Subject animal studies

In normal human subjects, ANP infusion for one hour causes increased absolute and fractional sodium excretion, urine flow, GFR, and water clearance (53—55). As shown in many in vitro and in vivo animal studies, ANP achieves this by direct effect on the sodium reabsorption in the inner medullary collecting duct, ie, by reducing vasopressin-dependent free-water and sodium reabsorption leading to diuresis and by indirect effect through increased hemodynamic force upon the kidney. ANP inhibits the release of renin and aldosterone resulting in the decreased plasma renin activity and aldosterone concentration (56,57). 

In-vitro models can provide preliminary insights into some pharmacodynamic aspects. For example, cultured Caco 2 cell lines (derived from a human colorectal carcinoma) may be used to simulate intestinal absorption behaviour, while cultured hepatic cell lines are available for metabolic studies. However, a comprehensive understanding of the pharmacokinetic effects vfill require the use of in-vivo animal studies, where the drug levels in various tissues can be measured after different dosages and time intervals. Radioactively labelled drugs (carbon-14) may be used to facilitate detection. Animal model studies of human biopharmaceutical products may be compromised by immune responses that would not be expected when actually treating human subjects. 

The sponsor is obliged to submit safety reports for SUSAR events to the same timelines as apply in Europe. They must also report within 15 days any findings from animal studies that would suggest an increased risk to human subjects, such as carcinogenidty or mutagenidty. 

Tolerance is characterized by reduced responsiveness to the initial effects of a drug after repeated exposure or reduced responsiveness to a related compound (i.e., cross-tolerance). Animal studies have not provided conclusive evidence of tolerance to the effects of the centrally active compounds in toluene or trichloroethane (Moser and Balster 1981 Moser et al. 1985). Observations in humans, on the other hand, have documented pronounced tolerance among subjects who chronically inhale substances with high concentrations of toluene (Glaser and Massengale 1962 Press and Done 1967) and butane (Evans and Raistrick 1987). Kono et al. (2001) showed that tolerance to the reinforcing effects of solvents is comparable to that conditioned by nicotine but less intense than that reported with alcohol or methamphetamine use. 

Phytochemicals have been the subject of many studies evaluating their effects in relation to common chronic human illnesses such as cancer and cardiovascular diseases. These studies encounter difficulties in using this information to influence the dietary patterns of consumers because in the past they have used models or experiments with animals. However, in the last decade, researchers have moved away from animal studies in favour of human cell models or human intervention studies. Scientists still need to determine the likely incidence of illness from exposure to known amounts of a given natural compound in the diet and specifically in relation to the complex matrices of whole foods. Therefore, it is inevitable that some animal studies have to be continued for toxicological studies. 

A number of studies in humans show that PUFAs can generate significant immunomodulatory effects. Generally, these studies have utilized considerably lower amounts of fish oil to treat subjects than found in most animal studies. Numerous clinical trials have examined the effects of fish oil on rheumatoid arthritis and many have reported statistically significant benefits such as decreased morning stiffness and numbers of tender joints [57]. Several other studies have reported that PUFAs can provide therapeutic benefits for patients with IgA nephropathy, the most common primary human glomerulonephritis... 

There are only two reports of the human evaluation of a 6-hydroxylated N,N-dialkyltryptamine. Szara and Hearst (223) studied the effects of 6-hydroxy-N,N-diethyltryptamine (6-OH-DET 56) in a single subject. Doses of 1 and 2 mg were inactive a 5-mg dose produced a short-lasting perceptual disturbance and a 10-mg dose, after 1 hr, produced some psychotomimetic disturbances. Rosenberg et al. (182) compared the activity of DMT with that of 6-OH-DMT (55) in five human subjects. While DMT was active, the 6-hydroxy derivative was found to be inactive at intramuscular doses of approximately 50 to 75 mg. At a dose of 10 mg/kg, 6-OH-DMT (55) increased spontaneous activity in mice more so than a comparable dose of DMT 6-OH-DET (36) was essentially equiactive with DET in this respect (224). In most other animal studies, however, 6-hydroxylation of DMT has been observed to result in a decrease or complete loss of behavioral activity (228,236-238). The behavioral potency of 5-OMeDMT (59) was also reduced by 6-hydroxylation (226). 7-Hydroxy-N,N-dimethyltrypt-amine (7-OH-DMT 57) has not been evaluated in man. At an intraperitoneal dose of 33 jtM/kg, 7-OH-DMT displayed no behavioral effects in rats (228). The pharmacologic effects of all four hydroxylated derivatives of DMT, psilocin (49), bufotenine (53), 6-OH-DMT (55), and 7-OH-DMT (57) have been compared in studies by Taborsky et al. (228) and by Cerletti et al. (29). 

Data adequacy The key study was well designed, conducted, and documented used 20 human subjects and utilized a range of concentrations and exposure durations. Occupational exposures support the 8-h AEGL value. The mechanism of headache induction (vasodilation) is well understood and occurs following therapeutic administration of nitrate esters to humans. Animal studies utilized several mammalian species and addressed metabolism, neurotoxicity, developmental and reproductive toxicity, and potential carcinogenicity. ... 

The AEGL-1 concentration was based on a 1-hour (h) no-effect concentration of 8,000 parts per million (ppm) in healthy human subjects (Emmen et al. 2000). This concentration was without effects on pulmonary function, respiratory parameters, the eyes (irritation), or the cardiovascular system. Because this concentration is considerably below that causing any adverse effect in animal studies, an intraspecies uncertainty factor (UF) of 1 was applied. The intraspecies UF of 1 is supported by the absence of adverse effects in therapy tests with patients with severe chronic obstructive pulmonary disease and adult and pediatric asthmatics who were tested with metered-dose inhalers containing HFC-134a as the propellant. Because blood concentrations in this study approached equilibrium following 55 minutes (min) of exposure and effects are determined by blood concentrations, the value of 8,000 ppm was made equivalent across all time periods. The AEGL-1 of 8,000 ppm is supported by the absence of adverse effects in experimental animals that inhaled considerably higher concentrations. No adverse effects were observed in rats exposed at 81,000 ppm for 4 h (Silber and Kennedy 1979) or in rats exposed... 

Experimental studies with human subjects and several mammalian species (monkey, dog, rat, mouse, and rabbit) were located. Animal studies addressed neurotoxicity, genotoxicity, carcinogenicity, and cardiac sensitization and were conducted over acute, subchronic, and chronic exposure durations. 

The database for HFC-134a is extensive it contains studies with both human subjects and animal models. Potentially sensitive populations, including patients with COPD and adult and pediatric asthmatic patients, were tested with direct inhalation of HFC-134a from metered-dose inhalers. The response of these groups was no different than that of healthy adults. The animal studies covered acute, subchronic, and chronic exposure durations and addressed systemic toxicity as well as neurotoxicity, reproductive and developmental effects, cardiac sensitization, genotoxicity, and carcinogenicity. The metabolism of HFC-134a is well understood, and the relationship of exposure con... 

The AEGL-1 value was based on the observation that exercising healthy human subjects could tolerate exposure to concentrations of 500 or 1,000 ppm for 4 h with no adverse effects on lung function, respiratory symptoms, sensory irritation, or cardiac symptoms (Utell et al. 1997). The exercise, which tripled the subjects minute ventilation, simulates an emergency situation and accelerates pulmonary uptake. Results of the exposure of two subjects for an additional 2 h to the 500-ppm concentration and the exposure of one subject to the 1,000-ppm concentration for an additional 2 h failed to elicit any clear alterations in neurobehavioral parameters. The 4- or 6-h 1,000-ppm concentration is a NOAEL in exercising individuals, there were no indications of response differences among tested subjects, and animal studies indicate that adverse effects occur only at considerably higher concentrations, so the 1,000-ppm value was adjusted by an uncertainty factor (UF) of 1. The intraspecies UF of 1 is supported by the lack of adverse effects in patients with severe... 

The data base for HCFC-141b is extensive and contains studies with human subjects as well as several mammalian species. The study with human subjects was well conducted and addressed clinical symptoms, respiratory effects, cardiotoxicity, hematology and clinical chemistry effects, and pharmacokinetics. The study with humans established a no-effect level (AEGL-1) that may be conservative, because a lowest-observed-effect level was not attained. The AEGL-1 of 1,000 ppm is supported by the animal data, which show an absence of effects at concentrations that are higher by a factor of 10. Animal studies addressed both acute and chronic exposure durations as well as neurotoxicity, genotoxicity, carcinogenicity, and cardiac sensitiza... 

Data Adequacy Although human data are limited to primarily occupational monitoring studies, the data base on animal studies is good. The test atmosphere in the key study was supplied via a face mask to the restrained test subjects restrained animals have been shown to be more sensitive than unrestrained animals to inhaled toxicants. Relative species sensitivity to inhaled HCN may be related to breathing rate. Compared to rodents, the slower breathing rate of humans and monkeys may make them less sensitive to the effects of HCN. 

None of these earlier animal studies had been rigorously for protein, calcium, or acid output. The data of the present study demonstrated that the acid nature of the diet, fed at constant levels, and to the same subjects, induced hypercalciuria in the meat period. 

Interval or satellite groups have been discussed at two earlier points in this chapter. They allow measurement of termination parameters at intervals other than at termination of the study. They are also useftd when the manipulation involved in making a measurement (such as the collection of an extensive blood sample), while not terminal, may compromise (relative to other animals) the subject animals. Another common use of such groups is to evaluate recovery from some observed effect at study termination. 

Animal studies show that chlordecone can pass into your blood when you eat food contaminated with it. Animal data show that only a small amount of chlordecone can pass through the skin into the bloodstream. We do not know if or how much chlordecone can pass from your lungs into your blood when you breathe it in. Like mirex, once chlordecone is taken up by your body, it is carried by the blood throughout the body and is stored for a long time. Unlike mirex, chlordecone is found mainly in the liver. Chlordecone is broken down to chlordecone alcohol, which is a less harmful product. Chlordecone and its breakdown product slowly leave the body through the feces. This process can take from several weeks to months. Very little chlordecone leaves the body in the urine. Chlordecone has also been found in saliva and human milk. Refer to Chapter 2 for more information on this subject. 

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