Many different factors can cause anxiety. One little-known cause is a genetic variation that prevents your brain from making enough GABA, a calming brain chemical that prevents anxiety. You can do a simple test with a supplement to find out if this genetic variation affects you.

GABA: The brain chemicals that prevents anxiety

When GABA is low, anxiety goes up, it’s difficult to sleep, and you always feel like you’re in a hurry or living under the threat of imminent doom.

GABA is made from another brain chemical called glutamate. Glutamate is the opposite of GABA in that it is excitatory and stimulating to the nervous system. Both are necessary for healthy brain function. Ideally, they operate in concert with one another, keeping the brain both sufficiently stimulated and calmed as necessary.

However, many disorders today, including anxiety, involved excess glutamate and insufficient GABA. Excess glutamate not only over stimulates the nervous system, it is also toxic to the brain and can age, or degenerate, it too quickly.

The alpha-ketoglutaric acid challenge to screen for genetic cause of anxiety

A variety of factors can cause excess glutamate, however, for some it is faulty conversion of glutamate to GABA that is genetic. Consider this possibility if you have a family history of anxiety.

You can test whether you have this genetic conversion variation with a supplement called alpha-ketoglutaric acid (AKG). The body makes AKG into glutamate, some of which will be made into GABA, unless you have this genetic issue.

How to do the AKG challenge

To perform the challenge, take 3,000 to 4,000 mg of alpha-ketoglutaric acid. Some people have a response after taking it once; others have to take it for several days to respond. Use trial and error to test it.

If you do not have this genetic conversion issue, the AKG will cause either no symptoms or perhaps a little extra energy from the increased glutamate production, but not anxiety.

For the person with the genetic variation, however, the surge of glutamate production combined with the genetic inability to convert it to GABA will cause excitability, nervousness, anxiety, insomnia, and other GABA-deficiency symptoms.

If you have a positive result with the AKG challenge

If the AKG gave you anxiety or insomnia, then you know a perpetual GABA shortage may be an issue for you. Taking GABA support on a regular, lifelong basis may help alleviate symptoms of anxiety, insomnia, nervousness, and catastrophic thinking.

Compounds that work well to support GABA pathways include l-theanine, l-taurine, vitamin B6, valerian, passion flower, and lithium orotate. These can be taken regularly.

Be careful with drugs that increase GABA, such as benzodiazepenes (Valium, Xanax, etc.) They cause many people to build a tolerance to them and withdrawal can be extremely difficult.

Some supplements such as phenibut act like benzodiazepenes and can also cause tolerance if taken regularly, so be mindful of those. Straight GABA is too large to cross the blood-brain barrier, so if it works, then this may indicate you have a leaky blood-brain barrier, which is commonly associated with leaky gut. Also, taking straight GABA regularly can cause you to build a tolerance as well.

Regular exercise, stress-reducing techniques, blocking blue light at night  avoiding foods or supplements that raise glutamate (such as MSG or artificial sweeteners), stabilizing blood sugar, and avoiding foods that cause an immune reaction are some other ways to manage your anxiety naturally.

The cerebellum (the area at the back of the brain) is best known for its role in balance and coordination. However, the cerebellum does more than that — when it starts to malfunction, the results can be not only worsened balance, but also anxiety, insomnia, and hyper sensitivity.

The cerebellum is a primary integrator of information for the brain. Our body has hundreds of thousands of receptors that detect motion, vision, and where and how our body and joints are positioned at all times. These receptors constantly relay information to the brain so that we can move and function properly in our environment.

This information requires organizing before heading to the rest of the brain. The cerebellum condenses the information and “gates” it, meaning it releases it in manageable amounts to the brain’s cortex, the outer covering with its characteristic folds.

The cortex, which is responsible for higher-order functions of thought and action, decides if you need to carry out a specific action or thought in response to the information, such as turn left, answer a question, run from danger, make a decision, etc. The cortex then sends its information back to the cerebellum to help carry out actions.

When things go wrong with the cerebellum

The cerebellum is a common site of dysfunction. It can degenerate, meaning neurons die. The cerebellum is very susceptible to sensitivity to gluten and other foods, environmental toxins, and oxidative stress. It also can degenerate with age — why older people notoriously have bad balance. Children born with brain developmental disorders often have poor cerebellar function.

Poor cerebellar function is observed in various ways, such as poor balance, lack of coordination, or a tremor as you go to pick something up or bring a glass to your mouth (known as termination tremors).

Stand with your feet together, your arms at your side, and then close your eyes. If you sway more frequently to one side, that may indicate the side with more cerebellar dysfunction — it takes it longer to respond to falling on that side of your body.

Other tests your doctor may use to observe cerebellum function are coordination tests such as: finger to nose, walking heel to toe in a straight line, performing complex alternating movements, and ocular tracking (the eyes give insight into function).

Poor cerebellar function can also cause dizziness, disorientation, and nausea in cars, on boats, or when seeing things move swiftly, such as in a movie. Basically, the cerebellum is not able to respond appropriately to input from the environment.

Cerebellum function and anxiety and insomnia

As the cerebellum loses function it begins to falter at its job of gating information delivered to the cortex. As a result, excess information slips through.

This means the cortex and areas in the brainstem receive more information than they can adequately manage. Much of the role of the frontal cortex is to act as a brake pedal on the brainstem, preventing the brainstem from spinning out of control. Our brainstem governs myriad functions, such as emotions, heart function, blood pressure, and digestion.

This poorly gated sensory overload can cause many symptoms:

• Anxiety
• Sensitivity to light and sound
• Startle easily
• Insomnia due to racing mind
• Irritable
• Trouble staying asleep
• Highly emotionally sensitive
• Fearful
• Heart racing/palpitations
• Blood Pressure changes
• Digestive Issues

Many factors work against us when it comes to healthy brain function that prevents an overactive brain and anxiety. They include a culture that cherishes overworking, inflammatory diets, unstable blood sugar, too much screen time, stressful lives, and not enough sleep.

Ask my office for information on how to dampen brain activity and help relieve anxiety and insomnia.

How does functional neurology differ from conventional neurology? Conventional neurology diagnoses neurological disorders that can be treated with pharmaceutical or surgery. Functional neurology, on the other hand, identifies a broader range of brain disorders and restores function through rehabilitation that either dampens or activates specific regions of the brain.

A good example is migraines. Many people see neurologists for debilitating migraines. However, virtually every person who suffers with chronic migraines has a normal brain scan. As a result, conventional neurology has little too offer beyond pharmaceuticals. In other words, the neurons are there, they just aren’t firing correctly.

The same can be said for other brain disorders. Autism, depression, anxiety, insomnia, chronic fatigue, chronic pain, hyper sensitivity to light and pain, emotional instability, loss of memory, gut problems, childhood developmental disorders, autism, brain injury, memory loss, vertigo, tremors, dystonia, are examples of brain-based disorders functional neurology can help.

An analogy for brain function is a symphony orchestra. Before the performance, the musicians tuning their instruments sounds jarring. However, when the instruments are tuned and the musicians play at the appropriate time, the result is lovely.

Our brain works the same way. Firing and timing that are off in the brain causes symptoms while restoring function through rehabilitation improves neurological harmony.

Functional neurology and underlying causes

Neither drugs nor surgery are appropriate or effective for many brain-based disorders.

For one thing, medications are not selective for one area of the brain, but instead they bathe the entire brain. Depression may be related to dysfunction in just the frontal lobe, but an anti-depressant affects the entire brain and may cause negative side effects.

Another example is a patient with Meniere’s disease, which causes dizziness, ringing ears, and nausea. They may be told they need anti-nausea or anti-vertiginous medication and surgery to sever the nerve in the inner ear. However, Meniere’s is an autoimmune disease caused by the immune system attacking and destroying the inner ear.

Functional neurology looks at not only the underlying causes of an over zealous immune system, but also at the areas of the brain that are responsible for interpreting this information. The combination of these two can provide relief and slow or halt progression of the disease.

Functional neurology exams and protocols

Functional neurology uses a variety of techniques to assess which areas of the brain are breaking down. An important aspect of the functional neurology exam includes observing your eyes in response to various stimuli; eye function involves almost every part of the brain.

How your eyes respond when tracking fast movements, slow movements, and when you are rotating or balancing delivers specific insights into brain function and what kinds of rehabilitation will work best.

Other exam techniques involve observing your response to balance, coordination, gait, and rotation challenges. The discipline requires a strong understanding of neurological anatomy, physiology, function, and the various pathways and networks in the nervous system.

The functional neurologist uses the data from your exam to create brain rehabilitation exercises that activate sluggish areas of the brain or dampen over active areas.

For instance, a person with anxiety, insomnia, hyper sensitivity to light and sound, and who startles easily may suffer from degeneration of the cerebellum (at the back of the brain) that is causing the midbrain (in the lower center of the brain) to become over active, resulting in PTSD-like symptoms.

This is a broad overview of functional neurology basics. For more information, contact my office.

One of the biggest mistakes many people make is assuming a tremor signifies Parkinson's disease. The truth is many different kinds of tremors exist for different reasons. You can distinguish between them by knowing some basic characteristics.

Understanding the expression of the tremor

Tremors can be grouped into three categories: action tremor, resting tremor, and physiological tremor.

Action tremor happens with movement. These tremors typically stem from a disorder of the cerebellum, the area at the back of the brain involved in movement and coordination. The more calibration the movement requires (such as touching your pinkie finger to your nose with your eyes closed), the easier it is to see this tremor. Drinking alcohol may make this tremor worse.

Resting tremor happens when the hands are totally at rest. These tremors are related to the basal ganglia, and area of the brain involved in regulating movement. Moving the hands will stop the tremor. This is the type of tremor associated with Parkinson’s disease.

Physiological tremor results from a metabolic issue affecting muscle contractions, such as too much coffee, low blood sugar, too much thyroid hormones, or certain medications. The key feature of this tremor is that it happens both at rest and in action.

Types of tremors

Those are the three primary ways tremors express themselves. Beyond that, we can identify different tremors based on what causes them.

Essential tremor is the most common tremor and is caused by a hereditary disorder of the cerebellum. You know you’re a candidate for this tremor if drinking alcohol makes it better and other family members have it. It may also occur in the head and the voice.

Orthostatic tremor occurs in the legs when a person stands up but goes away upon walking. It is related to misfiring in the autonomic nervous system, which governs unconscious bodily functions.

Dystonic tremors occur with dystonia, a disorder in which muscles contract involuntarily.

Parkinsonian tremor is a pill-rolling rest tremor and re-emergence tremor (i.e., it occurs after the arms have been held out a few moments).

Cerebellar tremors occur when the cerebellum cannot correctly calibrate muscle movements during movement, such as bringing a glass to your mouth. Vertigo and nausea may be other complaints.

A Holmes tremor is also known as wing-beating, midbrain, or rubral tremor. It is associated with strokes that impact the midbrain, as well as copper toxicity.

Palatal tremor is a rare disorder that causes rhythmic tremoring of the soft palate.

Neuropathic tremor stems from neuropathy, more often an acute autoimmune neuropathy.

Neurotoxic and drug-induced tremors, are, like they sound, induced by toxins and medications.

Psychogenic tremors are a psychiatric disorder in which the individual creates the tremor.

Functional neurology and tremors

In functional neurology, we can often lessen the severity of tremors by identifying the area of the brain causing them and then using brain rehabilitation techniques to address dysfunction in those areas. We also work with you to reduce inflammation, ensure proper brain nutrition, and improve overall metabolic health so that your brain has the best chance at improvement.