ALS (AMYOTROPHIC LATERAL SCLEROSIS)
WHAT IS ALS?
Amyotrophic lateral sclerosis, ALS, or Lou Gehrig’s disease, is a progressive neurological disease that affects nerve cells in the brain and spinal cord. ALS causes progressive degeneration of motor neurons that run from the brain to the spinal cord and from the spinal cord to the body’s muscles. When the disease causes motor neurons to die, the brain loses its ability to initiate and control muscle movement. People with ALS may lose their ability to speak, eat, move, and breathe normally.
How does the Oxford Recovery Method help treat ALS?
Many approaches to treating ALS involve using Rilutek, and other medications, as well as various kinds of therapies. Sadly, for many, these medications cause side effects such as dizziness, gastrointestinal conditions, and liver function changes. And while various adjunctive therapies, such as speech therapy or psychological counseling, can be helpful, these therapies do not address the root cause of underlying nervous system imbalances.
So, what are the root causes of ALS? Recent advances in neuroscience reveal the root causes include a lack of blood flow and oxygen to the brain, lack of specific brain chemicals, and brainwave imbalances.
Let’s look at all these causes a little more in depth: Inside the brain, we have billions of brain cells, called neurons, sending electrical signals to each other, which we measure as brainwaves. These electrical signals cause the brain cells to release small chemicals called neurotransmitters, such as serotonin, dopamine, and adrenaline.
This vast network of brain cells is fed with oxygen and other nutrients by blood from over 100,000 miles of blood vessels inside the brain. For people with ALS, there is often not enough of these blood vessels supplying oxygen and important nutrients.
This lack of nutrients begins to cause brainwave imbalances, as measured by an EEG scan. This, in turn, causes a downstream effect on brain chemicals called neurotransmitters, meaning that the brain cells start producing too little or too much of the chemicals they need. People with ALS usually have elevated levels of glutamate neurotransmitters. These neurotransmitters imbalances are further exacerbated by nutritional deficiencies in the person’s diet, especially of key vitamins, minerals, antioxidants, and amino acids.
So, how do we start correcting a potentially multifaceted problem?
One of our most important tools at Oxford Recovery Center is called hyperbaric oxygen. This therapy actually causes new blood vessel growth in the brain and causes the brain to generate new stem cells which turn into new brain cells. (See our video about hyperbaric oxygen here.)
Another important tool is neurofeedback therapy. We use neurofeedback to scan your brain’s electrical signals and reset them with non-invasive feedback in the form of sound. (See our video about neurofeedback here.)
And finally, neurotransmitter therapy and nutrition coaching is used to correct nutritional deficiencies which are underlying the brain chemical imbalances—imbalances that we can find through laboratory testing we provide.
We strive to offer the most comprehensive research-based recovery program available for ALS, and we are happy to serve you by taking as much time as we need to answer your specific questions.
Therapies at Oxford Recovery CenterClick on the links below to learn about the therapies offered at Oxford Recovery Center
A specialized form of medical treatment administered by delivering 100% pure oxygen to the body through increased atmospheric pressure greater than 1.3 ATA. in an enclosed hard chamber.
The Oxford Recovery Center integrates conventional Physical Therapy and Suit Therapy programs to accelerate the development of new motor skills that strengthen muscles and teach the brain and body how to sit, stand, and walk.
The Oxford Neurofeedback program evaluates brain activity patterns and teaches self-regulation of brain function through quantitative electroencephalography (qEEG). Also known as “brain mapping,” qEEG analyzes electrical patterns at the surface of the scalp.