Depression deaths

All prescription drug abuse may lead to harmful consequences such as accidents, injuries, blackouts, legal problems, and unsafe sexual behavior, which can increase the risk of acquiring sexually transmitted diseases (STDs) and human immunodeficiency virus (HIV). Specifically, each class of drugs has certain potentially life-threatening consequences of abuse. The abuse of opioids may lead to severe respiratory depression and inability to breathe, which can lead to death. Depressants may also cause respiratory depression and may lead to seizures if an addict suddenly stops taking them. Stimulants speed up the body s activities and raise blood pressure and heart rate, and when abused, may lead to a heart attack, stroke, or a seizure. Combinations... 

Intoxicated birds may show sudden death, depression, disorientation, abnormal postures, and apparent blindness. 

As of the mid-1990s, use of MAOIs for the treatment of depression is severely restricted because of potential side effects, the most serious of which is hypertensive crisis, which results primarily from the presence of dietary tyramine. Tyramine, a naturally occurring amine present in cheese, beer, wine, and other foods, is an indirecdy acting sympathomimetic, that is, it potently causes the release of norepinephrine from sympathetic neurons. The norepinephrine that is released interacts with adrenoceptors and, by interacting with a-adrenoceptors, causes a marked increase in blood pressure the resultant hypertension may be so severe as to cause death. 

It must be remembered that all anesthetics and tranquilizers are used by the practitioner following a risk—benefit evaluation. General anesthesia, even being adininistered by an experienced practitioner, can result in death through cardiac or respiratory depression. The veterinarian is acutely aware of these risks and chooses the dmg and method of adininistration considering the patient s health status, the nature of and need for the procedure, and the likelihood of success. 

Acute benzene poisoning results in CNS depression and is characterized by an initial euphoria followed by staggered gait, stupor, coma, and convulsions. Exposure to approximately 4000 ppm benzene results in complete loss of consciousness. Insomnia, agitation, headache, nausea, and drowsiness may persist for weeks after exposure (126). Continued inhalation of benzene to the point of euphoria has caused irreversible encephalopathy with tremulousness, emotional lability, and diffuse cerebral atrophy (125). In deaths arising from acute exposure, respiratory tract infection, hypo- and hyperplasia of sternal bone marrow, congested kidneys, and cerebral edema have been found at autopsy. 

Overexposure to tetrachloroethylene by inhalation affects the central nervous system and the Hver. Dizziness, headache, confusion, nausea, and eye and mucous tissue irritation occur during prolonged exposure to vapor concentrations of 200 ppm (15). These effects are intensified and include incoordination and dmnkenness at concentrations in excess of 600 ppm. At concentrations in excess of 1000 ppm the anesthetic and respiratory depression effects can cause unconsciousness and death. A single, brief exposure to concentrations above 6000 ppm can be immediately dangerous to life. Reversible changes to the Hver have been reported foUowing prolonged exposures to concentrations in excess of 200 ppm (16—22). Alcohol consumed before or after exposure may increase adverse effects. 

Air-poUutant effects on neural and sensory functions in humans vary widely. Odorous pollutants cause only minor annoyance yet, if persistent, they can lead to irritation, emotional upset, anorexia, and mental depression. Carbon monoxide can cause death secondary to the depression of the respiratory centers of the central nervous system. Short of death, repeated and prolonged exposure to carbon monoxide can alter sensory protection, temporal perception, and higher mental functions. Lipid-soluble aerosols can enter the body and be absorbed in the lipids of the central nervous system. Once there, their effects may persist long after the initial contact has been removed. Examples of agents of long-term chronic effects are organic phosphate pesticides and aerosols carrying the metals lead, mercury, and cadmium. 

CNS DEPRESSANT Substanccs, e.g. anaesthetics and narcotics, which depress the activity of the central nervous system. Symptoms following exposure include headache, dizziness, loss of consciousness, respiratory or cardiac depression, death. 

The toxic effect depends both on lipid and blood solubility. I his will be illustrated with an example of anesthetic gases. The solubility of dinitrous oxide (N2O) in blood is very small therefore, it very quickly saturates in the blood, and its effect on the central nervous system is quick, but because N,0 is not highly lipid soluble, it does not cause deep anesthesia. Halothane and diethyl ether, in contrast, are very lipid soluble, and their solubility in the blood is also high. Thus, their saturation in the blood takes place slowly. For the same reason, the increase of tissue concentration is a slow process. On the other hand, the depression of the central nervous system may become deep, and may even cause death. During the elimination phase, the same processes occur in reverse order. N2O is rapidly eliminated whereas the elimination of halothane and diethyl ether is slow. In addition, only a small part of halothane and diethyl ether are eliminated via the lungs. They require first biotransformation and then elimination of the metabolites through the kidneys into the... 

Cocaine. This lias a bitter taste, is mydriatic, produces local anaesthesia and is toxic. After absorption, or when taken internally, it acts chiefly by stimulation of the central nervous system, succeeded by depression. Since the two phases may be present in different areas simultaneously, a mixed result may ensue. With large doses the chief symptoms are those of medullary depression. Death is due to paralysis of the respiratory centre. The main use of cocaine in medicine is as a local anaesthetic. 

Both Cushny and Dale found the amorphous gelsemium alkaloids represented by such fractions as gelseminine much more active than gelsemine. Cushny stated that gelseminine resembled coniine in action and showed a greater depressant effect on the central nervous system, but unlike coniine it exerted no pressor effect. It was also a powerful mydriatic. Dale found that 0-001 gm. of the hydrochlorides of the amorphous alkaloids injected into rabbits caused death from respiratory failure in 25 minutes, preceded by convulsions. These results are explained by the subsequent isolation from such amorphous fractions, of the potent alkaloids sempervirine and gelsemicine. 

Ethanol is classified for medical purposes as a central nervous system (CNS) depressant. Its effects—that is, being drunk—resemble the human response to anesthetics. There is an initial excitability and increase in sociable behavior, but this results from depression of inhibition rather than from stimulation. At a blood alcohol concentration of 0.1% to 0.3%, motor coordination is affected, accompanied by loss of balance, slurred speech, and amnesia. When blood alcohol concentration rises to 0.3% to 0.4%, nausea and loss of consciousness occur. Above 0.6%, spontaneous respiration and cardiovascular regulation are affected, ultimately leading to death. The LD50 of ethanol is 10.6 g/kg (Chapter 1 Focus On). 

Use With Alcohol. Alcohol is a CNS depressant, as are the sedatives and hypnotics. When alcohol and a sedative or hypnotic are taken together, there is an additive effect and an increase in CNS depression, which has, on occasion, resulted in death. The nurse must emphasize tiie importance of not drinking alcohol while taking this drug and stress that the use of alcohol and any one of these drains can result in serious effects. 

Major gastrointestinal effects include decreased gut motility and changes in secretion of gastric and intestinal fluids. Morphine and most p receptor agonists cause pupillary constriction. Some tolerance to this effect may develop, but addicts with high opioid levels will still have miosis. Respiratory depression is the usual cause of death from opioid overdose. 

Death from overdose of barbiturates may occur and is more likely when more than 10 times the hypnotic dose is ingested. The barbiturates with high lipid solubility and short half-lives are the most toxic. Thus the lethal dose of phenobarbital is 6—10 g, whereas that of secobarbital, pentobarbital, or amo-barbital is 2-3 g. Symptoms of barbiturate poisoning include CNS depression, coma, depressed reflex activity, a positive Babinski reflex, contracted pupils (with hypoxia there may be paralytic dilation), altered respiration, hypothermia, depressed cardiac function, hypotension, shock, pulmonary complications, and renal failure. 

Death after the use of MDMA or MDEA is rare but may occur because of induction of cardiac arrhythmias or as a consequence of risk-taking behavior. Following its acute effects, MDMA may produce symptoms such as anxiety, depression, and confusion, which, in some cases, continue for several weeks (Dowling et al. 1987). 

One of six workers died 12 days after exposure to a mixture of half dimethyltin dichloride and half trimeth-yltin chloride vapour during cleaning of a cauldron at a chemical plant in Germany in 1981. Maximum exposure time was 1.5 h over a 3-day period no estimates of exposure concentration were made. Symptoms preceding death included excretion of high levels of tin in the urine, respiratory depression, and coma (Rey et al.,... 

---