Nerve agents, nervous system effects

In addition to battlefield trauma, there is also the risk of exposure to chemical weapons such as the nerve agents, notably the organophosphorus gases (soman, sarin, VX, tabun) [6]. Organophosphorus toxicity arises largely from their ability to irreversibly inhibit acetyl-cholinesterases, leading to effects associated with peripheral acetyl-choline accumulation (muscarinic syndrome) such as meiosis, profuse sweating, bradychardia, bronchioconstriction, hypotension, and diarrhoea. Central nervous system effects include anxiety, restlessness, confusion, ataxia, tremors. 

The initial effects of nerve agents depend on the dose and route of exposure. A small inhalation exposure from nerve agent vapor causes a response in the eyes, nose and airway, such as miosis, conjunctival injection, eye pain, rhinorrhea, bron-choconstriction, excessive bronchial secretions, and mild to moderate dyspnea (9,13,18). Larger exposures cause central nervous system effects within seconds to minutes, including loss of consciousness, seizures, and central apnea. Death can occur within 5-lOmin of a lethal dose, usually due to respiratory failure from the combined effects of respiratory muscle paralysis, loss of airway control and profuse bronchorrhea (13,14). 

V. DIRECT CENTRAL NERVOUS SYSTEM EFFECTS OF CWAs AND STRESS A. Acute Exposure to Nerve Agents... 

Both the G- and V-agents have the same physiological action on humans. They are potent inhibitors of the enzyme acetylcholinesterase (AChE), which is required for the function of many nerves and muscles in nearly every multicellular animal. Normally, AChE prevents the accumulation of acetylcholine after its release in the nervous system. Acetylcholine plays a vital role in stimulating voluntary muscles and nerve endings of the autonomic nervous system and many structures within the CNS. Thus, nerve agents that are cholinesterase inhibitors permit acetylcholine to accumulate at those sites, mimicking the effects of a massive release of acetylcholine. The major effects will be on skeletal muscles, parasympathetic end organs, and the CNS. 

Another very important site for drug delivery is the central nervous system (CNS). The blood-brain barrier presents a formidable barrier to the effective delivery of most agents to the brain. Interesting work is now advancing in such areas as direct convective delivery of macromolecules (and presumably in the future macromolecular drug carriers) to the spinal cord [238] and even to peripheral nerves [239]. For the interested reader, the delivery of therapeutic molecules into the CNS has also been recently comprehensively reviewed... 

The endogenous release of the potent vasoconstrictor neuropeptide Y (NPY) is increased during sepsis and the highest levels are detected in patients with shock (A8). NPY is a 36-amino-acid peptide belonging to the pancreatic polypeptide family of neuroendocrine peptides (T2). It is one of the most abundant peptides present in the brain and is widely expressed by neurons in the central and peripheral nervous systems as well as the adrenal medulla (A3). NPY coexists with norepinephrine in peripheral sympathetic nerves and is released together with norepinephrine (LI9, W14). NPY causes direct vasoconstriction of cerebral, coronary, and mesenteric arteries and also potentiates norepinephrine-induced vasoconstriction in these arterial beds (T8). It appears that vasoconstriction caused by NPY does not counterbalance the vasodilatator effects of substance P in patients with sepsis. The properties of vasodilatation and smooth muscle contraction of substance P are well known (14), but because of the morphological distribution and the neuroendocrine effects a possible stress hormone function for substance P was also advocated (J7). Substance P, which is a potent vasodilatator agent and has an innervation pathway similar to that of NPY, shows a low plasma concentration in septic patients with and without shock (A8). 

Toxins present a variety of both incapacitating and lethal effect. Most toxins of military significance can be broadly classified in one of two ways. Neurotoxins disrupt the nervous system and interfere with nerve impulse transmission similar to nerve agents (Chapter 1). However, all neurotoxins do not operate through the same mechanism of action or do they produce the same symptoms. Cytotoxins are poisons that destroy cells or impair cellular activities. Symptoms may resemble those of vesicants (Chapter 3) or they may resemble food poisoning or other diseases. Toxins may also produce effects that are a combination of these general categories. The consequences of intoxication from any individual toxin can vary widely with route of exposure and dose. In addition, some toxins act as biomediators and cause the body to release excessive, and therefore harmful, amounts of chemicals that are normally produced by the body. 

Target Organ Toxicity. -Hexane exposure is documented to cause toxicity in peripheral nerves of humans (both sensory and motor). In rats, -hexane exposure causes toxicity in the peripheral and central nervous system and in male reproductive tissues. Effects on respiratory tissue have been observed in mice and rabbits. The toxic agent in nervous system and reproductive tissues is believed to be the -hexane metabolite 2,5-hexanedione (Graham et al. 1995). 

The actions of p-blockers on blood pressure are complex. After acute administration, blood pressure is only slightly altered. This is because of the compensatory reflex increase in peripheral vascular resistance that results from a (3-blocker-induced decrease in cardiac output. Vasoconstriction is mediated by a-receptors, and a-receptors are not antagonized by (3-receptor blocking agents. Chronic administration of (3-blockers, however, results in a reduction of blood pressure, and this is the reason for their use in primary hypertension (see Chapter 20). The mechanism of this effect is not well understood, but it may include such actions as a reduction in renin release, antagonism of (3-receptors in the central nervous system, or antagonism of presynaptic facilita-tory (3-receptors on sympathetic nerves. 

The neurotrophins represent a family of survival and differentiation factors that exert profound effects in the central and peripheral nervous systems. The neurotrophins are currently under investigation as therapeutic agents for the treatment of neurodegenerative disorders and nerve injury either individually or in combination with other trophic factors such as ciliary neurotrophic factor (CNTF) or fibroblast growth factor (FGF). 

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