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+ | Link to presentation: https://docs.google.com/a/mcmaster.ca/presentation/d/1dW15LKA4tzy2A1yKkckc6njZKW-URDgH05njQZ8UVXI/edit?usp=sharing | ||
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====== Introduction ====== | ====== Introduction ====== | ||
Epilepsy is a chronic condition that affects the central nervous system and is characterized by a disruption in the normal functioning of neuronal signaling and activity. Epilepsy is characterized by the presence of unprovoked or spontaneously recurring epileptic seizures ranging in severity and occur within a short span of time. There is often no immediately identifiable trigger for epileptic seizures and two or more seizures occurring within a span of 24 hours is considered an isolated event. Seizures that occur during the neonatal period of life, and acute symptomatic seizures linked to substance abuse are not considered epileptic. (Banerjee, Filippi, & Hauser, 2009) (Scharfman, 2007). The spectrum of epileptic seizures range from a lapse in concentration to unconsciousness with regards to severity. In addition, the World Health Organization defines epilepsy as a prevalent and major health concern world wide, and statistics show that over 50 million individuals world-wide present the disorder (World Health Organization, 2015). | Epilepsy is a chronic condition that affects the central nervous system and is characterized by a disruption in the normal functioning of neuronal signaling and activity. Epilepsy is characterized by the presence of unprovoked or spontaneously recurring epileptic seizures ranging in severity and occur within a short span of time. There is often no immediately identifiable trigger for epileptic seizures and two or more seizures occurring within a span of 24 hours is considered an isolated event. Seizures that occur during the neonatal period of life, and acute symptomatic seizures linked to substance abuse are not considered epileptic. (Banerjee, Filippi, & Hauser, 2009) (Scharfman, 2007). The spectrum of epileptic seizures range from a lapse in concentration to unconsciousness with regards to severity. In addition, the World Health Organization defines epilepsy as a prevalent and major health concern world wide, and statistics show that over 50 million individuals world-wide present the disorder (World Health Organization, 2015). | ||
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{{::focalseizures.png|}} | {{::focalseizures.png|}} | ||
- | Figure: visual representation of partial, primary and secondary generalized seizures. | + | **Figure 2**: visual representation of partial, primary and secondary generalized seizures. |
**Describing Awareness** | **Describing Awareness** | ||
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{{ :classification.png |}} | {{ :classification.png |}} | ||
- | **Figure _**: Revised seizure classification system developed by the International League Against Epilepsy | + | **Figure 3**: Revised seizure classification system developed by the International League Against Epilepsy |
Moreover, epileptic seizures vary in severity and duration, usually lasting seconds or mintues but have the potential to continue beyond normal time frames. Regardless, notable symptoms associated with epileptic seizures include: | Moreover, epileptic seizures vary in severity and duration, usually lasting seconds or mintues but have the potential to continue beyond normal time frames. Regardless, notable symptoms associated with epileptic seizures include: | ||
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====== EEG patterns and behaviour ====== | ====== EEG patterns and behaviour ====== | ||
- | Electroencephalogram (EEGs) is a diagnostic test conducted to detect any irregularities in neuronal activity in the brain. There 5 main types of EEG rhythms, each associated with different states of consciousness (refer to Figure_). Beta rhythms occur during thinking and wakeful periods and are characterized by low amplitudes and high frequencies. This pattern is due to the complex firing of neurons needed for thinking. There are many inputs being processed simultaneously and these signals can be excitatory and inhibitory (Bear, 2007). However, when they fired asynchronously the waves destructively interfere and cancel each other out, leading to low amplitudes. Delta and Theta rhythms fire during deep sleep periods and are characterized by high amplitudes and low frequencies. When there is no real active processes occurring, firing is controlled by the thalamus which is regarded as the rhythmic pace maker in the brain. These neurons fire synchronously and constructively interfere with each other leading to the superimposition of brain waves (Bear, 2007). | + | Electroencephalogram (EEGs) is a diagnostic test conducted to detect any irregularities in neuronal activity in the brain. There 5 main types of EEG rhythms, each associated with different states of consciousness (refer to Figure 4). Beta rhythms occur during thinking and wakeful periods and are characterized by low amplitudes and high frequencies. This pattern is due to the complex firing of neurons needed for thinking. There are many inputs being processed simultaneously and these signals can be excitatory and inhibitory (Bear, 2007). However, when they fired asynchronously the waves destructively interfere and cancel each other out, leading to low amplitudes. Delta and Theta rhythms fire during deep sleep periods and are characterized by high amplitudes and low frequencies. When there is no real active processes occurring, firing is controlled by the thalamus which is regarded as the rhythmic pace maker in the brain. These neurons fire synchronously and constructively interfere with each other leading to the superimposition of brain waves (Bear, 2007). |
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- | Figure _: EEG rhythms and associated behaviours. Beta waves occur during thinking periods and are characterized by low amplitudes. Delta waves occur during sleeping periods and are characterized by larder amplitudes. | + | **Figure 4**: EEG rhythms and associated behaviours. Beta waves occur during thinking periods and are characterized by low amplitudes. Delta waves occur during sleeping periods and are characterized by larder amplitudes. |
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{{:eeg.png?300|}} | {{:eeg.png?300|}} | ||
- | Figure_: EEG recording field potential in pyramidal cells. | + | **Figure 5**: EEG recording field potential in pyramidal cells. |
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**Action Potentials** | **Action Potentials** | ||
- | Neurons communicate with each other through the release of neurotransmitters into the synaptic cleft to elicit an excitatory or inhibitory effect. The release of these neurotransmitters is regulated by fluctuations in the axon membrane potential. There are two main channels that are located on axon membrane; one being sensitive to Na+ ions and the other K+ ions. These channels are referred to as voltage gated because their activation is dependent on membrane potential (Purves, 2012). In the presence of a stimulus, the resting membrane potential (-70mV) begins to depolarize through the activation of Na+ voltage gated channels which allows the influx of Na+ ions. Once the membrane potential has crossed the threshold of excitation (-50mV) an action potential is guaranteed (Purves, 2012). The axon continues to depolarize until it peaks (+50mV), at this point the inactivation gate on the Na+ channel closes preventing an Na+ influx. Since voltage gated K+ channels activate in response to depolarization the channels open causing an efflux of K+ ions and a decrease of membrane potential (Purves, 2012). Voltage gated K+ channels are less sensitive to polarization so often times the channels stay open even after resting membrane potential has been reached, which leads to hyperpolarization. The K+ channels eventually close and the cell is able to return to its resting membrane potential. The action potential moves throughout the axon until it reaches the presynaptic terminal. The depolarization causes voltage gated Ca2+ channels to open leading to an influx of Ca2+ ions. The influx of Ca2+ ions leads to further depolarization and the fusing of neurotransmitter vesicles with the presynaptic membrane (Purves, 2012). Attached to the vesicle membrane are SNARE complexes made up of Synaptobrevin protein and Synaptotagmin. The presynaptic membranes also have a SNARE complex made up of Syntaxin and SNAP-25. These bind to the Synaptobrevin from the vesicle. The influx of Ca2+ ions bind onto the vesicle Synaptotagmin subunit which allows the fusing of the vesicle with the membrane and finally the release of neurotransmitters into the synaptic cleft (Purves, 2012). | + | Neurons communicate with each other through the release of neurotransmitters into the synaptic cleft to elicit an excitatory or inhibitory effect. The release of these neurotransmitters is regulated by fluctuations in the axon membrane potential. There are two main channels that are located on axon membrane; one being sensitive to Na+ ions and the other K+ ions. These channels are referred to as voltage gated because their activation is dependent on membrane potential (Purves, 2012). Refer to Figure 6 for the following explanation on action potential: 1-2) In the presence of a stimulus, the resting membrane potential (-70mV) begins to depolarize through the activation of Na+ voltage gated channels which allows the influx of Na+ ions. Once the membrane potential has crossed the threshold of excitation (-50mV) an action potential is guaranteed (Purves, 2012). 3) The axon continues to depolarize until it peaks (+50mV), at this point the inactivation gate on the Na+ channel closes preventing an Na+ influx. 4) Since voltage gated K+ channels activate in response to depolarization the channels open causing an efflux of K+ ions and a decrease of membrane potential (Purves, 2012). 5) Voltage gated K+ channels are less sensitive to polarization so often times the channels stay open even after resting membrane potential has been reached, which leads to hyperpolarization. 6) The K+ channels eventually close and the cell is able to return to its resting membrane potential. The action potential moves throughout the axon until it reaches the presynaptic terminal. The depolarization causes voltage gated Ca2+ channels to open leading to an influx of Ca2+ ions. The influx of Ca2+ ions leads to further depolarization and the fusing of neurotransmitter vesicles with the presynaptic membrane (Purves, 2012). Attached to the vesicle membrane are SNARE complexes made up of Synaptobrevin protein and Synaptotagmin (refer to Figure 7). The presynaptic membranes also have a SNARE complex made up of Syntaxin and SNAP-25. These bind to the Synaptobrevin from the vesicle. The influx of Ca2+ ions bind onto the vesicle Synaptotagmin subunit which allows the fusing of the vesicle with the membrane and finally the release of neurotransmitters into the synaptic cleft (Purves, 2012). |
{{:action_potential_ap_.png|}} | {{:action_potential_ap_.png|}} | ||
- | Figure _: The steps of action potential | + | **Figure 6**: The steps of action potential |
{{:snare_pic.png|}} | {{:snare_pic.png|}} | ||
- | Figure _: Mechanisms of vesicle fusion with axonal membrane leading to the release of neurotransmitters | + | **Figure 7:** Mechanisms of vesicle fusion with axonal membrane leading to the release of neurotransmitters |
**Excitatory Neurotransmission** | **Excitatory Neurotransmission** | ||
- | The brain’s primary excitatory neurotransmitter is glutamate. The influx of Ca2+ following depolarization of the terminal axon prompts vesicles to release glutamate into the synaptic cleft where it can bind either NMDA (N-methyl-D-aspartate) or non-NMDA (kainate and AMPA) receptors (Stafstrom, 1998). The binding of glutamate to non-NMDA receptors causes the influx of Na+ into the post synaptic neuron via the rector’s pore. This brings the membrane potential inside the postsynaptic neuron closer to firing threshold and is called an excitatory postsynaptic potential (EPSP). Non-NMDA receptors mediate a fast-EPSP, which is often followed by an action potential once firing threshold is reached. To activate a NMDA receptor, glutamate must bind to the NMDA receptor, a glycine co-agonist must bind to the NMDA receptor complex and a Mg2+ ion that blocks the channel pore of the NMDA receptor complex must be expelled (Stafstrom, 1998). At resting membrane potential the Mg2+ ion blocks the pore and prevents the influx of ions into the postsynaptic neuron. Once the postsynaptic neuron has been depolarized by a non-NMDA mediated fast-EPSP the Mg2+ ion is relieved, permitting the flow of Na+ and Ca2+ into the postsynaptic neuron, this results in a NMDA-mediated prolonged-EPSP. During the longer NMDA-mediated depolarization several action potential may fire (Stafstrom, 1998). | + | The brain’s primary excitatory neurotransmitter is Glutamate. The influx of Ca2+ following depolarization of the terminal axon prompts vesicles to release Glutamate into the synaptic cleft where it can bind either NMDA (N-methyl-D-aspartate) or non-NMDA (kainate and AMPA) receptors (Stafstrom, 1998). The binding of Glutamate to non-NMDA receptors causes the influx of Na+ into the post synaptic neuron via the rector’s pore. This brings the membrane potential inside the postsynaptic neuron closer to firing threshold and is called an excitatory postsynaptic potential (EPSP). Non-NMDA receptors mediate a fast-EPSP, which is often followed by an action potential once firing threshold is reached. To activate a NMDA receptor, Glutamate must bind to the NMDA receptor, a glycine co-agonist must bind to the NMDA receptor complex and a Mg2+ ion that blocks the channel pore of the NMDA receptor complex must be expelled (Stafstrom, 1998). At resting membrane potential the Mg2+ ion blocks the pore and prevents the influx of ions into the postsynaptic neuron. Once the postsynaptic neuron has been depolarized by a non-NMDA mediated fast-EPSP the Mg2+ ion is relieved, permitting the flow of Na+ and Ca2+ into the postsynaptic neuron, this results in a NMDA-mediated prolonged-EPSP. During the longer NMDA-mediated depolarization several action potential may fire (Stafstrom, 1998). |
{{ :excite.png |}} | {{ :excite.png |}} | ||
- | **Figure_**: Glutamate is released from the presynaptic neuron into the synaptic cleft and binds to either a NMDA or non-NMDA receptor on the postsynaptic neuron. This allows positive ions to move into the postsynaptic neuron and causes either a prolonged-EPSP or a fast-EPSP. | + | **Figure 8**: Glutamate is released from the presynaptic neuron into the synaptic cleft and binds to either a NMDA or non-NMDA receptor on the postsynaptic neuron. This allows positive ions to move into the postsynaptic neuron and causes either a prolonged-EPSP or a fast-EPSP. |
**Inhibitory Neurotransmission** | **Inhibitory Neurotransmission** | ||
- | The brain’s primary inhibitory neurotransmitter is gamma-amino-butyric acid (GABA). Glucose is the primary precursor of GABA, but it can also be produced from pyruvate and glutamine. Tricarboxylic acid cycle enzymes convert glucose to glutamate which is then converted to GABA via glutamic acid decarboxylase (GAD). GABA is eventually degraded into succinate by GABA transaminase and is free to enter the Krebs cycle (Purves, 2012). The influx of Ca2+ following the depolarization of the terminal axon causes vesicles to release GABA into the synaptic cleft. Once GABA is in the synaptic cleft it can bind to three receptors: GABA-A, GABA-C, GABA-B. The former two are ionotropic receptors and therefore, the activation of these two receptors leads to an influx of Cl-, which inhibits postsynaptic neurons. Receptor GABA-B is a G-coupled protein, therefore when GABA binds to the receptor it activates the G-subunit of the receptor. Stimulation of the G-protein subunit leads to the recruitment of secondary messengers to activate downstream ion channels. In the case of GABA-B, downstream K+ channels are activated so K+ flows out of the neuron and Ca2+ channels are blocked so they cannot flow into the neuron, resulting in hyperpolarization of the postsynaptic neuron (Treiman, 2001). Essentially, the binding of GABA to any of its respective receptors results in a greater negative charge inside the postsynaptic neuron, this change in membrane potential is called an inhibitory postsynaptic potential (IPSP), which reduces the firing frequency of a neuron by keeping the membrane potential away from firing threshold (Stafstrom, 1998). | + | The brain’s primary inhibitory neurotransmitter is Gamma-Amino-Butyric Acid (GABA). Glucose is the primary precursor of GABA, but it can also be produced from pyruvate and glutamine. Tricarboxylic Acid Cycle enzymes convert glucose to Glutamate which is then converted to GABA via Glutamic Acid Decarboxylase (GAD). GABA is eventually degraded into succinate by GABA transaminase and is free to enter the Krebs cycle (Purves, 2012). The influx of Ca2+ following the depolarization of the terminal axon causes vesicles to release GABA into the synaptic cleft. Once GABA is in the synaptic cleft it can bind to three receptors: GABA-A, GABA-C, GABA-B. The former two are ionotropic receptors and therefore, the activation of these two receptors leads to an influx of Cl-, which inhibits postsynaptic neurons. Receptor GABA-B is a G-coupled protein. When GABA binds to the receptor it activates the G-subunit of the receptor. Stimulation of the G-protein subunit leads to the recruitment of secondary messengers to activate downstream ion channels. In the case of GABA-B, downstream K+ channels are activated so K+ flows out of the neuron and Ca2+ channels are blocked so they cannot flow into the neuron, resulting in hyperpolarization of the postsynaptic neuron (Treiman, 2001). Essentially, the binding of GABA to any of its respective receptors results in a greater negative charge inside the postsynaptic neuron, this change in membrane potential is called an Inhibitory Postsynaptic Potential (IPSP), which reduces the firing frequency of a neuron by keeping the membrane potential away from firing threshold (Stafstrom, 1998). |
{{ :inhibit.png |}} | {{ :inhibit.png |}} | ||
- | **Figure_**: GABA is released from the presynaptic neuron into the synaptic cleft and binds onto a GABA receptor on the postsynaptic neuron, this permits the influx of Cl- ions into the postsynaptic neuron and leads to an IPSP. | + | **Figure 9**: GABA is released from the presynaptic neuron into the synaptic cleft and binds onto a GABA receptor on the postsynaptic neuron, this permits the influx of Cl- ions into the postsynaptic neuron and leads to an IPSP. |
+ | |||
+ | ====== Brain Physiology ====== | ||
+ | |||
+ | The cortex is primarily composed of two types of neurons, principle and interneurons. Principle neurons output action potentials to distal neurons and are excitatory in nature. Interneurons make up the local circuit and influence neighbouring neurons and are inhibitory (Bromfield, 2008). Recurrent inhibition occurs when a principle neurons synapses on an interneuron, once the interneuron has been activated is can elicit an inhibitory effect on the principle cell creating a negative feedback loop. The instigation of seizure transpires when there is a sudden burst of excitatory activity in a discrete region of the cortex, example the thalamus, and expands to local regions. In order to establish seizure-like symptoms, there needs to be a high-frequency bursts of action potentials from the thalamus and the hyper-synchronization of principle cells (Bromfield, 2008). Each neuron will experience a paroxysmal depolarizing shift which can be characterized by a sustained depolarization (through the release of glutamate and the activation of Ca2+ and Na+ channels), followed by a hyperpolarization (through the opening of K+ channels and influx of Cl- ions via GABA). Propagation of an excitatory response and therefore spreading of seizure-like symptoms occur when this inhibitory response is lost. The loss of this hyperpolarization can occur for a number of reasons such as; a) due to the sustained depolarization, there is an increase in extracellular K+ which decreases the electrochemical gradient causing less of a K+ efflux, b) sustained depolarization leads to increased Ca2+ levels which leads to increased vesicle fusion and neurotransmitter release, c) depolarization leads to activation of excitatory NMDA R causing increased Ca2+ influx. Referring to Figure 10, it can be seen propagation of the seizure can be attributed to increased excitatory behaviour and diminished inhibition (Bromfield, 2008). | ||
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+ | {{::loss_of_hyperpol.png|}} | ||
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+ | **Figure 10**: Loss of hyper polarization leads to propagation of seizure. | ||
===== Pathophysiology of Epilepsy ===== | ===== Pathophysiology of Epilepsy ===== | ||
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During the second phase, there is both rapid and slower progressive changes. Rapid changes contain neuronal excitation and calcium influx, which triggers events that such as second messenger and immediate early gene responses, modifications to pre-existing proteins, and protein synthesis. Immediately, there is cell death and proliferation as well as inflammatory, glia, and vascular responses. Slower responses include growth such as; axon outgrowth, synaptogenesis, angiogenesis, leading to synaptic reorganization. Over a period of time, there is a growing increase in excitability, and thus the risk of a seizure increases. Therefore, genes, development, and the responses to the initial insult are likely to act together to result in a state of chronic seizures (Scharfman 2007) | During the second phase, there is both rapid and slower progressive changes. Rapid changes contain neuronal excitation and calcium influx, which triggers events that such as second messenger and immediate early gene responses, modifications to pre-existing proteins, and protein synthesis. Immediately, there is cell death and proliferation as well as inflammatory, glia, and vascular responses. Slower responses include growth such as; axon outgrowth, synaptogenesis, angiogenesis, leading to synaptic reorganization. Over a period of time, there is a growing increase in excitability, and thus the risk of a seizure increases. Therefore, genes, development, and the responses to the initial insult are likely to act together to result in a state of chronic seizures (Scharfman 2007) | ||
{{ :steps_of_epilepsy.png |}} | {{ :steps_of_epilepsy.png |}} | ||
+ | **Figure 11**: | ||
+ | |||
+ | |||
Abnormal synchronization of neurons in the brain results in an epileptic seizure. These seizure present various symptoms, which depend on the origin of the seizure and the connections in the brain. Seizure develop from either increased excitation or decreased inhibition (Moshé et al. 2015) | Abnormal synchronization of neurons in the brain results in an epileptic seizure. These seizure present various symptoms, which depend on the origin of the seizure and the connections in the brain. Seizure develop from either increased excitation or decreased inhibition (Moshé et al. 2015) | ||
{{ :2stepepi.png |}} | {{ :2stepepi.png |}} | ||
+ | |||
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+ | **Figure 12**: | ||
**Increased Excitability** | **Increased Excitability** | ||
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There are elevated levels of glutamate in the brain of patients with epilepsy, which is known as glutamate-induced excitotoxicity. Glutamate is normally degraded by an enzyme called glutamine synthetases (GS). However, GS has been shown to be deficient in patients with acquired epilepsy, also known as TLE. The GS deficiency causes high glutamate levels in astrocytes and in extracellular areas such as the synaptic cleft. This leads to prolonged effects of glutamate. Furthermore, GTL-1 is a major glutamate uptake molecule found in the brain, and its downregulation causes increased glutamate levels, leading to more excitability (Cho 2013). Glutamate itself and glutamate receptors, such as NMDA, cause high excitability as characterized in epilepsy. The cell death and tissue damage which occur in the initial stage of acquired epilepsy leads to the high concentrations of glutamate leakage into the extracellular space. Furthermore, tissue reorganization, occurring in epileptogenesis impairs high efficiency uptake of glutamate from the synaptic cleft. The decreased uptake of glutamate, allows for prolonged excitation of postsynaptic neurons (Brandford 1995). | There are elevated levels of glutamate in the brain of patients with epilepsy, which is known as glutamate-induced excitotoxicity. Glutamate is normally degraded by an enzyme called glutamine synthetases (GS). However, GS has been shown to be deficient in patients with acquired epilepsy, also known as TLE. The GS deficiency causes high glutamate levels in astrocytes and in extracellular areas such as the synaptic cleft. This leads to prolonged effects of glutamate. Furthermore, GTL-1 is a major glutamate uptake molecule found in the brain, and its downregulation causes increased glutamate levels, leading to more excitability (Cho 2013). Glutamate itself and glutamate receptors, such as NMDA, cause high excitability as characterized in epilepsy. The cell death and tissue damage which occur in the initial stage of acquired epilepsy leads to the high concentrations of glutamate leakage into the extracellular space. Furthermore, tissue reorganization, occurring in epileptogenesis impairs high efficiency uptake of glutamate from the synaptic cleft. The decreased uptake of glutamate, allows for prolonged excitation of postsynaptic neurons (Brandford 1995). | ||
{{ :glutame_epilepsy.png |}} | {{ :glutame_epilepsy.png |}} | ||
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+ | **Figure 13**: Sustained excitatory behaviour via glutamate release results in propagation of seizure. | ||
As mentioned before, voltage gated Na+ channels play a vital role in axon depolarization and therefore it can be assumed that dysregulation in their function can lead to epileptic symptoms. The voltage gated Na+ channels are composed of four homologous subunits (I-IV) and each subunit is composed of 6 transmembrane segments (Escayg, 2010). Subunits III and IV are connected by an intracellular loop which forms the inactivation gate. The channels are also connected to accessory beta units; 1, 2, 3, 4 which help modulate voltage dependence. Voltage gated Na+ channels are encoded by nine genes, SCN1A to SCN11A which gives rise to nine distinct channel isoforms. These isoforms differ in their location, ranging from CNS to embryonic heart muscle and also their threshold for activation. Mutations in these SNCA genes lead to increased frequency of depolarization of neurons and can even lead to excitotoxicity. For example, alterations in SCN1A and SCN2A lead to disorders such as genetic epilepsy with febrile seizures plus (Escayg, 2010). | As mentioned before, voltage gated Na+ channels play a vital role in axon depolarization and therefore it can be assumed that dysregulation in their function can lead to epileptic symptoms. The voltage gated Na+ channels are composed of four homologous subunits (I-IV) and each subunit is composed of 6 transmembrane segments (Escayg, 2010). Subunits III and IV are connected by an intracellular loop which forms the inactivation gate. The channels are also connected to accessory beta units; 1, 2, 3, 4 which help modulate voltage dependence. Voltage gated Na+ channels are encoded by nine genes, SCN1A to SCN11A which gives rise to nine distinct channel isoforms. These isoforms differ in their location, ranging from CNS to embryonic heart muscle and also their threshold for activation. Mutations in these SNCA genes lead to increased frequency of depolarization of neurons and can even lead to excitotoxicity. For example, alterations in SCN1A and SCN2A lead to disorders such as genetic epilepsy with febrile seizures plus (Escayg, 2010). | ||
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{{::na_channels_.png|}} | {{::na_channels_.png|}} | ||
- | Figure_: Visual representation of voltage gated Na+ channels, composed of four subunits which are each made up of 6 transmembrane proteins to form the channel and inactivation gate. | + | **Figure 14:** Visual representation of voltage gated Na+ channels, composed of four subunits which are each made up of 6 transmembrane proteins to form the channel and inactivation gate. |
**Decreased Inhibition** | **Decreased Inhibition** | ||
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Deviations in normal GABA synthesis and release has been shown to produce epileptic symptoms. There has been observed abnormalities in GABAergic function found in both genetic and acquired epilepsy. Decreased GABA-mediated inhibition has been observed in epilepsy. There is defective GABA synthesis in humans with genetic epilepsy, which is characterized by seizures in infants (Treiman, 2012). GABA-receptor densities have been shown to be decreased in people with epilepsy. Furthermore, it was also shown that GABA release in epileptic patients were reduced when compared to non-epileptic people. In a particular study, it was shown that there are two main mechanisms in which GABA can be released into the synaptic cleft (Treiman, 2012). The first being vesicular fusion mediated by Ca2+ influx (discussed earlier). The second is non-vesicular secretion which is regulated via Na+ influx. When comparing an epileptic hippocampus to a non-epileptic hippocampus, it was observed that non-vesicular release of GABA in the epileptic hippocampus was not as robust as the control, resulting in a decreased amount of GABA in the synaptic cleft and by extension a decrease in inhibitory effects on postsynaptic neurons (Treiman, 2012). | Deviations in normal GABA synthesis and release has been shown to produce epileptic symptoms. There has been observed abnormalities in GABAergic function found in both genetic and acquired epilepsy. Decreased GABA-mediated inhibition has been observed in epilepsy. There is defective GABA synthesis in humans with genetic epilepsy, which is characterized by seizures in infants (Treiman, 2012). GABA-receptor densities have been shown to be decreased in people with epilepsy. Furthermore, it was also shown that GABA release in epileptic patients were reduced when compared to non-epileptic people. In a particular study, it was shown that there are two main mechanisms in which GABA can be released into the synaptic cleft (Treiman, 2012). The first being vesicular fusion mediated by Ca2+ influx (discussed earlier). The second is non-vesicular secretion which is regulated via Na+ influx. When comparing an epileptic hippocampus to a non-epileptic hippocampus, it was observed that non-vesicular release of GABA in the epileptic hippocampus was not as robust as the control, resulting in a decreased amount of GABA in the synaptic cleft and by extension a decrease in inhibitory effects on postsynaptic neurons (Treiman, 2012). | ||
{{ :gaba_epi.png |}} | {{ :gaba_epi.png |}} | ||
+ | **Figure 15:** Decreased GABA release results in loss of hyper polarization and transmission of excitatory signals to distal neurons. | ||
+ | |||
====== Treatments ====== | ====== Treatments ====== | ||
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Antiepileptic drugs decrease the membrane excitability via interaction with neurotransmitter receptors or ion channels such as sodium, calcium, or potassium. For example, AEDs that were developed before 1980 acted on sodium channels, GABA receptors (inhibitory), or calcium channels. Drugs such as benzodiazepines and barbiturates enhance GABA receptors to inhibit HFS and activation of neurons. Some drugs (CBZ) mechanism of action is theorized to inhibit the HFS that is sustained via sodium action potentials (Macdonald et al, 1995). | Antiepileptic drugs decrease the membrane excitability via interaction with neurotransmitter receptors or ion channels such as sodium, calcium, or potassium. For example, AEDs that were developed before 1980 acted on sodium channels, GABA receptors (inhibitory), or calcium channels. Drugs such as benzodiazepines and barbiturates enhance GABA receptors to inhibit HFS and activation of neurons. Some drugs (CBZ) mechanism of action is theorized to inhibit the HFS that is sustained via sodium action potentials (Macdonald et al, 1995). | ||
- | Gabapentin is one of the four clinically approved drugs in the states that have proven to have relatively significant effects. The mechanism of action of gabapentin is not fully understood, but its distinct profile of anticonvulsant activity in animal seizure models and its lack of activity at many drug binding sites associated with other antiepileptic drugs indicate that its mechanism of action is novel. Gabapentin has no effect on the GABA receptors uptake but instead, it will interact with a high affinity binding site in the brain membranes: the auxiliary subunit of voltage-sensitive Ca2+ channels. Investigation in rat cortical neurones reported inhibitory effects of GBP on high voltage-activated calcium channels and a specific interaction (Graeme et al, 2006). Gabapentin crosses several lipid membrane barriers via L amino acid transporters. The L amino transport system is responsible for the absorption of the drug from the small intestine and expressed at the blood brain barrier. Once transported, it will increase GABA synthesis as indicated by NMR spec. The increased non-synaptic GABA responses and the reduced release of several mono-amine neurotransmitters are the main results of clinical effects for the treatment of epilepsy. | + | Gabapentin is one of the four clinically FDA approved drugs in the United States that has proven to have relatively significant effects. The mechanism of action of gabapentin is not fully understood, but its distinct profile of anticonvulsant activity in animal seizure models and its lack of activity at many drug binding sites associated with other antiepileptic drugs indicate that its mechanism of action is novel. Gabapentin has no effect on the GABA receptors uptake but instead, it will interact with a high affinity binding site in the brain membranes: the auxiliary subunit of voltage-sensitive Ca2+ channels. Investigation in rat cortical neurones reported inhibitory effects of GBP on high voltage-activated calcium channels and a specific interaction (Graeme et al, 2006). Gabapentin crosses several lipid membrane barriers via L amino acid transporters. The L amino transport system is responsible for the absorption of the drug from the small intestine and expressed at the blood brain barrier. Once transported, it will increase GABA synthesis as indicated by NMR spectroscopy. The increased non-synaptic GABA responses and the reduced release of several mono-amine neurotransmitters are the main results of clinical effects for the treatment of epilepsy. |
Antiepileptic Drugs (AEDs) Mechanism | Antiepileptic Drugs (AEDs) Mechanism | ||
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AEDs also will affect excitation. Phenytoin, carbamazepine, and Lamotrigine all block voltage gated sodium channels, resulting in a reduction of continuation of electric signal. Furthermore, Ethosuximide will block calcium channels to prevent the post synaptic neuron from firing. Felbamate, ketamine, and Mg++ will block NMDA receptors (which bind to glutamate) to prevent an excitatory signal, while topiramate can block both NMDA and non- NMDA receptors to produce the same effect (Stafstrom 1998). | AEDs also will affect excitation. Phenytoin, carbamazepine, and Lamotrigine all block voltage gated sodium channels, resulting in a reduction of continuation of electric signal. Furthermore, Ethosuximide will block calcium channels to prevent the post synaptic neuron from firing. Felbamate, ketamine, and Mg++ will block NMDA receptors (which bind to glutamate) to prevent an excitatory signal, while topiramate can block both NMDA and non- NMDA receptors to produce the same effect (Stafstrom 1998). | ||
{{ :aeds_mechanims_epi.png |}} | {{ :aeds_mechanims_epi.png |}} | ||
- | **Vagus Nerve Stimulation (VNS)** | ||
- | It is a novel therapy that has become available for epilepsy. This is used for patients with partial onset with or without secondary generalization after the age of 12. It is basically a system compromised to battery generators which send intermittent electrical stimuli which is controlled by software and an interrogating wand. The generator is implanted in the left upper chest which connects to the left cervical vagus nerve using two semi-circular helical electrodes. It takes an approximate of 2 hours to complete under general anesthesia. There are some effects that are present during VNS such as vice alteration and tingling sensation in the throat. The intensity of the effects starts to decrease over several weeks. This is one of the less invasive methods for anti-epilepsy. This is however not a replacement for resection surgery which is known to produce seizure-free effects in patients with a chance of 70-90%. | + | **Figure 16**: Certain AEDs can increase inhibition by potentiating GABA's effect whereas others inhibit excitatory by decreasing Glutamatergic effects. |
- | (Uthman, 2000) | + | |
+ | **Vagus Nerve Stimulation (VNS)** | ||
+ | |||
+ | It is a novel therapy that has become available for epilepsy. This is used for patients with partial onset with or without secondary generalization after the age of 12. It is basically a system compromised to battery generators which send intermittent electrical stimuli which is controlled by software and an interrogating wand (Uthman, 2000). The generator is implanted in the left upper chest which connects to the left cervical vagus nerve using two semi-circular helical electrodes. It takes an approximate of 2 hours to complete under general anesthesia. There are some effects that are present during VNS such as vice alteration and tingling sensation in the throat(Uthman, 2000). The intensity of the effects starts to decrease over several weeks. This is one of the less invasive methods for anti-epilepsy. This is however not a replacement for resection surgery which is known to produce seizure-free effects in patients with a chance of 70-90%. (Uthman, 2000) | ||
**Deep Brain Stimulation (DBS)** | **Deep Brain Stimulation (DBS)** | ||
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{{::dbs_procedure.png|}} | {{::dbs_procedure.png|}} | ||
- | Figure_: | + | **Figure 17**: visual of DBS procedure. |
**Brain Surgery** | **Brain Surgery** | ||
- | The goal of surgery is to find the epileptogenic focus which is not eloquent cortex and resect it without causing any neurological deficits. The most common focus point in adults is the temporal lobe (mainly the hippocampus). There are many ways to discover the area of epileptogenic focus: Video and scalp EEG, fMRI, MEG (magnetoencephalography), or seizure semiology. | + | The goal of surgery is to find the epileptogenic focus which is not eloquent cortex and resect it without causing any neurological deficits. The most common focus point in adults is the temporal lobe (mainly the hippocampus). There are many ways to discover the area of epileptogenic focus: Video and scalp EEG, fMRI, MEG (magnetoencephalography), or seizure semiology. (Kawai, 2015) |
Surgery can be divided into either palliative or curative procedures. Curative procedures include lesional resection, lobectomy, and multiple subpial transections. For the treatment of temporal love epilepsy a gamma knife radiosurgery is used. | Surgery can be divided into either palliative or curative procedures. Curative procedures include lesional resection, lobectomy, and multiple subpial transections. For the treatment of temporal love epilepsy a gamma knife radiosurgery is used. | ||
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Surgery is either used to define and resect an area of epileptogenic focus or disrupt the spread of seizure activity which in turn reduces the likelihood of seizures. Electrodes are used to record from the surface of the brain. One of the most common procedures is for medial temporal lobe epilepsy where the hippocampus is the main target for surgery. | Surgery is either used to define and resect an area of epileptogenic focus or disrupt the spread of seizure activity which in turn reduces the likelihood of seizures. Electrodes are used to record from the surface of the brain. One of the most common procedures is for medial temporal lobe epilepsy where the hippocampus is the main target for surgery. | ||
- | + | (Bromfield, 2006) | |
- | (Bromfield, 2006) (Kawai, 2015) | + | |
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Banerjee, P. N., Filippi, D., & Hauser, W. A. (2009). The descriptive epidemiology of epilepsy-a review. Epilepsy Research, 85(1), 31–45. http://doi.org/10.1016/j.eplepsyres.2009.03.003 | Banerjee, P. N., Filippi, D., & Hauser, W. A. (2009). The descriptive epidemiology of epilepsy-a review. Epilepsy Research, 85(1), 31–45. http://doi.org/10.1016/j.eplepsyres.2009.03.003 | ||
- | Bhalla, D., Godet, B., Druet-Cabanac, M., Preux, P.M. (2011). Etiologies of epilepsy: a comprehensive review. Expert Review of Neurotherapeutics. 11(6):861-76 | + | Bhalla, D., Godet, B., Druet-Cabanac, M., Preux, P.M. (2011). Etiologies of epilepsy: a comprehensive review. Expert Review of Neurotherapeutics. 11(6):861-76. Retrieved from https://journals-scholarsportal-info.libaccess.lib.mcmaster.ca/pdf/14737175/v11i0006/861_eoeacr.xml |
- | https://journals-scholarsportal-info.libaccess.lib.mcmaster.ca/pdf/14737175/v11i0006/861_eoeacr.xml | + | |
BRADFORD, H.F. (1995). Glutamate, GABA and epilepsy. Prog. Neurobiol., 47, 477–511. | BRADFORD, H.F. (1995). Glutamate, GABA and epilepsy. Prog. Neurobiol., 47, 477–511. | ||
- | Bromfield EB, Cavazos JE, Sirven JI, editors. An Introduction to Epilepsy [Internet]. West Hartford (CT): American Epilepsy Society; 2006. Chapter 1, Basic Mechanisms Underlying Seizures and Epilepsy.Available from: https://www.ncbi.nlm.nih.gov/books/NBK2510/ | + | Bromfield EB, Cavazos JE, Sirven JI, editors. An Introduction to Epilepsy [Internet]. West Hartford (CT): American Epilepsy Society; 2006. Chapter 1, Basic Mechanisms Underlying Seizures and Epilepsy. Retrieved from: https://www.ncbi.nlm.nih.gov/books/NBK2510/ |
Cho, C.-H. (2013). New mechanism for glutamate hypothesis in epilepsy. Frontiers in Cellular Neuroscience, 7, 127. http://doi.org/10.3389/fncel.2013.00127 | Cho, C.-H. (2013). New mechanism for glutamate hypothesis in epilepsy. Frontiers in Cellular Neuroscience, 7, 127. http://doi.org/10.3389/fncel.2013.00127 | ||
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Dostrovsky, J. O. and Lozano, A. M. (2002), Mechanisms of deep brain stimulation. Mov. Disord., 17: S63–S68. doi:10.1002/mds.10143 | Dostrovsky, J. O. and Lozano, A. M. (2002), Mechanisms of deep brain stimulation. Mov. Disord., 17: S63–S68. doi:10.1002/mds.10143 | ||
- | Epilepsy Support Centre. (2015). Diagnosing Epilepsy. Available at: http://epilepsysupport.ca/seizure-education/about/diagnosing | + | Epilepsy Support Centre. (2015). Diagnosing Epilepsy. Retrieved from http://epilepsysupport.ca/seizure-education/about/diagnosing |
Fisher, R.S. (2017). The New Classification of Seizures by the International League Against Epilepsy 2017. Current Neurology and Neuroscience Reports, 17(48). https://doi.org/10.1007/s11910-017-0758-6 | Fisher, R.S. (2017). The New Classification of Seizures by the International League Against Epilepsy 2017. Current Neurology and Neuroscience Reports, 17(48). https://doi.org/10.1007/s11910-017-0758-6 | ||
- | Gilmour, H., Ramage-Morin, P., & Wong, S.L. (2016). Epilepsy in Canada: Prevalence and impact. Statistics Canada. http://www.statcan.gc.ca/pub/82-003-x/2016009/article/14654-eng.htm | + | Gilmour, H., Ramage-Morin, P., & Wong, S.L. (2016). Epilepsy in Canada: Prevalence and impact. Statistics Canada. Retrieved from http://www.statcan.gc.ca/pub/82-003-x/2016009/article/14654-eng.htm |
Goldberg, E. M., & Coulter, D. A. (2013). Mechanisms of epileptogenesis: a convergence on neural circuit dysfunction. Nature Reviews. Neuroscience, 14(5), 337–349. http://doi.org/10.1038/nrn3482 | Goldberg, E. M., & Coulter, D. A. (2013). Mechanisms of epileptogenesis: a convergence on neural circuit dysfunction. Nature Reviews. Neuroscience, 14(5), 337–349. http://doi.org/10.1038/nrn3482 | ||
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Banerjee, P. N., Filippi, D., & Hauser, W. A. (2009). The descriptive epidemiology of epilepsy-a review. Epilepsy Research, 85(1), 31–45. http://doi.org/10.1016/j.eplepsyres.2009.03.003 | Banerjee, P. N., Filippi, D., & Hauser, W. A. (2009). The descriptive epidemiology of epilepsy-a review. Epilepsy Research, 85(1), 31–45. http://doi.org/10.1016/j.eplepsyres.2009.03.003 | ||
- | Sills, G.J.(2006). The mechanisms of action of gabapentin and pregabalin. Current Opinions in Pharmacology.6(1);108-126. https://doi.org/10.1016/j.coph.2005.11.003. (http://www.sciencedirect.com/science/article/pii/S1471489205001906) | + | Sills, G.J.(2006). The mechanisms of action of gabapentin and pregabalin. Current Opinions in Pharmacology.6(1);108-126. https://doi.org/10.1016/j.coph.2005.11.003. |
- | Stafstrom, C.E. (1998). Back to Basics: The Pathophysiology of Epileptic Seizures: A Primer For Pediatricians. Pediatrics in Review, 19(10). | + | Stafstrom, C.E. (1998). Back to Basics: The Pathophysiology of Epileptic Seizures: A Primer For Pediatricians. Pediatrics in Review, 19(10). Retrieved from http://pedsinreview.aappublications.org.libaccess.lib.mcmaster.ca/content/19/10/342.long |
Treiman DM.(2001). GABAergic mechanisms in epilepsy. Epilepsia;42:Suppl 3:8-12 | Treiman DM.(2001). GABAergic mechanisms in epilepsy. Epilepsia;42:Suppl 3:8-12 | ||
- | World Health Organization. Epilepsy. Fact Sheet No. 999. Geneva: World Health Organization, 2015. Available at: http://www.who.int/mediacentre/factsheets/fs999/en/index.html | + | World Health Organization. Epilepsy. Fact Sheet No. 999. Geneva: World Health Organization, 2015. Retrieved from http://www.who.int/mediacentre/factsheets/fs999/en/index.html |
- | Uthman, B. M. (n.d.). (2000). Vagus nerve stimulation for seizures. Retrieved October 27, 2017, from https://www.ncbi.nlm.nih.gov/pubmed/11036181 | + | Uthman, B. M. (n.d.). (2000). Vagus nerve stimulation for seizures. Retrieved from https://www.ncbi.nlm.nih.gov/pubmed/11036181 |