The Anatomy Of Fear and How It Relates To Survival Skills Training
By Darren Laur

An officer assigned to jail duty conducts a prisoner bed check when he observes that a male who was lodged in the drunk tank was laying face down not breathing in a corner of the cell. The officer attempts to verbally arouse the prisoner, but these attempts fail. The officer now believing that the prisoner is dead, proceeds into the cell, bends over and grabs the prisoner by his left shoulder in an attempt to roll him over. At this point the prisoner, suddenly and spontaneously, quickly rolls towards the officer, and with his right hand, swings towards the officer's face. The officer "instinctively" pulls both of his arms in to protect his head, and moves backwards.

The suspect has now moved to his feet, and again lashes out towards the officer with what the officer "perceives" to be a big right hooking punch, at which time the officer again puts his hand up to cover his head, crouches and again moves backwards away from the threat. The officer only now realizes that he is bleeding profusely, but doesn't know why. The prisoner lunges at the officer a third time, with a straight line punch, at which time the officer sees the shinning glimmer of a metal object. As this third attack makes contact, he instinctually attempts to push the prisoners hands away from his body, but contact is made resulting in a puncture wound to the officer's chest area. The officer now realizing that he is in an edged weapon encounter, and cut several times, disengages from the cell area to call for help.

The above noted scenario happened to a police officer in my department in 1992. Although this officer had received training in edged weapon defense, and was one of the more officer safety conscious members of the department, he could not make his training work. Based upon the officers reaction to this spontaneous attack, I began to wonder if the "instinctual" physical reactions to this attack, which were totally different from the training he received up to that point in time, would be experienced by other officers as well, if placed into a spontaneous attack situation in which they had no idea that an attack was going to occur.

I'm a big believer in, "don't tell me, show me" so in early 1992 I conducted an empirical video research study. I had 85 police officers participate in a scenario based training session where unknown to them; they would be attacked with a knife. The attacker, who was dressed in a combatives suit, was told that during mid way of the contact, they were to pull a knife that they had been concealing, flash it directly at the officer saying "I'm going to kill you pig", and then engage the officer physically. The results were remarkable:

. 3/85 saw the knife prior to contact
. 10/85 realized that they were being stabbed repeatedly during the scenario
. 72/85 did not realize that they were being assaulted with a knife until the scenario was over, and the officers were advised to look at their uniforms to see the simulated thrusts and slices left behind by the chalked training knives

When I reviewed the many hours of videotape of the scenarios, I also made two very important and interesting observations in how the majority of officers reacted to the spontaneous attacks:
. Most flinched, bringing both hands up to protect their head while crouching at the same time, and attempted to disengage from the attacker by backing away from the threat. This usually resulted in the attacker closing the gap quite quickly with their victim . Those officers that did engage the threat immediately, proceeded to effectively block the initial strike of the attacker and then immediately grappled with the attacker using elbows and knee strikes

After making these observations, I asked, "why was I seeing these reactions." During this research project, I had the opportunity to read an article authored by Bruce Siddle and Dr. Hal Breedlove entitled, " Survival Stress Reaction". In this article Siddle and Breedlove stated:

"Research by numerous studies provide two clear messages why people will place themselves in bad tactical situations. The common phenomena of backing away under survival stress results from the visual systems deterioration of the peripheral field to attain more information regarding threat stimulus. Since the brain is demanding more information to deal with the threat, the officer will invariably retreat from the to widen the peripheral field. Secondly, the brains normal ability to process (analyze and evaluate) a wide range of information quickly is focused to specific items. Therefore, additional cues, which would normally be processed, are lost. This explains why people can't remember seeing or identifying specific facts which were relatively close to the threat."

The research by Siddle and Breedlove not only confirmed my findings, but also answered why our officers were acting this way. It also explains why one officer, who had actually caught the attackers knife hand with both of his hands and was looking directly at the knife, stated "I didn't see any knife" It wasn't until I showed the video replay that he believed there was a knife.

In 1995, Bruce Siddle released his first book entitled; "Sharpening The Warrior's Edge The Psychology and Science Of Training" In my opinion, Siddles's published works began to answer a lot of the questions that I asked during my experience with, and empirical research into combatives

The first real studies in the area of SSR as it related to combat performance, were conducted in the 1930's, when it was noted that those soldiers who were sending Morse code (fine/complex motor skill) during combat situations had much more difficulty in doing so when compared to non-combat environments. The next real research in SSR came during the Vietnam War as it related to the location of buttons and switches in fighter cockpits. As a result of this research, cockpits were reconfigured to take SSR into affect, as it specifically related to eye/hand co-ordination during combat situations.

Although much of the early research surrounding SSR was conducted by the military during times of war, recently (from the mid 1960's to present time) a lot of research has been conducted in SSR as it relates to athletic performance.

Siddle's definition of SSR as it relates to combat is; " a state where a "perceived" high threat stimulus automatically engages the parasympathetic nervous system." The parasympathetic nervous system is an autonomic response process, which, when activated, one has little control of. Why is SSR so important when it comes to combat/self protection? Because when activated, SSR has both a psychological and physiological effect to the body which could affect one's perception of threat in a negative way. So what are some of these effects according to Siddle's research?

a) Increased Heart Rate:
. We know that SSR is directly related to an increased heart rate

. At 115 beats per minute (bpm) most people will lose fine complex motor skills such as finger dexterity, eye hand co-ordination, multi tasking becomes difficult

. At 145 bpm, most people will lose complex motor skills ( 3 or more motor skills designed to work in unison)

b) Effects To Visual System:
. The visual system is the primary sensory organ of the body for those of us that can see, due to the fact that the visual system sends information to the brain that is needed during combat/self protection

. At approximately 175 bpm, a person will experience an eye/lid lift, pupils will dilate and flatten. As this reaction takes place, a person will experience visual narrowing (commonly known as tunnel vision). This is why it is very common for a person to back up from a threat in order to get more information through this tunnel. It is also at this point in time, that a person becomes "binocular" rather than "monocular" This is why in CQB shooting, I teach two eye "binocular" shooting rather than one eye aimed shooting.

. At 175 bpm, visual tracking becomes difficult…… this is very important when it comes to multiple threats. During multiples, the brain will want the visual system to stay with what it sees to be the primary threat. Once this threat has been neutralized, the brain and visual system will then find its next threat. This is commonly known as the "light house" effect. Studies have found that a person in SSR will experience on average about a 70% decrease in their visual field. This is one reason why in combat, we need to teach students to constantly be scanning their environment, looking for the second and third opponent.

. At 175 bpm, it also becomes difficult to focus on close objects…. One of the first things to go under SSR is depth perception. A fighter WILL become far sighted rather than near sighted. This is why it is very common for people experiencing SSR to say that the threat was either closer or father away from where they actually were. Studies in SSR have shown that binocular fighting/shooting will improve one's depth perception by 20-30%

c) Effects To The Auditory System:
. At approx 145 bpm, that part of the brain that hears, shuts down during SSR. This is one reason why it is not uncommon for fighters to say " I didn't hear that" , " I heard voices but I couldn't understand what they were saying" or ' I heard bits and pieces", " I didn't hear a gun shot"

d) Effects To The Brain:
. At approx 175 bpm, it is not uncommon for a person to have difficulty remembering what took place or what they did during a confrontation

. This recall problem is known as " Critical Stress Amnesia". After a critical incident, it is not uncommon for a person to only recall approx 30% of what happened in the first 24hrs, 50% in 48 hrs, and 75-95 % in 72-100hrs

. At 185-220 bpm, most people will go into a state of "hypervigilance", this is also commonly known as the "deer in the headlights" or "Brain fart mode" It is not uncommon for a person to continue doing things that are not effective ( known as a feedback loop) or to show irrational behavior such as leaving cover. This is also the sate in which people find themselves in when they describe that they can not move, yell, or scream. Once a person is caught in a state of hypervigilance, it is a downward spiral that is very tough to get out of. Once caught in a state of hypervigilance information on the threat is reduced to the brain which leads to increased reaction time. This increased reaction time then leads to a heightened state of stress which further exacerbates hypervigilance

e) Effects To Motor Skill performance
. At approximately 115 bpm, fine/complex motor skills become less available/effective (pulling a trigger, handling a knife), but gross motor skills turn on and become optimized

So why is this information so important? Because Siddle has found, the higher the heart rate, the more SSR will affect one's perception of threat. Also, the higher the heart rate, the more negative effects it will have on motor skill performance.

One must remember that in combat, a person's heart rate can go from 70 bpm to 220bpm in less than half a second. So what is the "combat maximum performance range" when it comes to SSR and heart rate? Siddle in his studies has found that it is between 115-145 bpm. Siddle has also found that a fighter's "maximum reaction time performance range" is also between 115-145 bpm. In other words, the 115-145 bpm range is where fighting skills (gross motor) and reaction time are maximized.

As I said earlier, SSR is an autonomic response, which happens without conscious thought. Having said this, Siddle in his research has found that a person can manage SSR to attain that peak 115-145 bpm range in the following ways:

1) Skill Confidence:
. This takes place through both mental and physical training

2) Experience Through Dynamic Simulation Training
. Experience increases and builds confidence- reduces "newness" of stimulus
. Training should be "realistic" stimulus/response based
. The more real the training experience (stimulus) the better


3) Visualization (mental imagery)
. Commonly known as "spinal tuning," we now know that the upper part of the spinal column holds a short term memory.

. This is one reason why I have taught our department's Emergency Response Team (ERT) to visualize both their plan "A" strategy and plan "B" strategy as they are enrout to their target.

. Remember that the mind can not easily tell the difference between fantasy and reality. The more one uses mental imagery, the more one becomes spinal tuned to deal with the task at hand

. As a certified hypnotherapist, I am using the science and art of hypnosis and NLP (Neuro Linguistic Programming) to pre-program stimulus /response issues directly into the subconscious, specific to combat performance. Not only have I have seen a DRAMATIC increase in combative performance in those students in which I am using hypnosis and NLP, but I am also experiencing about a 50% decrease in the amount of time needed to make a student unconsciously competent in the skill set taught, when compared to those who I have not conducted this type of training with. In fact, I truly believe that hypnosis and NLP specific to combatives, will be the next nexus in training

4) Breathing
. This skill has been used in the martial arts for thousands of years known as autogenic breathing

. You want to breath in through their nose for a three count, hold for a two count, and then breath out through the mouth for a three count. Studies have found that if a person was to do this for a 3 cycle count, it decreases one's heart rate up to 30% for up to 40 seconds. Again remember that heart rate is directly related to SSR. If a person's heart rate was sitting at around 175-220 bpm, autogenic breathing would help bring them back down into that target range of 115-145 bpm

. I have also taught this skill to our department's ERT team. While they are doing their spinal tuning, they are also conducting autogenic breathing drills at the same time. Our ERT team have conducted a lot of empirical and "real world" operations where they placed heart monitors on team members which have proven this de-escalation in heart rate

5) Value Of Life:
. In our society a person's life is considered to be precious. In fact, most of our morals and laws are based upon protecting oneself and others against serious injury or death

. In a self-defence situation, one may have to seriously injury or even kill another human being

. Although a reality, many people involved in combatives training have not "really" internalized or even thought about this. Because of one's "belief system", to kill or seriously injure another person is as foreign to them as committing suicide

. If one does not come to grips with this issue one will fail to act in such a situation

6) Belief In Mission / Task At hand:
. If you do not believe in the mission or task at hand, or if the risks outweigh the ultimate benefit to you/society, you WILL hesitate in combat

. One who hesitates in combat, will usually levitate ( 12 feet under or be seriously injured

7) Faith System:
. You do not want to go into combat without having things resolved

. Both the ancient samurai and the kamikaze's during WWII understood this important rule

. Even in our modern times, there are certain spec war teams around the world that are allowed to make peace with their deity prior to mission

. A strong faith system, whatever that faith system may be, MINIMIZES the fear of dying. As a graphic example of this, look at the events of September 11th and how the terrorists were not afraid to die and thus were able to carry out their mission. Also look at what is happening in Israel right now!

. Remember, combat is not the place for you to be making major adjustments to your belief system. You need to be concentrating on the task at hand and nothing else. Not to do so places yourself in jeopardy

8) Training:
. Training for combat must be gross motor based, why? Because we know that during combat, SSR will negatively effect fine/complex motor skill performance no matter how well trained an individual

. For any skill taught, there must always be a plan "B" abort strategy conditioned as well. We must not be teaching multiple defenses (responses) to a specific type of attack (stimulus). The reason for this, HICKS LAW!

. Hicks Law basically states the following: the average reaction time given one stimulus one response is about ½ second. If we now teach a student a second technique (response) to the same attack (stimulus) we WILL increase a person's reaction time by 58%. On the street we want to DECREASE reaction time, not increase it. If we teach multiple defenses to one specific attack, the brain will take time deciding which option to use. This increased reaction time could mean the difference between life and death.

. Instructors should always teach a new technique in slow motion, why? it allows the students brain time to observe the technique and begin the "soft wiring process" which becomes "hard wired" through physical and mental training in conjunction with repetition, as long as it is gross motor skilled

. All physical skills should be chunked or partitioned into progressive steps, rather than taught all at once. Many instructors when teaching a physical techniques will have the students practice the entire technique from beginning to end when first learning the specific skill set. This is a huge mistake. Remember that the brain first learns in pictures and through modeling. By teaching a technique from A to Z all at once, the student may not fully develop the proper and full "mental picture" needed to perform the technique properly which usually leads to frustration by the student. Teachers, coaches, and instructors must insure that the student understands step A fully, then move onto step B. Once step B is understood move on to step C and so on. By doing this, frustration goes down, while confidence and skill level go up.

. Once the skill sets are learned, they must now be applied in dynamic training in order to make the stimulus/response training as real as possible. Again, the more the real the training, the better prepared one becomes for the reality of the street

Although Siddle's research has brought to light the physiological effects of fear, such as increased heart rate, fine complex motor skill deterioration, and what we can do as instructors to limit the effects of SSR during combat, it didn't fully explain why and how the brain learns and responds to the emotion of fear, thus triggering SSR. To me, this is the key question to be answered if one's combative system or style is going to be able to consistently deal with an unexpected spontaneous assault, be it armed or unarmed. In other words, are our brains hardwired to the point where a trained response, no matter how well ingrained, be overridden by a more powerful "instinctual" response? If the answer to this question is yes, can this instinctual response be changed, molded, or integrated into a combative context?

Research into this question, specific to Survival Skills Training, has really been non-existent. Having said this, research into how the brain learns and responds to the emotion of fear has taken off over the past few years, due mainly to brain mapping technology such as MRI's, and has been spearheaded by several experts in the Neuroscience filed. One of the more significant researchers, Dr Joseph LeDoux of New York University, has led the way in tracing brain circuitry underlying the fear response in animals/ mammals, which have been directly correlated to humans as well. It is because of Dr LeDoux's pioneering research, that the neural pathways and connections that bring upon the effects of SSR are now being understood.

Dr LeDoux has stated, "fear is a neural circuit that has been designed to keep an organism alive in dangerous situations." Throughout his research, Dr LeDoux has shown that the fear response has been tightly conserved in evolution throughout the development of humankind and other vertebrates. According to most experts in the field of Neuroscience, the areas of the brain that deal with fear are located in the phylogenetically old structures of the brain, commonly known as the "reptilian brain." Based on his research, Dr LeDoux believes, "learning and responding to stimuli that warn of danger involves neural pathways that send information about the outside world to the amygdalya, which in turn, determines the significance of the stimulus and triggers emotional responses like running, fighting, or freezing, as well as changes in the inner workings of the body's organs and glands such as increased heart rate." This statement explains the correlation between SSR and heart rate increase.

Siddle's research draws a direct correlation between SSR and increase in heart rate. The problem with this assumption is that for runners, who have very high heart rates, SSR does not take effect, why? A runner's high heart rate is caused by physical exertion, and not the emotion of fear caused by a spontaneous or immediate threat to body or life, which triggers the neurological response of the brain, and more specifically the amygdala, which in turn begins the SSR process.

Dr LeDoux has also found, " there are important distinctions to make between emotions and feelings. Feelings are "red herrings," products of the "conscious mind," labels given to unconscious emotions, whereas emotions are distinct patterns of behaviors of neurons. Emotions can exist of conscious experiences as well as physiological and neurological reactions and voluntary and involuntary behaviors." I believe the most important thing to take from this statement is that the emotion of fear is an unconscious process that has been blueprinted at the neurological level, and when triggered, has physiological reactions that we may have little, if any, control over, but which can be molded.

Dr LeDoux has also discovered that the components of fear go way beyond feelings and emotions. According to Dr Ledoux it is also the specific memory of the emotion. A fellow Neuroscientist, Dr Doug Holt expanded upon this fact and said' " after a frightful experience, one can remember the logical reasons for the experience ( e.g. the time and place) but one will also feel the memory, and his body will react as such (i.e. increased heart rate and respiration rate, sweating)." This is why it is not uncommon for a survivor of spontaneous assault to not only vividly remember each detail, but when doing so, their body reacts as though they were reliving the experience. This is another reason why I believe that guided imagery, when used appropriately and professionally, will be the next nexus in combatives training. Although not all scientific research makes this particular distinction between emotions and feelings, most would agree that the fear response involves more than just the physical preparation for "fight, flight, or hyper-vigilance." This initial physiological response is followed by a slower, more detailed psychological assessment of the dangerous situation being faced, during which the individual becomes conscious of feeling afraid.

So what happens in our brain when the emotion of fear is triggered? According to Dr. LeDoux and other Neuroscientist, once the fear system of the brain detects and starts responding to danger (primarily the amygdala which receives input directly from every sensory system of the body and can therefore immediately respond), and depending upon fear stimulus intensity, the brain will begin to assess what is going on, and try to figure out what to do about it using the following process:

. Information of the threat stimulus is detected via the senses of the body; sight, sound, touch, smell, taste

. Information from one or all of these senses is then routed to the thalamus ( a brain structure near the amygdala that acts like an air traffic controller or a mail sorting station that sorts out incoming sensory signals)

. In a non-spontaneous threat situation, the thalamus will direct information received to the appropriate cortex of the brain (such as the visual cortex) which consciously thinks about the impulse, assessing the danger, and making sense of it. This is where the O.O.D.A. loop begin (Observe, Organize, Decision, Action)

. Once a decision has been made as to what to do, the information is then downloaded to the amygdala which creates emotion and action through the body to either perpetuate a physical response or to abort a physical response

Again, this process takes place in non-spontaneous type situations. This neuro- pathway is commonly called the "high road". This is the pathway in which most combatives instructors teach too. In other words:

. Person throws a right hooking punch which is seen and detected by the visual system

. Visual system downloads this stimulus to the thalamus that sorts it and send it to the visual cortex of the brain

. Visual cortex using the OODA loop, observes the stimulus, organizes it (right hooking punch), makes a decision as to how to deal with stimulus and then downloads the response to the amygdala

. Amygdala then creates emotion and action through the body and the punch is blocked

This is what Siddle and others have called stimulus/ response training. A threat stimulus triggers a trained response is the goal, as long as that trained response is gross motor based and takes into consideration Hicks Law. Siddle has stated, "an automatic response to a specific threat can only occur when the students practice a skill in conjunction with a specific level of threat. For a response to be conditioned or an automatic response, there must be an associated stimulus, which triggers the response. Therefore, if a survival motor program is expected to be automatic to a threat in the field, the two must be combined early in the student's training."

Although I do agree that we as instructors should be focusing our training at the development of automatic responses to a specific threat stimulus, what happens if those trained responses are not congruent with the bodies hardwired response during an unexpected spontaneous assault? Does it not make logical sense that we as trainers should teach a physical response that would be congruent with what the brain has preprogrammed itself to do through millions of years of evolution?

Again, the answer to this question is a definite yes, and Dr. LeDoux has been able to prove it scientifically. Dr. LeDoux has found that frightening stimuli trigger neuronal responses along dual pathways. The first path is the one mentioned above "The High Road". The second path is known as the "Low Road", and this is the path that the brain "WILL" follow in a spontaneous surprise attack for survival:

. In a spontaneous surprise attack, information received by the thalamus is quickly re-routed to the amygdala bypassing the cortex (the thinking brain in which OODA is followed)

. The amygdala immediately sets SSR (autonomic arousal) into effect with the added benefit of what neuroscientists have called "Somatic Reflex Potentiation" also commonly known as the "startle circuit" or "protective reflex" ( i.e. an exaggerated startle/flinch response) Other protective reflexes include; sneezing, eye blinking, gag reflex, pulling away from a pain stimulus, laryngospasm( closing of the airway to prevent water into the lungs)

. After passing directly through the amygdala, which initiates SSR and Somatic Reflex Potentiation, sensory information is then sent to the cortex.

. Once the cortex has received this information, the frightening stimulus is then examined in detail to determine whether or not a real threat exists. Based upon this information, the amygdala will be signaled either to perpetuate the physical response and deal with the threat or abort action. Because the amygdala is aroused before the cortex can accurately assess the situation, an individual will experience the physical effects of fear even in the case of a false alarm. The "Low Road" has already prepared the body for immediate action.

Knowing that the brain has a dual pathway to deal with what I like to call progressive and spontaneous fear stimuli, Dr LeDoux has stated, "there are problems associated with the double wiring between the higher cortex and the amygdala. Unfortunately the neural connections from the cortex down to the amygdala are less well developed than are connections from the amygdala back up to the cortex. Thus, the amygdala exerts a greater influence on the cortex than vice versa.

Once an emotion has been turned on, it is difficult to exert conscious control over it at will. What this means to me is that in an unexpected spontaneous attack, if you are training motor skills that are not congruent with what the amygdala will cause the body to do, more specifically the "Somatic Reflex Potentiation" no matter how well trained the response, it will be overridden. But many in the field of combatives believe that we can make a trained response the dominant response through much repetition and training, using stimulus / response training methods. In a "High Road" scenario, this will work given SSR issues and Hick's law, but in a "Low Road" scenario, the answer will only be "yes" as long as the motor skill taught is congruent with the automatic protective reflex the amygdala will cause the body to take.

This "low road" signal system does not convey detailed information about the threat stimulus, but it has the advantage of speed. And in combat speed is of great importance to one facing a threat to their survival. Dr Ledoux pointed out that having a very rapid, if imprecise, method of detecting danger (such is found in the low road pathway) is of high survival value. As Dr. Ledoux has so eloquently stated in several articles, "You're better off mistaking a stick for a snake than a snake for a stick."

So what is the correlation between the neuro-scientific research of fear, and it relationship to survival skills training?

1. The brain has been "hard-wired" to deal with the emotion of fear 2. One pathway is known as the "High Road," in which action can be based on conscious will and thought. This pathway appears to take effect during "progressive" types of fear stimuli. Here a combatives student will be able to apply stimulus / response type training using the OODA model having regards to gross motor skills and Hick's Law

3. A second pathway is known as the "Low Road" which is triggered by a spontaneous / unexpected attack. Here, the brain will take control of the body with an immediate "protective reflex" (downloaded directly to the brain stem where all of our reflexive responses to danger are stored), which will override any system of combat that bases its ability on "cognitively" applying a physical response. This is especially true if the trained response is not congruent with the "protective reflex" (this is exactly what I observed in the 1992 video study I conducted.

So what can we as Instructors, coaches, and teachers do to incorporate the most current research in the field of Fear and Survival Skills Training?

. Absorb the above noted information and research it yourself

. Seek out instructors, coaches, trainers that are using this research in their teaching. You will be surprised that there are few that do. One of the leading pioneers in design and implementation of programs that incorporate this information is Tony Blauer and those associated with his organization in which I am not a member. Since 1992, the motor skill training programs I teach have also revolved around the principals of the above noted information as well. Another instructor, Richard Dimitri (Senshido) provides training based upon the above noted information. And of course, Bruce Siddle and his PPCT management systems is also a leader in the field of psychology of combatives training.

. If you can not attend courses from the above mentioned, look at what you are doing in the area of self protection and ask yourself, is my training "congruent" with the information noted above, if not change what you are doing

. Train on the concept of "commonality of technique." The initial plan-A strategy that I use in an unexpected spontaneous assault (armed or unarmed), is no different than in an attack that I do see coming. Why, because no matter if the brain goes "High-Road" or "Low-Road," my "congruent" gross motor skills will work in both paths. This is a definite tactical advantage

. Understand that although the "Low-Road" reflexive motor responses cannot be changed, but can be "molded" to fit a combative motor skill technique that are useable during a spontaneous attack. I use the Somatic Reflex Potentiation response, which I call "penetrate and dominate," in all my programs. Tony Blauer uses the flinch response in his SPEAR system. Richard Dimitri also incorporates the flinch in his training at Senshido

. Fortunately, there are methods of reducing fear and inhibiting the fear response (see Siddle's 8 steps to management of SSR)

I'm not a doctor or Neuroscientist, but I have been studying combatives for the past 14 years. Since 1992, I have been using training techniques based upon the information presented here, not knowing that I was doing so. In the past, my training was based solely on my empirical research here at the school, and what was happening to officers and civilians in the real world. The information in this posting has now solidified my belief that what I'm doing (and have been doing for years) in the area of combatives is correct. This belief is not only based upon my empirical research over the past 10 years, but scientific research as well.

The field of Neuroscience, (specific to fear), is constantly evolving. Any true "street" combative system or style should keep abreast of these new discoveries and integrate them into a training program to make their survival skills more applicable for the street.

Knowledge and the understanding and application of that knowledge is power. Please feel free to pass this information on, but remember give credit where credit is due.

Strength and Honor
Darren Laur
Integrated Street Combatives

References:

. Bruce Siddle, Sharpening The Warrior's Edge The Psychology and Science Of Training
. Lt. Col Dave Grossman, On Killing The Psychological Cost Of Learning To Kill In War And Society
. Dr Doug Holt, The Role Of the Amygdala In fear And Panic
. The Anatomy Of Fear
. Michael Davis, The Role Of The Amygdala In Fear And Anxiety
. National Institute Of Mental Health, Lessons From Fear Conditioning
. LeDoux Laboratory, Overview, Emotion, Memory, and The Brain
. Joseph E LeDoux, Memory and Emotion
. Laurel Duphiney Edmunson, The Neurobiology Of Fear
. Joshua Freedman, Hijacking Of The Amygdala
. Society For Neurosciences, Fear And The Amygdala