From Citizendium, the Citizens' Compendium
Jump to: navigation, search
This article is developed but not approved.
Main Article
Related Articles  [?]
Bibliography  [?]
External Links  [?]
Citable Version  [?]
This editable Main Article is under development and not meant to be cited; by editing it you can help to improve it towards a future approved, citable version. These unapproved articles are subject to a disclaimer.
Neurotoxins can be found in a number of organisms, including some strains of cyanobacteria,[1] which can be found in algal blooms or washed up on the shore in a green scum[2]

Neurotoxin is derived from the Greek νευρών (nevron / neuron) meaning "nerve" (derived from neuro: "cord")[3] and Latin toxicum meaning "poison" (derived from Greek τοξικόν φάρμακον toxikon pharmakon, meaning "arrow poison"[4]). They are an extensive class of exogenous chemical neurological insults[5] which can adversely affect function in both developing and mature nervous tissue.[6] The term can also be used to classify endogenous compounds which when abnormally concentrated can prove neurologically toxic.[5] Though neurotoxins are often neurologically destructive, their ability to specifically target neural components is important in the study of nervous systems.[7] Common examples of neurotoxins include lead,[8] ethanol,[9] glutamate,[10] nitric oxide (NO),[11] botulinum toxin,[12] tetanus toxin,[13] and tetrodotoxin.[7]

Neurotoxin activity can be characterized by the ability to inhibit neuron control over ion concentrations across the cell membrane,[7] or communication between neurons across a synapse.[14] Local pathology of neurotoxin exposure often includes neuron excitotoxicity or apoptosis[15] but can also include glial cell damage.[16] Macroscopic manifestations of neurotoxin exposure can include widespread central nervous system damage such as mental retardation,[6] persistent memory impairments,[17] epilepsy, and dementia.[18] Additionally, neurotoxin-mediated peripheral nervous system damage such as neuropathy or myopathy is common. Support has been shown for a number of treatments aimed at attenuating neurotoxin-mediated injury, such as antioxidant,[9] antitoxin[19] and ethanol[20] administration.


Illustration of typical multipolar neuron

Exposure to neurotoxins in society is not new as civilizations have been exposed to neurologically destructive compounds for thousands of years. One notable example is the possible significant lead exposure during the Roman Empire resulting from the development of extensive plumbing networks[21] and the habit of boiling vinegared wine in lead pans to sweeten it, the process generating lead acetate, known as "sugar of lead". In part, neurotoxins have been part of human history because of the fragile and susceptible nature of the nervous system, making it highly prone to disruption.

The nervous tissue found in the brain, spinal cord, and periphery comprises an extraordinarily complex biological system that largely defines many of the unique traits of individuals. As with any highly complex system, however, even small perturbations to its environment can lead to significant functional disruptions. Properties leading to the susceptibility of nervous tissue include a high surface area of neurons, a high lipid content which retains lipophilic toxins, high blood flow to the brain inducing increased effective toxin exposure, and the persistence of neurons through an individual's lifetime, leading to compounding of damages.[22] As a result, the nervous system has a number of mechanisms designed to protect it from internal, and external insults, including the blood brain barrier.

The blood brain barrier (BBB) is one critical example of protection which prevents toxins and other adverse compounds from reaching the brain.[23] As the brain requires nutrient entry and waste removal, it is perfused by blood flow. Blood can carry a number of ingested toxins, however, which would induce significant neuron death if they reach nervous tissue. Thus, protective cells termed astrocytes surround the capillaries in the brain and absorb nutrients from the blood and subsequently transport them to the neurons, effectively isolating the brain from a number of potential chemical insults.[23]

Astrocytes surrounding capillaries in the brain to form the blood brain barrier

This barrier creates a tight hydrophobic layer around the capillaries in the brain, inhibiting the transport of large or hydrophilic compounds. In addition to the BBB, the choroid plexus provides a layer of protection against toxin absorption in the brain. The choroid plexuses are vascularized layers of tissue found in the third, fourth, and lateral ventricles of the brain, which through the function of their ependymal cells, are responsible for the synthesis of cerebrospinal fluid (CSF).[24] Importantly, through selective passage of ions and nutrients and trapping heavy metals such as lead, the choroid plexuses maintain a strictly regulated environment which contains the brain and spinal cord.[23][24]

Choroid plexus

By being hydrophobic and small, or inhibiting astrocyte function, some compounds including certain neurotoxins are able to penetrate into the brain and induce significant damage. In modern times, scientists and physicians have been presented with the challenge of identifying and treating neurotoxins, which has resulted in a growing interest in both neurotoxicology research and clinical studies.[25] Though clinical neurotoxicology is largely a burgeoning field, extensive inroads have been made in the identification of many environmental neurotoxins leading to the classification of 750 to 1000 known potentially neurotoxic compounds.[22] Due to the critical importance of finding neurotoxins in common environments, specific protocols have been developed by the Environmental Protection Agency (EPA) for testing and determining neurotoxic effects of compounds (USEPA 1998). Additionally, in-vitro systems have increased in use as they provide significant improvements over the more common in-vivo systems of the past. Examples of improvements include tractable, uniform environments, and the elimination of contaminating effects of systemic metabolism.[25] In-vitro systems, however, have presented problems as it has been difficult to properly replicate the complexities of the nervous system, such as the interactions between supporting astrocytes and neurons in creating the BBB.[26] To even further complicate the process of determining neurotoxins when testing in-vitro, neurotoxicity and cytotoxicity may be difficult to distinguish as exposing neurons directly to compounds may not be possible in-vivo, as it is in-vitro. Additionally, the response of cells to chemicals may not accurately convey a distinction between neurotoxins and cytotoxins, as symptoms like oxidative stress or skeletal modifications may occur in response to either.[27]

In an effort to address this complication, neurite outgrowths (either axonal or dendritic) in response to applied compounds have recently been proposed as a more accurate distinction between true neurotoxins and cytotoxins in an in-vitro testing environment. Due to the significant inaccuracies associated with this process, however, it has been slow in gaining widespread support.[28] Additionally, biochemical mechanisms have become more widely used in neurotoxin testing, such that compounds can be screened for sufficiency to induce cell mechanism interference, like the inhibition of acetylcholinesterase capacity of organophosphates (includes DDT and sarin gas).[29] Though methods of determining neurotoxicity still require significant development, the identification of deleterious compounds and toxin exposure symptoms has undergone significant improvement.

Applications in neuroscience

Though diverse in chemical properties and functions, neurotoxins share the common property that they act by some mechanism leading to either the disruption or destruction of necessary components within the nervous system. Neurotoxins, however, by their very design have shown highly useful in the field of neuroscience. As the nervous system in most organisms is both highly complex and necessary for survival, it has naturally become a target for attack by both predators and prey. As venomous organisms often use their neurotoxins to subdue a predator or prey very rapidly, toxins have evolved to become highly specific to their target channels such that the toxin does not readily bind other targets.[30] As such, neurotoxins provide an effective means by which certain elements of the nervous system may be accurately and efficiently targeted. An early example of neurotoxin based targeting used radiolabeled tetrodotoxin to assay sodium channels and obtain precise measurements about their concentration along nerve membranes.[30] Likewise through isolation of certain channel activities, neurotoxins have provided the ability to improve the original Hodgkin-Huxley model of the neuron in which it was theorized that single generic sodium and potassium channels could account for most nervous tissue function.[30] From this basic understanding, the use of common compounds such as tetrodotoxin, tetraethylammonium, and bungarotoxins have led to a much deeper understanding of the distinct ways in which individual neurons may behave.

Mechanisms of activity

As neurotoxins are compounds which adversely affect the nervous system, a number of mechanisms through which they function are through the inhibition of neuron cellular processes. These inhibited processes can range from membrane depolarization mechanisms to inter-neuron communication. By inhibiting the ability for neurons to perform their expected intracellular functions, or pass a signal to a neighboring cell, neurotoxins can induce systemic nervous system arrest as in the case of botulinum toxin,[14] or even nervous tissue death.[31] The time required for the onset of symptoms upon neurotoxin exposure can vary between different toxins, being on the order of hours for botulinum toxin[19] and years for lead.[32]

Neurotoxin classification Neurotoxins
Na channel inhibitors Tetrodotoxin[7]
K channel inhibitors Tetraethylammonium[33]
Cl channel inhibitors Chlorotoxin,[34] curare[35]
Ca channel inhibitors Conotoxin[36]
Inhibitors of synaptic vesicle release Botulinum toxin,[37] tetanus toxin[38]
Receptor inhibitors Bungarotoxin[39]
Blood brain barrier inhibitors Aluminium,[40] mercury[41]
Cytoskeleton interference Arsenic,[42] ammonia[43]
Ca-mediated cytotoxicity Lead[44]
Multiple effects Ethanol[45][46]
Endogenous neurotoxin sources Nitric oxide,[47] glutamate[48]


Sodium channel

The puffer fish is a well known tetrodoxin producer
Tetrodotoxin (TTX) is a poison produced by organisms belonging to the Tetradontidae order, which includes the puffer fish, ocean sunfish, and porcupine fish.[49] Within the puffer fish, which is a common delicacy especially in Japan, TTX is found in the liver, gonads, ovaries, intestines, and skin.[7][50] TTX can be fatal if consumed, and has become a common form of poisoning in many countries (How 2003). Common symptoms of TTX consumption include paraesthesia (often restricted to the mouth and limbs), muscle weakness, nausea, and vomiting[49] and often manifest within 30 minutes of ingestion.[51] The primary mechanism by which TTX is toxic is through the inhibition of sodium channel function, which reduces the functional capacity of neuron communication.
Inhibited signaling response resulting from neuron exposure to tetrodotoxin
This inhibition largely affects a susceptible subset of sodium channels known as TTX-sensitive (TTX-s), which also happens to be largely responsible for the sodium current that drives the depolarization phase of neuron action potentials.[7] TTX-resistant (TTX-r) is another form of sodium channel which has limited sensitivity to TTX, and is largely found in small diameter axons such as those found in nociception neurons.[7] When significant levels of TTX is ingested, it will bind sodium channels on neurons and reduce their membrane permeability to sodium. This results in an increased effective threshold of required excitatory signals in order to induce an action potential in a postsynaptic neuron.[7] The effect of this increased signaling threshold is a reduced excitability of postsynaptic neurons, and subsequent loss of motor and sensory function which can result in paralysis and death. Though assisted ventilation may increase the chance of survival after TTX exposure, there is currently no antitoxin. The use of the acetylcholinesterase inhibitor Neostigmine or the acetylcholine antagonist Atropine, however, can increase sympathetic nerve activity enough to improve the chance of survival after TTX exposure.[49]

Potassium channel

Black mamba (Dendroaspis polylepis)

Dendrotoxins are a class of neurotoxins produced by mamba snakes (Dendroaspis) that block particular subtypes of voltage-gated potassium channels in neurons, thereby enhancing the release of acetylcholine at neuromuscular junctions. A single dendrotoxin molecule associates reversibly with a potassium channel in order to exert its inhibitory effect. It is proposed that this interaction is mediated by electrostatic interactions between the positively-charged amino acid residues in the cationic domain of dendrotoxin and the negatively-charged residues in the ion channel pore. Potassium channels, similar to other cation-selective channels, are believed to have a cloud of negative charges that precede the opening to the channel pore that help conduct potassium ions through the permeation pathway. It is generally believed (though not proven) that a dendrotoxin molecules bind to anionic sites near the extracellular surface of the channel and physically occlude the pore, thereby preventing ion conductance. However, Imredy and MacKinnon [52] have proposed that delta-dendrotoxin may have an off-center binding site on their target proteins, and may inhibit the channel by altering the structure of the channel, rather than physically blocking the pore.


Tetraethylammonium (TEA) is a compound that, like a number of neurotoxins, was first identified through its damaging effects to the nervous system and shown to have the capacity of inhibiting the function of motor nerves and thus the contraction of the musculature in a manner similar to that of curare.[53] Additionally, through chronic TEA administration, muscular atrophy would be induced.[53] It was later determined that TEA functions in-vivo primarily through its ability to inhibit both the potassium channels responsible for the delayed rectifier seen in an action potential and some population of calcium-dependent potassium channels.[33] It is this capability to inhibit potassium flux in neurons that has made TEA one of the most important tools in neuroscience. It has been hypothesized that the ability for TEA to inhibit potassium channels is derived from its similar space-filling structure to potassium ions.[53] What makes TEA very useful for neuroscientists is its specific ability to eliminate potassium channel activity, thereby allowing the study of neuron response contributions of other ion channels such as voltage gated sodium channels.[54] In addition to its many uses in neuroscience research, TEA has been shown to perform as an effective treatment of Parkinson's disease through its ability to limit the progression of the disease.[55]

Chloride channel


Chlorotoxin (Cltx) is the active compound found in scorpion venom, and is primarily toxic because of its ability to inhibit the conductance of chloride channels.[34] Ingestion of lethal volumes of Cltx results in paralysis through this ion channel disruption. Similar to botulinum toxin, Cltx has been shown to possess significant therapeutic value. Evidence has shown that Cltx can inhibit the ability for gliomas to infiltrate healthy nervous tissue in the brain, significantly reducing the potential invasive harm caused by tumors.[56][57]


The term "curare" is ambiguous because it has been used to describe a number of poisons which at the time of naming were understood differently from present day understandings. In the past the characterization has meant poisons used by South American tribes on arrows or darts, though it has matured to specify a specific categorization of poisons which act on the neuromuscular junction to inhibit signaling and thus induce muscle relaxation.[58] The neurotoxin category contains a number of distinct poisons, though all were originally purified from plants originating in South America.[58] The effect with which ingested curare poison is usually associated is muscle paralysis and resultant death.[59] Curare notably functions to inhibit GABA-induced chloride channels, resulting in reduced ability for chloride to flux.[35] As such, the neurotoxin is capable of significantly reducing neuromuscular junction signaling, an effect which has resulted in its use by anesthesiologists to produce muscular relaxation.[60]

Calcium channel


Conotoxins represent a category of poisons produced by the marine cone snail, and are capable of inhibiting the activity of a number of ion channels such as calcium, sodium, or potassium channels.[61][62] In many cases, the toxins released by the different types of cone snails include a range of different types of conotoxins, which may be specific for different ion channels, thus creating a venom capable of widespread nerve function interruption.[61] One of the unique forms of conotoxins, ω-conotoxin (ω-CgTx) is highly specific for Ca channels and has shown usefulness in isolating them from a system.[63] As calcium flux is necessary for proper excitability of a cell, any significant inhibition could prevent a large amount of functionality. Significantly, ω-CgTx is capable of long term binding to and inhibition of voltage-dependent calcium channels located in the membranes of neurons but not those of muscle cells.[64]

Synaptic vesicle release

Botulinum toxin
Mechanism of Botulinum Toxin neurotoxicity

Botulinum Toxin (BTX) is a group of neurotoxins consisting of seven distinct compounds, referred to as BTX-A,B,C,D,E,F,G, which are produced by the bacterium Clostridium Botulinum and lead to muscular paralysis.[65] A notably unique feature of BTX is its relatively common therapeutic use in treating dystonia and spasticity disorders,[65] as well as in inducing muscular atrophy[12] despite being the most poisonous substance known.[19] BTX functions peripherally to inhibit acetylcholine (ACh) release at the neuromuscular junction through degradation of the SNARE proteins required for ACh vesicle-membrane fusion.[37] As the toxin is highly biologically active, an estimated dose of 1μg/kg body weight is sufficient to induce an insufficient tidal volume and resultant death by asphyxiation.[14] Due to its high toxicity, BTX antitoxins have been an active area of research. It has been shown that capsaicin (active compound responsible for heat in chili peppers) can bind the TRPV1 receptor expressed on cholinergic neurons and inhibit the toxic effects of BTX.[19]

Tetanus toxin

Tetanus neurotoxin (TeNT) is a compound that functionally reduces inhibitory transmissions in the nervous system resulting in muscular tetany. TeNT is similar to BTX, and is in fact highly similar in structure and origin; both belonging to the same category of clostridial neurotoxins.[13] Like BTX, TeNT inhibits inter-neuron communication by means of vesicular neurotransmitter (NT) release.[38] One notable difference between the two compounds is that while BTX inhibits muscular contractions, TeNT induces them. Though both toxins inhibit vesicle release at neuron synapses, the reason for this different manifestation is that BTX functions mainly in the peripheral nervous system (PNS) while TeNT is largely active in the central nervous system (CNS).[66] This is a result of TeNT migration through motor neurons to the inhibitory neurons of the spinal cord after entering through endocytosis.[67] This results in a loss of function in inhibitory neurons within the CNS resulting in systemic muscular contractions. Similar to the prognosis of a lethal dose of BTX, TeNT leads to paralysis and subsequent suffocation.[67]

Blood brain barrier


Neurotoxic behavior of aluminium is known to occur upon entry into the circulatory system, where it can migrate to the brain and inhibit some of the crucial functions of the blood brain barrier (BBB).[40] A loss of function in the BBB can produce significant damage to the neurons in the CNS, as the barrier protecting the brain from other toxins found in the blood will no longer be capable of such action. Though the metal is known to be neurotoxic, effects are usually restricted to patients incapable of removing excess ions from the blood, such as those experiencing renal failure.[68] Patients experiencing aluminium toxicity can exhibit symptoms such as impaired learning and reduced motor coordination.[69] Additionally, systemic aluminium levels are known to increase with age, and have been shown to correlate with Alzheimer's Disease, implicating it as a neurotoxic causative compound of the disease.[70]


Mercury is capable of inducing CNS damage by migrating into the brain by crossing the BBB.[41] Mercury exists in a number of different compounds, though methylmercury (MeHg) is the only significantly neurotoxic form.[41] MeHg is usually acquired through consumption of seafood, as it tends to concentrate in organisms high on the food chain.[71] It is known that the mercuric ion inhibits amino acid (AA) and glutamate (Glu) transport, potentially leading to excitotoxic effects.[72]

Receptor agonists and antagonists


Many-banded krait (Bungarus multicinctus)

Bungarotoxin is a compound with known interaction with nicotinic acetylcholine receptors (nAChRs), which constitute a family of ion channels whose activity is triggered by neurotransmitter binding.[73] Bungarotoxin is produced in a number of different forms, though one of the commonly used forms is the long chain alpha form, α-bungarotoxin, which is isolated from the banded krait snake.[39] Though extremely toxic if ingested, α-bungarotoxin has shown extensive usefulness in neuroscience as it is particularly adept at isolating nAChRs due to its high affinity to the receptors.[39] As there are multiple forms of bungarotoxin, there are different forms of nAChRs to which they will bind, and α-bungarotoxin is particularly specific for α7-nAChR.[74] This α7-nAChR functions to allow calcium ion influx into cells, and thus when blocked by ingested bungarotoxin will produce damaging effects, as ACh signaling will be inhibited.[74] Likewise, the use of α-bungarotoxin can be very useful in neuroscience if it is desirable to block calcium flux in order to isolate effects of other channels. Additionally, different forms of bungarotoxin may be useful for studying inhibited nAChRs and their resultant calcium ion flow in different systems of the body. For example α-bungarotoxin is specific for nAChRs found in the musculature and κ-bungarotoxin is specific for nAChRs found in neurons.[75]



Investigations into anatoxin-a, also known as "Very Fast Death Factor", began in 1961 following the deaths of cows that drank from a lake containing an algal bloom in Saskatchewan, Canada.[76][77] It is a cyanotoxin produced by at least four different genera of cyanobacteria, and has been reported in North America, Europe, Africa, Asia, and New Zealand.[78]

Toxic effects from anatoxin-a progress very rapidly because it acts directly on the nerve cells (neurons). The progressive symptoms of anatoxin-a exposure are loss of coordination, twitching, convulsions and rapid death by respiratory paralysis. The nerve tissues which communicate with muscles contain a receptor called the nicotinic acetylcholine receptor. Stimulation of these receptors causes a muscular contraction. The anatoxin-a molecule is shaped so it fits this receptor, and in this way it mimics the natural neurotransmitter normally used by the receptor, acetylcholine. Once it has triggered a contraction, anatoxin-a does not allow the neurons to return to their resting state, because it is not degraded by cholinesterase which normally performs this function. As a result the muscle cells contract permanently, the communication between the brain and the muscles is disrupted and breathing stops.[79][80]

When it was first discovered, the toxin was called the Very Fast Death Factor (VFDF) because when it was injected into the body cavity of mice it induced tremors, paralysis and death within a few minutes. In 1977, the structure of VFDF was determined as a secondary, bicyclic amine alkaloid, and it was renamed anatoxin-a.[81][82] Structurally, it is similar to cocaine.[83] There is continued interest in anatoxin-a because of the dangers it presents to recreational and drinking waters, and because it is a particularly useful molecule for investigating acetylcholine receptors in the nervous system.[84] The deadliness of the toxin means that it has a high military potential as a toxin weapon.[85]

Cytoskeleton interference


Arsenic is a neurotoxin commonly found concentrated in areas exposed to agricultural runoff, mining, and smelting sites (Martinez-Finley 2011). One of the effects of arsenic ingestion during the development of the nervous system is the inhibition of neurite growth[86] which can occur both in PNS and the CNS.[87] This neurite growth inhibition can often lead to defects in neural migration, and significant morphological changes of neurons during development,[88]) often leading to neural tube defects in neonates.[89] As a metabolite of arsenic, arsenite is formed after ingestion of arsenic and has shown significant toxicity to neurons within about 24 hours of exposure. The mechanism of this cytotoxicity functions through arsenite-induced increases in intracellular calcium ion levels within neurons, which may subsequently reduce mitochondrial transmembrane potential which activates caspases, triggering cell death.[88] Another known function of arsenite is its destructive nature towards the cytoskeleton through inhibition of neurofilament transport.[42] This is particularly destructive as neurofilaments are used in basic cell structure and support. Lithium administion has shown promise, however, in restoring some of the lost neurofilament motility.[90] Additionally, similar to other neurotoxin treatments, the administration of certain antioxidants has shown some promise in reducing neurotoxicity of ingested arsenic.[88]

An Astrocyte, a cell notable for maintaining the blood brain barrier

Ammonia toxicity is often seen through two routes of administration, either through consumption or through endogenous ailments such as hepatic failure.[91][92] One notable case in which ammonia toxicity is common is in response to cirrhosis of the liver which results in hepatic encephalopathy, and can result in cerebral edema (Haussinger 2006). This cerebral edema can be the result of nervous cell remodeling. As a consequence of increased concentrations, ammonia activity in-vivo has been shown to induce swelling of astrocytes in the brain through increased production of cGMP (Cyclic Guanosine Monophosphate) within the cells which leads to Protein Kinase G-mediated(PKG) cytoskeletal modifications.[43] The resultant effect of this toxicity can be reduced brain energy metabolism and function. Importantly, the toxic effects of ammonia on astrocyte remodling can be reduced through administration of L-carnitine.[91] This astrocyte remodeling appears to be mediated through ammonia-induced mitochondrial permeability transition. This mitochondrial transition is a direct result of glutamine activity a compound which forms from ammonia in-vivo.[93] Administration of antioxidants or glutaminase inhibitor can reduce this mitochondrial transition, and potentially also astrocyte remodling.[93]

Calcium-mediated cytotoxicity


Lead is a potent neurotoxin whose toxicity has been recognized for at least thousands of years.[94] Though neurotoxic effects for lead are found in both adults and young children, the developing brain is particularly susceptible to lead-induced harm, effects which can include apoptosis and excitotoxicity.[94] An underlying mechanism by which lead is able to cause harm is its ability to be transported by calcium ATPase pumps across the BBB, allowing for direct contact with the fragile cells within the central nervous system.[95] Neurotoxicity results from lead’s ability to act in a similar manner to calcium ions, as concentrated lead will lead to cellular uptake of calcium which disrupts cellular homeostasis and induces apoptosis.[44] It is this intracellular calcium increase that activates protein kinase C (PKC), which manifests as learning deficits in children as a result of early lead exposure.[44] In addition to inducing apoptosis, lead inhibits interneuron signaling through the disruption of calcium-mediated neurotransmitter release.[96]

Neurotoxins with multiple effects


Baby with FAS.jpg

As a neurotoxin, ethanol has been shown to induce nervous system damage and affect the body in a variety of ways, where in small doses ethanol has even been shown to have health benefits.[97] Among the known effects of ethanol exposure are both transient and lasting consequences. Some of the lasting effects include long-term reduced neurogenesis in the hippocampus,[98][99] widespread brain atrophy,[100] and induced inflammation in the brain.[101] Of note, chronic ethanol ingestion has additionally been shown to induce reorganization of cellular membrane constituents, leading to a lipid bilayer marked by increased membrane concentrations of cholesterol and saturated fat.[46] This is important as neurotransmitter transport can be impaired through vesicular transport inhibition, resulting in diminished neural network function. One significant example of reduced inter-neuron communication is the ability for ethanol to inhibit NMDA receptors in the hippocampus, resulting in reduced LTP (long-term potentiation) and memory acquisition.[45] NMDA has been shown to play an important role in long-term potentiation (LTP) and consequently memory formation.[102] With chronic ethanol intake, however, the susceptibility of these NMDA receptors to induce LTP increases in the mesolimbic dopamine neurons in an inositol 1,4,5-triphosphate (IP3) dependent manner.[103] This reorganization may lead to neuronal cytotoxicity both through hyperactivation of postsynaptic neurons and through induced addiction to continuous ethanol consumption. It has, additionally, been shown that ethanol directly reduces intracellular calcium ion accumulation through inhibited NMDA receptor activity, and thus reduces the capacity for the occurrence of LTP.[20]

In addition to the neurotoxic effects of ethanol in mature organisms, chronic ingestion is capable of inducing severe developmental defects. Evidence was first shown in 1973 of a connection between chronic ethanol intake by mothers and defects in their offspring.[104] This work was responsible for creating the classification of fetal alcohol syndrome; a disease characterized by common morphogenesis aberrations such as defects in craniofacial formation, limb development, and cardiovascular formation. The magnitude of ethanol neurotoxicity in fetuses leading to fetal alcohol syndrome has been shown to be dependent on antioxidant levels in the brain such as vitamin E.[105] As the fetal brain is relatively fragile and susceptible to induced stresses, severe deleterious effects of alcohol exposure can be seen in important areas such as the hippocampus and cerebellum. The severity of these effects is directly dependent upon the amount and frequency of ethanol consumption by the mother, and the stage in development of the fetus.[106] It is known that ethanol exposure results in reduced antioxidant levels, mitochondrial dysfunction (Chu 2007), and subsequent neuronal death, seemingly as a result of increased generation of reactive oxidative species (ROS).[31] This is a plausible mechanism, as there is a reduced presence in the fetal brain of antioxidant enzymes such as catalase and peroxidase.[107] In support of this mechanism, administration of high levels of dietary vitamin E results in reduced or eliminated ethanol-induced neurotoxic effects in fetuses.[9]


n-Hexane is a neurotoxin. It is also a cleaner that is lower cost than using alcohol to clean electronics products. Several workers in Chinese electronics factories have been poisoned by n-Hexane in recent years.[108][109][110][111]

Endogenous neurotoxin sources

Unlike most common sources of neurotoxins which are acquired by the body through ingestion, endogenous neurotoxins both originate from and exert their effects in-vivo. Additionally, though most venoms and exogenous neurotoxins will rarely possess useful in-vivo capabilities, endogenous neurotoxins are commonly used by the body in useful and healthy ways, such as nitric oxide which is used in cell communication.[112] It is often only when these endogenous compounds become highly concentrated that they lead to dangerous effects.[10]

Nitric oxide

Though nitric oxide (NO) is commonly used by the nervous system in inter-neuron communication and signaling, it can be active in mechanisms leading to ischemia in the cerebrum (Iadecola 1998). The neurotoxicity of NO is based on its importance in glutamate excitotoxicity, as NO is generated in a calcium-dependent manner in response to glutamate mediated NMDA activation, which occurs at an elevated rate in glutamate excitotoxicity.[47] Though NO facilitates increased blood flow to potentially ischemic regions of the brain, it is also capable of increasing oxidative stress,[113] inducing DNA damage and apoptosis.[114] Thus an increased presence of NO in an ischemic area of the CNS can produce significantly toxic effects.


Glutamate, like nitric oxide, is an endogenously produced compound used by neurons to perform normally, being present in small concentrations throughout the gray matter of the CNS.[10] One of the most notable uses of endogenous glutamate is its functionality as an excitatory neurotransmitter.[48] When concentrated, however, glutamate becomes toxic to surrounding neurons. This toxicity can be both a result of direct lethality of glutamate on neurons and a result of induced calcium flux into neurons leading to swelling and necrosis.[48] Support has been shown for these mechanisms playing significant roles in diseases and complications such as Huntington’s disease, epilepsy, and stroke.[10]

Cited references

  1. Sivonen K (1999
  2. Scottish Government 2011
  3. Online Etymological Dictionary: Neuro-
  4. Online Etymological Dictionary: Toxic
  5. 5.0 5.1 Spencer 2000
  6. 6.0 6.1 Olney 2002
  7. 7.0 7.1 7.2 7.3 7.4 7.5 7.6 7.7 Kiernan 2005
  8. Lidsky 2003
  9. 9.0 9.1 9.2 Heaton 2000
  10. 10.0 10.1 10.2 10.3 Choi 1987
  11. Zhang 1994
  12. 12.0 12.1 Rosales 1996
  13. 13.0 13.1 Simpson 1986
  14. 14.0 14.1 14.2 Arnon 2001
  15. Dikranian 2001
  16. Deng 2003
  17. Jevtovic-Todorovic 2003
  18. Nadler 1978
  19. 19.0 19.1 19.2 19.3 Thyagarajan 2009
  20. 20.0 20.1 Takadera 1990
  21. Hodge 2002
  22. 22.0 22.1 Dobbs 2009
  23. 23.0 23.1 23.2 Widmaier 2008
  24. 24.0 24.1 Martini 2009
  25. 25.0 25.1 Costa 2011
  26. Harry 1998
  27. Gartlon 2006
  28. Mundy 2008
  29. Lotti 2005
  30. 30.0 30.1 30.2 Adams 2003
  31. 31.0 31.1 Brocardo 2011
  32. Lewendon 2001
  33. 33.0 33.1 Haghdoost-Yazdi 2011
  34. 34.0 34.1 DeBin 1993
  35. 35.0 35.1 Koller 1988
  36. McClesky 1987
  37. 37.0 37.1 Garcia-Rodriguez 2011
  38. 38.0 38.1 Williamson 1996
  39. 39.0 39.1 39.2 Dutrere 2006
  40. 40.0 40.1 Banks 1988
  41. 41.0 41.1 41.2 Aschner 1990
  42. 42.0 42.1 DeFuria 2006
  43. 43.0 43.1 Konopacka 2009
  44. 44.0 44.1 44.2 Bressler 1999
  45. 45.0 45.1 Lovinger 1989
  46. 46.0 46.1 Leonard 1986
  47. 47.0 47.1 Garthwaite 1988
  48. 48.0 48.1 48.2 Choi 1990
  49. 49.0 49.1 49.2 Chowdhury 2007
  50. Ahasan 2004
  51. Lau 1995
  52. Imredy JP, and MacKinnon R (2000). Energetic and Structural Interactions between delta-Dendrotoxin and a Voltage-gated Potassium Channel. J. Mol. Biol. 296:1283-1294
  53. 53.0 53.1 53.2 Standfield 1983
  54. Roed 1989
  55. Haghdoost-Yasdi 2011
  56. Deshane 2003
  57. Soroceanu 1998
  58. 58.0 58.1 Bisset 1992
  59. Schlesinger 1946
  60. Griffith 1942
  61. 61.0 61.1 Jacob 2010
  62. Olivera 1987
  63. Cruz 1986
  64. McCleskey 1987
  65. 65.0 65.1 Brin 1998
  66. Montecucco 1986
  67. 67.0 67.1 Pirazzini 2011
  68. King 1981
  69. Rabe 1982
  70. Walton 2006
  71. Chan 2011
  72. Brookes 1988
  73. Tsetlin 2003
  74. 74.0 74.1 Liu 2008
  75. Hue 2007
  76. Carmichael 1978
  77. Carmichael 1975
  78. Yang 2007
  79. Wood 2007
  80. National Center for Environmental Assessment
  81. Devlin 1977
  82. Moore 1977
  83. Metcalf 2009
  84. Stewart 2008
  85. Dixit 2005
  86. Liu 2009
  87. Vahidnia 2007
  88. 88.0 88.1 88.2 Rocha 2011
  89. Brender 2005
  90. DeFuria 2007
  91. 91.0 91.1 Matsuoka 1991
  92. Buzanska (2000)
  93. 93.0 93.1 Norenberg 2004
  94. 94.0 94.1 Lidskey 2003
  95. Bradbury 1993
  96. Lasley 1999
  97. Baum-Baicker 1985
  98. Taffe 2010
  99. Morris 2009
  100. Bleich 2003
  101. Blanco 2005
  102. Davis 1992
  103. Bernier 2011
  104. Jones 1973
  105. Mitchell 1999
  106. Gil-Mohapel 2010
  107. Bergamini 2004
  108. Workers poisoned while making iPhones ABC News, October 25, 2010
  109. Dirty Secrets ABC Foreign Correspondent, 2010-Oct-26
  110. Mr Daisey and the Apple Factory, This American Life, January 6, 2012
  111. Occupational Safety and Health Guideline for n-Hexane,
  112. Iadecola 1998
  113. Beckman 1990
  114. Bonfoco 1995


  • Adams, Michael E., and Baldomero M. Olivera (1994) "Neurotoxins: Overview of an Emerging Research Technology." Trends in Neuroscience, 17 (4): 151–55.
  • Ahasan, H A M N, A. A. Mamun, S. R. Karim, M. A. Baker, E. A. Gazi, and C. S. Bala (2004) "Paralytic Complications of Puffer Fish (Tetrodotoxin) Poisoning." Singapore Medical Journal, 73 (42.2): 73–74.
  • Arnon, Stephen S., Robert Schechter, Thomas V. Inglesby, Donald A. Henderson, John G. Bartlett, Michael S. Ascher, Edward Eitzen, Anne D. Fine, Jerome Hauer, Marcelle Layton, Scott Lillibridge, Michael T. Osterholm, Tara O'Toole, Gerald Parker, Trish M. Perl, Philip K. Russell, David L. Swerdlow, and Kevin Tonat (2001) "Botulinum Toxin as a Biological Weapon." The Journal of the Americal Medical Association, 285 (8): 1059–069.
  • Aschner, M., and J. Aschner (1990) "Mercury Neurotoxicity: Mechanisms of Blood-brain Barrier Transport." Neuroscience & Biobehavioral Reviews, 14 (2): 169–76.
  • Banks, William A., and Abba J. Kastin (1989) "Aluminum-Induced Neurotoxicity: Alterations in Membrane Function at the Blood-Brain Barrier." Neuroscience & Biobehavioral Reviews, 13: 47–53.
  • Baum-Baicker, Cynthia (1985) "The Health Benefits of Moderate Alcohol Consumption: A Review of the Literature." Drug and Alcohol Dependence, 15 (3): 207–27.
  • Beckman, J. S. (1990) "Apparent Hydroxyl Radical Production by Peroxynitrite: Implications for Endothelial Injury from Nitric Oxide and Superoxide." Proceedings of the National Academy of Sciences, 87 (4): 1620–624.
  • Bergamini, Carlo M., Stefani Gambetti, Alessia Dondi, and Carlo Cervellati (2004) "Oxygen, Reactive Oxygen Species and Tissue Damage." Current Pharmaceutical Design, 10 (14): 1611–626.
  • Bernier, Brian E., Leslie R. Whitaker, and Hitoshi Morikawa (2011) "Previous Ethanol Experience Enhances Synaptic Plasticity of NMDA Receptors in the Ventral Tegmental Area." The Journal of Neuroscience, 31.14: 5305–212.
  • Bisset, Norman G (1992) "War and Hunting Poisons of the New World. Part 1. Notes on the Early History of Curare." Journal of Ethnopharmacology, 36 (1): 1–26.
  • Blanco, Ana M., Soraya L. Valles, Maria Pascual, and Consuelo Guerri (2005) "Involvement of TLR4/Type I IL-1 Receptor Signaling in the Induction of Inflammatory Mediators and Cell Death Induced by Ethanol in Cultured Astrocytes." The Journal of Immunology, 175: 6893–899.
  • Bleich, S (2003) "Hyperhomocysteinemia as a New Risk Factor for Brain Shrinkage in Patients with Alcoholism." Neuroscience Letters, 335 (3): 179–82.
  • Bonfoco, E (1993) "Apoptosis and Necrosis: Two Distinct Events Induced, Respectively, by Mild and Intense Insults with N-Methyl-D-Aspartate or Nitric Oxide/Superoxide in Cortical Cell Cultures." Proceedings of the National Academy of Sciences 92.16 (1995): 7162–166.
  • Bradbury MW, Deane R. Permeability of the blood±brain barrier to lead. [Review]. Neurotoxicology, 14: 131–6.
  • Brender, J., L. Suarez, M. Felkner, Z. Gilani, D. Stinchcomb, K. Moody, J. Henry, and K. Hendricks (2006) "Maternal Exposure to Arsenic, Cadmium, Lead, and Mercury and Neural Tube Defects in Offspring." Environmental Research, 101 (1): 132–39.
  • Bressler J, Kim KA, Chakraborti T, Goldstein G (1999) Molecular mechanisms of lead neurotoxicity. [Review]. Neurochem Res, 24: 595–600.
  • Brin, Mitchell F (1997) "Botulinum Toxin: Chemistry, Pharmacology, Toxicity, and Immunology." Muscle & Nerve, 20 (S6): 146–68.
  • Brocardo, Patricia S., Joana Gil-Mohapel, and Brian R. Christie (2011) "The Role of Oxidative Stress in Fetal Alcohol Spectrum Disorders." Brain Research Reviews, 67 (1–2): 209–25.
  • Brookes, N (1988) "Specificity and Reversibility of the Inhibition by HgCl of Glutamate Transport in Astrocyte Cultures." Journal of Neurochemistry, 50 (4): 1117–122.
  • Buzanska, L., B. Zablocka, A. Dybel, K. Domanska-Janik, and J. Albrecht (2000) "Delayed Induction of Apoptosis by Ammonia in C6 Glioma Cells." Neurochemistry International, 37: 287–97.
  • Carmichael WW, Biggs DF, Gorham PR (1975). "Toxicology and pharmacological action of Anabaena flos-aquae toxin". Science 187 (4176): 542–544. DOI:10.1126/science.803708. PMID 803708. Research Blogging.
  • Carmichael WW, Gorham PR (1978). "Anatoxins from clones of Anabaena flos-aquae isolated from lakes of western Canada." Mitt. Infernal. Verein. Limnol". , 21: 285–295.
  • Chan, H. M. (2011) "Mercury in Fish: Human Health Risks." Encyclopedia of Environmental Health: 697–704.
  • Choi, D (1988) "Calcium-mediated Neurotoxicity: Relationship to Specific Channel Types and Role in Ischemic Damage." Trends in Neurosciences, 11 (10): 465–69.
  • Choi, D. W., and S. M. Rothman (1990) "The Role of Glutamate Neurotoxicity in Hypoxic-Ischemic Neuronal Death." Annual Review of Neuroscience, 13 (1): 171–82.
  • Choi, Dennis W (1987) "Ionic Dependence of Glutamate Neurotoxicity." The Journal of Neuroscience, 7 (2): 369–79.
  • Chowdhury, F. R., H A M. Nazmul Ahasan, A K M. Mamunur Rashid, A. Al Mamun, and S. M. Khaliduzzaman (2007) "Tetrodotoxin Poisoning: a Clinical Analysis, Role of Neostigmine and Short-term Outcome of 53 Cases." Singapore Medical Journal, 48 (9): 830–33.
  • Choi, Dennis W., Margaret Maulucci-Gedde, and Arnold R. Kriegstein (1987) "Glutamate Neurotoxicity in Cortical Cell Culture." The Journal of Neuroscience, 7 (2): 357–68.
  • Chu, Jennifer, Ming Tong, and Suzanne M. Monte (2007) "Chronic Ethanol Exposure Causes Mitochondrial Dysfunction and Oxidative Stress in Immature Central Nervous System Neurons." Acta Neuropathologica, 113 (6): 659–73.
  • Clancy, Barbara, Barbara L. Finlay, Richard B. Darlington, and K.j.s. Anand (2007) "Extrapolating Brain Development from Experimental Species to Humans." NeuroToxicology, 28 (5): 931–37.
  • Costa, Lucio G., Gennaro Giordano, and Marina Guizzetti (2011) In Vitro Neurotoxicology: Methods and Protocols. New York: Humana.
  • Coyle, Joseph T., and Robert Schwarcz. "Lesion of Striatal Neurons with Kainic Acid Provides a Model for Huntington's Chorea." Nature, 246: 244–46.
  • Cruz, Lourdes J., and Baldomero M. Olivera (1987) "Calcium Channel Antagonists ω-Conotoxin Defines a New High Affinity Site." The Journal of Biological Chemistry, 14 (261): 6230–233.
  • Davis, S., S. P. Butcher, and R. Morris (1992) "The NMDA Receptor Antagonist D-2-amino-5phosphonopentanoate (D-AP5) Impairs Spatial Learning and LTP in Vivo at Lntracerebral Concentrations Comparable to Those That Block LTP in Vitro." The Journal of Neuroscience, 12 (1): 21–34.
  • Dawson, V. L. (1991) "Nitric Oxide Mediates Glutamate Neurotoxicity in Primary Cortical Cultures." Proceedings of the National Academy of Sciences, 88 (14): 6368–371.
  • Debin, John A., John E. Maggio, and Gary R. Strichartz (1993) "Purification and Characterization of Chlorotoxin, a Chloride Channel Ligand from the Venom of the Scorpion." The American Physiological Society, pp. 361–69.
  • DeFuria, Jason, and Thomas B. Shea (2007) "Arsenic Inhibits Neurofilament Transport and Induces Perikaryal Accumulation of Phosphorylated Neurofilaments: Roles of JNK and GSK-3β." Brain Research, 1181: 74–82.
  • Defuria, Jason (2006) "The Environmental Neurotoxin Arsenic Impairs Neurofilament Dynamics by Overactivation of C-JUN Terminal Kinase: Potential Role for Amyotrophic Lateral Sclerosis." UMI, pp. 1–16.
  • Deng, Wenbin, and Ronald D. Poretz. "Oligodendroglia in Developmental Neurotoxicity." NeuroToxicology 24.2 (2003): 161–78.
  • Deshane, Jessy, Craig C. Garner, and Harald Sontheimer (2003) "Chlorotoxin Inhibits Glioma Cell Invasion via Matrix Metalloproteinase-2." The Journal of Biological Chemistry, 278 (6): 4135–144.
  • Devlin JP, Edwards OE, Gorham PR, Hunter NR, Pike RK, Stavric B (1977). "Anatoxin-a, a toxic alkaloid from Anabaena flos-aquae NRC-44h". Can. J. Chem. 55 (8): 1367–1371. DOI:10.1139/v77-189. Research Blogging.
  • Dikranian, K (2001) "Apoptosis in the in Vivo Mammalian Forebrain." Neurobiology of Disease, 8 (3): 359–79.
  • Dixit A, Dhaked RK, Alam SI, Singh L (2005). "Military potential of biological neurotoxins". Informa Healthcare 24 (2): 175–207. DOI:10.1081/TXR-200057850. Research Blogging.
  • Dobbs, Michael R (2009) Clinical Neurotoxicology. Philadelphia: Saunders-Elsevier.
  • Dutertre, S., and R. Lewis (2006) "Toxin Insights into Nicotinic Acetylcholine Receptors." Biochemical Pharmacology, 72 (6): 661–70.
  • Garcia-Rodriguez, C., I. N. Geren, J. Lou, F. Conrad, C. Forsyth, W. Wen, S. Chakraborti, H. Zao, G. Manzanarez, T. J. Smith, J. Brown, W. H. Tepp, N. Liu, S. Wijesuriya, M. T. Tomic, E. A. Johnson, L. A. Smith, and J. D. Marks (2011) "Response Re: 'Neutralizing Human Monoclonal Antibodies Binding Multiple Serotypes of Botulinum Neurotoxin' by Garcia-Rodriguez Et Al., PEDS, 2011;24:321–331." Protein Engineering Design and Selection, 24 (9): 633–34.
  • Garthwaite, John, Sarah L. Charles, and Russel Chess-Williams (1988) "Endothelim-derived Relaxing Factor Release on Activation of NMDA Receptors Suggests Role as Intercellular Messenger in the Brain." Nature, 336 (24): 385–88.
  • Gartlon, J., A. Kinsner, A. Balprice, S. Coecke, and R. Clothier (2006) "Evaluation of a Proposed in Vitro Test Strategy Using Neuronal and Non-neuronal Cell Systems for Detecting Neurotoxicity." Toxicology in Vitro, 20 (8): 1569–581.
  • Gil-Mohapel, Joana, Fanny Boehme, Leah Kainer, and Brian R. Christie (2010) "Hippocampal Cell Loss and Neurogenesis after Fetal Alcohol Exposure: Insights from Different Rodent Models." Brain Research Reviews, 64 (2): 283–303.
  • Griffith, Harold R., and G. Enid Johnson (1942) "The Use Of Curare In General Anesthesia." Anesthesiology, 3 (4): 418–420.
  • Haghdoost-Yazdi, Hashem, Ayda Faraji, Negin Fraidouni, Mohadeseh Movahedi, Elham Hadibeygi, and Fatemeh Vaezi (2011) "Significant Effects of 4-aminopyridine and Tetraethylammonium in the Treatment of 6-hydroxydopamine-induced Parkinson's Disease." Behavioural Brain Research, 223: 70–74.
  • Harry, G. J., Melvin Billingsley, Arendd Bruinink, Iain L. Campbell, Werner Classen, David C. Dorman, Corrado Galli, David Ray, Robert A. Smith, and Hugh A. Tilson (1998) "In Vitro Techniques for the Assessment of Neurotoxicity." Environmental Health Perspectives, 106: 131–58.
  • Häussinger, Dieter (2006) "Low Grade Cerebral Edema and the Pathogenesis of Hepatic Encephalopathy in Cirrhosis." Hepatology, 43 (6): 1187–190.
  • Heaton, Marieta Barrow, J. Jean Mitchell, and Michael Paiva (2000) "Amelioration of Ethanol-Induced Neurotoxicity in the Neonatal Rat Central Nervous System by Antioxidant Therapy." Alcoholism: Clinical and Experimental Research, 24 (4): 512–18.
  • Hensley, K. (1994) "A Model for β-Amyloid Aggregation and Neurotoxicity Based on Free Radical Generation by the Peptide: Relevance to Alzheimer Disease." Proceedings of the National Academy of Sciences, 91 (8): 3270–274.
  • Herbert, M. R. (2006) "Autism and Environmental Genomics." NeuroToxicology, pp. 671–84. Web.
  • Hodge, A. Trevor (2002) Roman Aqueducts and Water Supply. London: Duckworth.
  • How, C (2003) "Tetrodotoxin Poisoning." The American Journal of Emergency Medicine, 21 (1): 51–54.
  • Hue, Bernard, Steven D. Buckingham, David Buckingham, and David B. Sattelle (2007) "Actions of Snake Neurotoxins on an Insect Nicotinic Cholinergic Synapse." Invertebrate Neuroscience, 7 (3): 173–78.
  • Iadecola, Constantino (1997) "Bright and Dark Sides of Nitric Oxide in Ischemic Brain Injury." Trends in Neurosciences, 20 (3 : 132–39.
  • Jacob, Reed B., and Owen M. McDougal (2010) "The M-superfamily of Conotoxins: a Review." Cellular and Molecular Life Sciences, 67: 17–27.
  • Jevtovic-Todorovic, Vesna, Richard E. Hartman, Yukitoshi Izumi, Nicholas D. Benshoff, Krikor Dikranian, Charles F. Zorumski, John W. Olney, and David F. Wozniak (2003) "Early Exposure to Common Anesthetic Agents Causes Widespread Neurodegeneration in the Developing Rat Brain and Persistent Learning Deficits." The Journal of Neuroscience, 23 (3): 876–82.
  • Jones, K. (1973) "Pattern Of Malformation In Offspring Of Chronic Alcoholic Mothers." The Lancet, 301 (7815): 1267–271.
  • Kiernan, Matthew C., Geoffrey K. Isbister, Cindy S.-Y. Lin, David Burke, and Hugh Bostock (2005) "Acute Tetrodotoxin-induced Neurotoxicity after Ingestion of Puffer Fish." Annals of Neurology, 57 (3): 339–48.
  • King, Steven W., John Savory, Michael R. Wills, and H. J. Gitelman (1981) "The Clinical Biochemistry of Aluminum." Critical Reviews in Clinical Laboratory Sciences, 14 (1): 1–20.
  • Konopacka, Agnieszka, Filip A. Konopacki, and Jan Albrecht (2009) "Protein Kinase G Is Involved in Ammonia-induced Swelling of Astrocytes." Journal of Neurochemistry, 109: 246–51.
  • Lafon-Cazal, Mireille, Sylvia Pietri, Marcel Culcasi, and Joel Bockaert (1993) "NMDA-dependent Superoxide Production and Neurotoxicity." Nature, 364 (6437): 535–37.
  • Lasley SM, Green MC, Gilbert ME (1999) "Influence of exposure period on in vivo hippocampal glutamate and GABA release in rats chronically exposed to lead." Neurotoxicology, 20: 619–29.
  • Lau, F. L., C. K. Wong, and S. H. Yip (1995) "Puffer Fish Poisoning." Emergency Medicine Journal, 12 (3): 214–15.
  • Leonard, B. E. (1986) "Is Ethanol a Neurotoxin?: the Effects of Ethanol on Neuronal Structure and Function." Alcohol and Alcoholism, 21 (4): 325–38.
  • Lewendon, G., S. Kinra, R. Nelder, and T. Cronin (2001) "Should Children with Developmental and Behavioural Problems Be Routinely Screened for Lead?" Archives of Disease in Childhood, 85: 286–88.
  • Lidsky, Theodore I. (2003) "Lead Neurotoxicity in Children: Basic Mechanisms and Clinical Correlates." Oxford Journals. Online.
  • Liu, Kuang-Kai, Mei-Fang Chen, Po-Yi Chen, Tony J F. Lee, Chia-Liang Cheng, Chia-Ching Chang, Yen-Peng Ho, and Jui-I Chao (2010) "Alpha-bungarotoxin Binding to Target Cell in a Developing Visual System by Carboxylated Nanodiamond." Nanotechnology, 19 (20): 205102.
  • Liu, Yuan, Suzanne McDermott, Andrew Lawson, and C. Marjorie Aelion (2010) "The Relationship between Mental Retardation and Developmental Delays in Children and the Levels of Arsenic, Mercury and Lead in Soil Samples Taken near Their Mother’s Residence during Pregnancy." International Journal of Hygiene and Environmental Health, 213 (2): 116–23.
  • Lorenzo, A. (1994) " β-Amyloid Neurotoxicity Requires Fibril Formation and Is Inhibited by Congo Red." Proceedings of the National Academy of Sciences, 91 (25): 12243–2247.
  • Lotti, Marcello, and Angelo Moretto (1989) "Organophosphate-Induced Delayed Polyneuropathy." Toxicological Reviews, 24 (1) (2005): 37–49.
  • Lovinger, D., G. White, and F. Weight. "Ethanol Inhibits NMDA-activated Ion Current in Hippocampal Neurons." Science, 243 (4899): 1721–724.
  • Martinez-Finley, Ebany J., Samantha L. Goggin, Matthew T. Labrecque, and Andrea M. Allan (2011) "Reduced Expression of MAPK/ERK Genes in Perinatal Arsenic-exposed Offspring Induced by Glucocorticoid Receptor Deficits." Neurotoxicology and Teratology, 33 (5): 530–37.
  • Martini, Frederic, Michael J. Timmons, and Robert B. Tallitsch (2009) Human Anatomy. San Francisco: Pearson/Benjamin Cummings.
  • Matsuoka, Masato, Hideki Igisu, Kazuaki Kohriyama, and Naohide Inoue (1991) "Suppression of Neurotoxicity of Ammonia by L-carnitine." Brain Research, 567 (2): 328–31.
  • McCleskey, E. W. (1987) "Omega-conotoxin: Direct and Persistent Blockade of Specific Types of Calcium Channels in Neurons but Not Muscle." Proceedings of the National Academy of Sciences, 84 (12): 4327–331.
  • Meldrum, B., and J. Garthwaite (1990) "Excitatory Amino Acid Neurotoxicity and Neurodegenerative Disease." Trends in Pharmacological Sciences, 11 (9): 379–87.
  • Metcalf JS and Codd GA (2009) "Cyanobacteria, neurotoxins and water resources: Are there implications for human neurodegenerative disease?" Informa Healthcare, 10(s2): 74–78.
  • Mitchell, J.Jean, Michael Paiva, and Marieta Barrow Heaton (1999) "The Antioxidants Vitamin E and β-Carotene Protect Against Ethanol-Induced Neurotoxicity in Embryonic Rat Hippocampal Cultures." Alcohol, 17 (2): 163–68.
  • Moore RE (1977). "Toxins from blue-green algae". BioScience 27 (12): 797–802. DOI:10.2307/1297756. Research Blogging.
  • Montecucco, C. (1986) "How Do Tetanus and Botulinum Toxins Bind to Neuronal Membranes?"Trends in Biochemical Sciences 11.8: 314–17.
  • Morris, Stephanie A., David W. Eaves, Aleksander R. Smith, and Kimberly Nixon (2009) "Alcohol Inhibition of Neurogenesis: A Mechanism of Hippocampal Neurodegeneration in an Adolescent Alcohol Abuse Model." Hippocampus: NA.
  • Nadler, J. Victor, Bruce W. Perry, and Carl W. Cotman (1978) "Intraventricular Kainic Acid Preferentially Destroys Hippocampal Pyramidal Cells." Nature, 271 (5646): 676–77.
  • National Center for Environmental Assessment. "Toxicological Reviews of Cyanobacterial Toxins: Anatoxin-a" NCEA-C-1743
  • Norenberg, M. D., K. V. Rama Rao, and A. R. Jayakumar (2004) "Ammonia Neurotoxicity and the Mitochondrial Permeability Transition." Journal of Bioenergetics and Biomembranes, 36 (4): 303–07.
  • Olivera, Baldomero M., Lourdes J. Cruz, Victoria De Santos, Garth LeCheminant, David Griffin, Regina Zeikus, J. Michael McIntosh, Robert Galyean, and Janos Varga (1987) "Neuronal Calcium Channel Antagonists. Discrimination between Calcium Channel Subtypes Using .omega.-conotoxin from Conus Magus Venom." Biochemistry, 26 (8): 2086–090.
  • Olney, John W. (2002) "New Insights and New Issues in Developmental Neurotoxicology." NeuroToxicology, 23 (6): 659–68.
  • Pirazzini, Marco, Ornella Rossetto, Paolo Bolognese, Clifford C. Shone, and Cesare Montecucco (2011) "Double Anchorage to the Membrane and Intact Inter-chain Disulfide Bond Are Required for the Low PH Induced Entry of Tetanus and Botulinum Neurotoxins into Neurons." Cellular Microbiology: No. Print.
  • Rabe, Ausma, Moon He Lee, Judy Shek, and Henryk M. Wisniewski (1982) "Learning Deficit in Immature Rabbits with Aluminum-induced Neurofibrillary Changes." Experimental Neurology, 76 (2): 441–46.
  • Radio, Nicholas M., and William R. Mundy (2008) "Developmental Neurotoxicity Testing in Vitro: Models for Assessing Chemical Effects on Neurite Out-growth." NeuroToxicology, 29: 361–276.
  • Rocha, R. A., J. V. Gimeno-Alcaniz, Raymond Martín–Ibanez, J. M. Canals, D. Vélez, and V. Devesa (2011) "Arsenic and Fluoride Induce Neural Progenitor Cell Apoptosis." Toxicology Letters, 203: 237–44.
  • Roed, A. (1989) "The Effects of Tetraethylammonium during Twitch and Tetanic Stimulation of the Phrenic Nerve Diaphragm Preparation in the Rat." Neuropharmacology, 28 (6): 585–92.
  • Rosales, Raymond L., Kimiyoshi Arimura, Satoshi Takenaga, and Mitsuhiro Osame (1996) "Extrafusal and Intrafusal Muscle Effects in Experimental Botulinum Toxin-A Injection." Muscle & Nerve, 19 (4): 488–96.
  • Rothman, S., J. Thurston, and R. Hauhart (1987) "Delayed Neurotoxicity of Excitatory Amino Acids In Vitro." Neuroscience, 22 (2): 471–80.
  • Schlesinger, Edward B. (1946) "Curare A Review of Its Therapeutic Effects and Their Physiological Basis." The American Journal of Medicine, 1 (5): 518–30.
  • Scottish Government Blue-Green Algae (Cyanobacteria) in Inland Waters: Assessment and Control of Risks to Public Health Retrieved 15 December 2011.
  • Siebler, M., H. Koller, C. Schmalenbach, and H. Muller (1988) "GABA Activated Chloride Currents in Cultured Rat Hippocampal and Septal Region Neurons Can Be Inhibited by Curare and Atropine." Neuroscience Letters, 93 (2–3): 220–24.
  • Simpson, L. L. (1986) "Molecular Pharmacology of Botulinum Toxin and Tetanus Toxin." Annual Review of Pharmacology and Toxicology, 26 (1): 427–53.
  • Sivonen K (1999) "Toxins produced by cyanobacteria" Vesitalous, 5: 11–18.
  • Soroceanu, Liliana, Yancey Gillespie, M. B. Khazaeli, and Harold Sontheimer (1998) "Use of Chlorotoxin for Targeting of Primary Brain Tumors." Cancer Research, 58: 4871–879
  • Spencer PS, Schaumburg HH, Ludolph AC (Eds) (2000) Experimental and Clinical Neurotoxicology. Oxford University Press, Oxford, pp. 1310.
  • Stanfield, Peter R (1983) "Tetraethylammonium Ions and the Potassium Permeability of Excitable Cells." Reviews of Physiology, Biochemistry & Pharmacology, 97: 1–49.
  • Stewart I, Seawright AA, Shaw GR (2008). "Cyanobacterial poisoning in livestock, wild mammals and birds – an overview" (PDF). Cyanobacterial Harmful Algal Blooms: State of the Science and Research Needs 619: 613–637. DOI:10.1007/978-0-387-75865-7_28. Research Blogging.
  • Taffe, M. A., R. W. Kotzebue, R. D. Crean, E. F. Crawford, S. Edwards, and C. D. Mandyam (2010) "From the Cover: Long-lasting Reduction in Hippocampal Neurogenesis by Alcohol Consumption in Adolescent Nonhuman Primates." Proceedings of the National Academy of Sciences, 107 (24): 11104–1109.
  • Takadera, Tsuneo, Risa Suzuki, and Tetsuro Mohri (1990 "Protection by Ethanol of Cortical Neurons from N-methyl-d-aspartate-induced Neurotoxicity Is Associated with Blocking Calcium Influx." Brain Research, 537(1–2): 109–14.
  • Thyagarajan, B., N. Krivitskaya, J. G. Potian, K. Hognason, C. C. Garcia, and J. J. McArdle (2009) "Capsaicin Protects Mouse Neuromuscular Junctions from the Neuroparalytic Effects of Botulinum Neurotoxin A." Journal of Pharmacology and Experimental Therapeutics, 331 (2): 361–71.
  • Tymianski, Michael, Milton P. Charlton, Peter L. Carlen, and Charles H. Tator (2003) "Source Specificity of Early Calcium Neurotoxicity in Cultured Embryonic Spinal Neurons." The Journal of Neuroscience, 13 (5): 2095–104.
  • Tsetlin, V.I, and F. Hucho (2004) "Snake and Snail Toxins Acting on Nicotinic Acetylcholine Receptors: Fundamental Aspects and Medical Applications." FEBS Letters, 557 (1–3): 9–13.
  • USEPA (United States Environmental Protection Agency) (1998) Health Effects Test Guidelines. OPPTS 870.6200. Neurotoxicity screening battery. Washington DC, USEPA.
  • Vahidnia, A., G.B. Van Der Voet, and F.A. De Wolff (2007) "Arsenic Neurotoxicity A Review." Human & Experimental Toxicology, 26 (10) : 823–32.
  • Walton, J. (2006) "Aluminum in Hippocampal Neurons from Humans with Alzheimer's Disease." NeuroToxicology, 27 (3): 385–94.
  • Widmaier, Eric P., Hershel Raff, Kevin T. Strang, and Arthur J. Vander (2008) Vander's Human Physiology: the Mechanisms of Body Function.' Boston: McGraw-Hill Higher Education.
  • Williamson, Lura C., Jane L. Halpern, Cesare Montecucco, J. E. Brown, and Elaine A. Neale (1996) "Clostridial Neurotoxins and Substrate Proteolysis in Intact Neurons." The Journal of Biological Chemistry, 271 (13): 7694–699.
  • Wood S. A., Rasmussen J. P., Holland P. T., Campbell R., Crowe A. L. M. (2007). "First Report of the Cyanotoxin Anatoxin-A from Aphanizomenon issatschenkoi (cyanobacteria)". Journal of Phycology 43 (2): 356–365. DOI:10.1111/j.1529-8817.2007.00318.x. Research Blogging.
  • Yamada, Kiyofumi, Tomoko Tanaka, Daiken Han, Kouji Senzaki, Tsutomu Kameyama, and Toshitaka Nabeshima (1999) "Protective Effects of Idebenone and α-tocopherol on β-amyloid-(1–42)-induced Learning and Memory Deficits in Rats: Implication of Oxidative Stress in β-amyloid-induced Neurotoxicity In vivo." European Journal of Neuroscience, 11 (1): 83–90.
  • Yan, Shi Du, Xi Chen, Jin Fu, Ming Chen, Huaijie Zhu, Alex Roher, Timothy Slattery, Lei Zhao, Mariko Nagashima, John Morser, Antonio Migheli, Peter Nawroth, David Stern, and Ann Marie Schmidt (1996) "RAGE and Amyloid-β Peptide Neurotoxicity in Alzheimer's Disease." Nature, 382 (6593): 685–91.
  • Yang, X (2007) Occurrence of the cyanobacterial neurotoxin, anatoxin-a, in New York State waters ProQuest. ISBN 978-0-549-35451-2.
  • Zhang, J., V. Dawson, T. Dawson, and S. Snyder (1994) "Nitric Oxide Activation of Poly(ADP-ribose) Synthetase in Neurotoxicity." Science, 263 (5147): 687–89.