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Behavioral addiction : ウィキペディア英語版
Behavioral addiction is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a ''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.

Behavioral addiction is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a ''natural reward''〔〔 – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.〔〔〔
==Biomolecular mechanisms==
(詳細はΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction;〔 it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines〔 as well as addictions to natural rewards such as sex, exercise, and food.〔〔 A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.
Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.
One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior.
Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.
Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.〔

抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)
ウィキペディアで「'''Behavioral addiction''' is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a '''''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
'natural reward'' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.


Behavioral addiction is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a ''natural reward''〔〔 – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.〔〔〔
==Biomolecular mechanisms==
(詳細はΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction;〔 it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines〔 as well as addictions to natural rewards such as sex, exercise, and food.〔〔 A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.
Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.
One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior.
Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.
Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.〔

抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)
ウィキペディアで「'''Behavioral addiction''' is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a '''''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.

Behavioral addiction is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a ''natural reward''〔〔 – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.〔〔〔
==Biomolecular mechanisms==
(詳細はΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction;〔 it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines〔 as well as addictions to natural rewards such as sex, exercise, and food.〔〔 A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.
Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.
One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior.
Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.
Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.〔

抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)
ウィキペディアで「'''Behavioral addiction''' is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a '''''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
'natural reward'' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.">ウィキペディア(Wikipedia)』
ウィキペディアで「'''Behavioral addiction''' is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a '''''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.">ウィキペディア(Wikipedia)』
ウィキペディアで「'''Behavioral addiction''' is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a '''''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
'natural reward'' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.">ウィキペディアで「'''Behavioral addiction''' is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a '''''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.">ウィキペディアでBehavioral addiction is a form of addiction that involves a compulsion to repeatedly perform a rewarding non-drug-related behavior – sometimes called a ''natural reward''''' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
'natural reward'' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」の詳細全文を読む
' – despite any negative consequences to the person's physical, mental, social, and/or financial well-being. Compulsive behavior which persists in spite of these consequences is a sign of either an addiction, a dependence-withdrawal syndrome, or both disorders associated with the behavior. A gene transcription factor known as ΔFosB has been identified as being the critical progenitor of behavioral and drug addictions, which are associated with the same set of neural adaptations in the reward system.==Biomolecular mechanisms==(詳細はΔFosBを参照)ΔFosB, a gene transcription factor, has been identified as playing a critical role in the development of addictive states in both behavioral addictions and drug addictions. Overexpression of ΔFosB in the nucleus accumbens is necessary and sufficient for many of the neural adaptations seen in drug addiction; it has been implicated in addictions to alcohol, cannabinoids, cocaine, nicotine, phenylcyclidine, and substituted amphetamines as well as addictions to natural rewards such as sex, exercise, and food. A recent study also demonstrated a cross-sensitization between drug reward (amphetamine) and a natural reward (sex) that was mediated by ΔFosB.Besides increased ΔFosB expression in the nucleus accumbens, there are many other similarities in the neurobiology of behavior and drug addictions.One of the most important discoveries of addictions has been the drug based reinforcement and, even more important, reward based learning processes. Several structures of the brain are important in the conditioning process of behavioral addiction; these structures form the region of the brain known as the reward system. One of the major areas of study includes the region, called the amygdala, which involves emotional significance and associated learning. Research shows that dopaminergic projections from the ventral tegmental area facilitate a motivational or learned association to a specific behavior. Dopamine neurons take a role in the learning and sustaining of many acquired behaviors. Research specific to Parkinson’s disease has led to identifying the intracellular signaling pathways that underlie the immediate actions of dopamine. The most common mechanism of dopamine is to create addictive properties along with certain behaviors. There are three stages to the dopamine reward system: bursts of dopamine, triggering of behavior, and further impact to the behavior. Once electronically signaled, possibly through the behavior, dopamine neurons let out a ‘burst-fire’ of elements to stimulate areas along fast transmitting pathways. The behavior response then perpetuates the striated neurons to further send stimuli. The fast firing of dopamine neurons can be monitored over time by evaluating the amount of extracellular concentrations of dopamine through micro dialysis and brain imaging. This monitoring can lead to a model in which one can see the multiplicity of triggering over a period of time. Once the behavior is triggered, it is hard to work away from the dopamine reward system.Behaviors like gambling have been linked to the newfound idea of the brain’s capacity to predict rewards. The reward system can be triggered by early detectors of the behavior, and trigger dopamine neurons to begin stimulating behaviors. But in some cases, it can lead to many issues due to error, or reward-prediction errors. These errors can act as teaching signals to create a complex behavior task over time.」
の詳細全文を読む



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