catheterization without any resistance. The dogs are placed in metabolic cages. At least 4 dogs are used as controls receiving water only, as standard controls 1 g/kg urea p.o. or 5 mg/kg furosemide p.o. or the test drug group. Twenty-four hours prior to the experiment food but not water is withheld. On the morning of the experiment, the urinary bladder is emptied with a plastic catheter. The dogs receive 20 ml/kg body weight water by gavage, followed by hourly doses of 4 ml/kg body weight drinking water. The bladder is catheterized twice in an interval of 1 h and the urine collected for analysis of initial values. Then, the test compound or the standard is applied either orally or intravenously. Hourly catheterization is repeated over the next 6 h. 13
- 14. Without further water dosage the animals are placed in metabolic cages overnight. Twenty-four hours after dosage of the test compound, the dogs are catheterized once more and this urine together with the urine collected over night in the metabolic cage registered. All urine samples are analyzed by flame photometry for sodium and potassium and by argentometry for chloride content. Furthermore, osmolality is measured with an Osmometer. EVALUATION Urine volume, electrolyte concentrations and osmolality are averaged for each group. The values are plotted against time to allow comparison with pretreatment values as well as with water controls and standards. The non-parametric U-test is used for statistical analysis. 14
- 15. CLEARANCE METHOD Purpose and Rationale A drug that acts solely in the PCT by causing the delivery of the increased amounts of filtrate to the loop of Henle and the distal convolution, would augment the clearance of solute-free water (CH2O) during water diuresis and the reabsorption of solute-free water (TCH2O) during water restriction. In contrast, drugs that inhibit sodium reabsorption in Henle’s loop would impair both CH2O and TCH2O. On the other hand, drugs that act only in the distal tubule would reduce CH2O but not TCH2O. PROCEDURE Clearance experiments are performed either in conscious or anaesthetized beagle dogs under conditions of water diuresis and hydropenia. Water diuresis is induced by oral administration of 50 ml of water per kg body weight and maintained by continuos infusion into jugular vein of 2.5% glucose solution and 0.58% NaCl solution at 0.5 ml/min per kg body weight. When water diuresis is well established, the glucose infusion is discontinued and control urine samples are collected by urethral catheter. 15
- 16. CONT…. Blood samples are obtained in the middle of each clearance period. After the control period,compounds to be tested are administered and further clearance tests are performed. Hydropenia is induced by withdrawing the drinking water 48 h before experiment. On the day before the experiment 0.5 U/kg body weight of vasopressin in oil is injected intramuscularly. On the day of the experiment 20 mU/kg vasopressin is injected i.v., followed by infusion of 50 mU/kg per hour vasopressin. To accomplish constant urine flow 5% NaCl solution is infused at 1 ml/min per kg body weight up to i.v. administration of a compound to be tested, followed by i.v. infusion of 0.9% NaCl solution at a rate equal to the urine flow. Glomerular filtration rate (GFR) and renal plasma flow (RPF) are measured by the clearance of inulin and para-aminohippurate, respectively. Therefore, appropriate infusion of inulin and para-aminohippurate are initiated. Inulin and para-aminohippurate are measured. 16
- 17. EVALUATION The following parameters may be determined: water and electrolyte excretion, GFR, RPF, CH2O, TCH2O and plasma renin activity. Results of test compound are compared statistically with control and standard drug treated animals. Modification 1. A simple method to serial renal clearance studies without urine collection in rats. 2. This was applied to non-radiolabeled para-aminohippurate sodium and iothalamate sodium which were used respectively to estimate renal blood flow and glomerular filtration rate. 3. An enzymatic method was developed for the determination of inulin and a colorimetric method was developed for determination of p-aminohippurate in the plasma and urine of rats. 17
- 18. 3. clearance methods described in monkeys ( Hropot et al.) Chimpanzees weighing 30.7 ±10.6 kg were anesthetized with 1 mg/kg Sernylan i.m. injection. Food was withdrawn 24 h prior to the experiment and the animals received only tap water. In the morning before the experiment, the urinary bladder of the animals was emptied by catheterization. The urine was discarded. To determine the glomerular filtration rate (inulin clearance), a bolus injection of 50 mg/kg inulin i.v. was given and followed by a continuous infusion of 3 ml/min inulin dissolved in Ringer lactate solution. After an equilibrium of 60 min, urine and blood samples were collected for two control clearance for 30 mins each. The control periods were followed by intravenous administration of the test preparation in a dose of 20 mg/kg. Thereafter, urine and blood samples were collected during 6 clearance periods. The following parameters were determined: urine excretion, inulin clearance and urate clearance, fractional excretion of urate and plasma urate . 18
- 19. MICROPUNCTURE TECHNIQUES IN THE RATS Purpose and Rationale Micropuncture techniques have been applied to the direct investigation of the effect of diuretics on single nephron function. The observed changes in tubular fluid reabsorptive rates and electrolyte concentrations can be used to asses the mechanism of action. The rat is the model of choice since proximal and distal tubules as well as collecting ducts are accessible for micropuncture. Methodology Speces -Rats ( 250 gm) Sex - male or female 19
- 20. PROCEDURE Rats with a body weight of 250g are anaesthetized with intraperitoneal injection of Thiopentone. The animals are fasted for 16 h before the beginning of the experiment, but have free access to tap water. After anesthesia the animals are placed on a thermostatically heated table. Thereafter rats are tracheotomized and carotid artery and jugular vein are cannulated for blood pressure recording, blood sampling, and for infusion of compounds, respectively. The left kidney is carefully exposed by a flank incision, embedded in a small plastic vessel with cotton wool, and bathed with paraffin oil at 37 °C. The ureter is cannulated and rectal temperature monitored continuously. A bolus injection of inulin 3H in NaCl solution is given, followed by 0.85% NaCl solution at a rate of 2.5 ml/min per 100 g body weight. The control puncture of tubules is performed 45 min after beginning of the intravenous infusion. The direct collection of tubular fluid samples from proximal and distal tubules is carried out with glass capillaries of 8 to10 μm external diameter using a micromanipulator and microscopic observation. 20
- 21. Distal tubules are identified by intravenous injection of lissamine green. The control period is followed by the test period. After an equilibration period of 30 min with the compound to be tested, micropuncture is performed again and tubular fluid is collected. The uretral urine is collected and blood sampling is performed in the middle of each clearance period. 1. The following parameters may be determined: inulin clearance (GFR), single nephron GFR, fractional delivery of water, sodium and potassium in proximal and distal tubules and in urine. 2. All data are expressed as mean values ±SEM. 3. Comparison of the effects of compounds to be tested with controls is performed by one way analysis of variance and by Student’s t-test for paired and unpaired data. Evaluation Cont…. 21
- 22. STOP FLOW TECHNIQUE Purpose and Rationale This procedure is of considerable value in the localization of transport processes along the length of the nephron. During clamping of the ureter, glomerular filtration is grossly reduced. The contact time for the tubular fluid in the respective nephron segments increases, and the concentration of the constituents of tubular fluid should approximate the static-head situation. After release of the clamp, the rapid passage of the tubular fluid should modify the composition of the fluid only slightly. The first samples should correspond to the distal nephron segment, the latest to glomerular fluid. However, with introduction of the micropuncture technique, the stop-flow method appears less attractive. 22
- 23. PROCEDURE This test can be performed on different animals. The ureter of an animal undergoing intense osmotic diuresis is clamped for several minutes allowing a relatively static column of urine to remain in contact with the various tubular segments for longer than the usual periods of time. Thus, the operation of each segment on the tubular fluid is exaggerated. Then the clamp is released, and the urine is sampled sequentially. Small serial samples are collected rapidly, the earliest sample representing fluid which had been in contact with the most distal nephron segment. Substances examined are administered along with inulin before the application of uretral occlusion. However, tubular segments downstream from the proximal segments may modify the tubular fluid during its egress. 23
- 24. EVALUATION Each sample the concentration of a glomerular marker, such as inulin, and the concentration of the under study are measured. Fractional excretion of the substance and the glomerular marker are plotted versus the cumulative urinary volume. Modifications of the method 1. stop-flow studies on tubular transport of uric acid in rats treated with pyrazinoic acid, an inhibitor of tubular urate secretion. 2. Tanaka et al. used stop-flow experiments to test uricosuric and diuretic activities of new compounds in dogs. 24
- 25. REFERENCES H. Gerhard Vogel “Drug Discovery and Evaluation” ,Pharmacological Assays , springer publication London , 2nd edition ,2002, pg (316-331). http://www.pharmatutor.org/articles/screening-diuretic-agents-overview 25
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