Back Clinic Chiropractic. This is a form of alternative treatment that focuses on the diagnosis and treatment of various musculoskeletal injuries and conditions, especially those associated with the spine. Dr. Alex Jimenez discusses how spinal adjustments and manual manipulations regularly can greatly help both improve and eliminate many symptoms that could be causing discomfort to the individual. Chiropractors believe among the main reasons for pain and disease are the vertebrae’s misalignment in the spinal column (this is known as a chiropractic subluxation).
Through the usage of manual detection (or palpation), carefully applied pressure, massage, and manual manipulation of the vertebrae and joints (called adjustments), chiropractors can alleviate pressure and irritation on the nerves, restore joint mobility, and help return the body’s homeostasis. From subluxations, or spinal misalignments, to sciatica, a set of symptoms along the sciatic nerve caused by nerve impingement, chiropractic care can gradually restore the individual’s natural state of being. Dr. Jimenez compiles a group of concepts on chiropractic to best educate individuals on the variety of injuries and conditions affecting the human body.
The human brain is the human body’s control center. It is a fundamental structure in the nervous system, which also includes the spinal cord and a system of nerves and neurons. The nervous system controls every structure and function in the human body. When the brain is damaged, it can ultimately affect the function of the nervous system, including memory, sensation, and even personality. Brain disorders include any health issues which affect the brain. This includes health issues due to: �
genetics
illness
trauma or injury
What are the Different Types of Brain Disorders?
There is a wide array of different brain disorders which can vary tremendously in symptoms and grade of severity. Below, we will demonstrate the different types of brain disorders and discuss several of the most common types of brain disorders. �
Brain Injuries
Brain injuries are generally caused by blunt trauma or injury. Trauma or injury can damage brain tissue, neurons, and nerves. This damage affects the brain’s capacity to communicate with the rest of the human body. Several brain injuries include: �
hematomas
blood clots
contusions or bruising of brain tissue
cerebral edema or swelling inside the skull
concussions
strokes
Common symptoms of brain injuries include: �
vomiting
nausea
speech difficulty
bleeding from the ear
numbness
paralysis
memory loss
problems with concentration
Furthermore, other common symptoms you may develop include: �
high blood pressure
low heart rate
pupil dilation
irregular breathing
Depending on the type of brain injury, treatment may include medication, rehabilitation, or brain surgery. Approximately half of the people with acute brain injuries require surgery to remove or repair damaged tissue and to relieve stress. Individuals with mild brain injuries may not require any treatment past medication. Many people with brain injuries may also require: �
physical therapy
speech and language therapy
psychiatry
Brain Tumors
Occasionally, brain tumors can develop and they can become quite dangerous. These are known as primary brain tumors. In other instances, cancer from other regions of the body can spread into the brain. These are known as secondary or metastatic brain tumors. Brain tumors may be categorized as either malignant (cancerous) or benign (noncancerous). Healthcare professionals also categorize brain tumors as grades 1, 2, 3, or 4. Higher numbers indicate more severe cancers. �
The main cause of the majority of brain tumors is largely unknown. They can occur in people of all age. Symptoms of brain cancers generally depend on the size and location of the tumor. The most common symptoms of brain tumors include: �
headaches
seizures
tingling sensations or numbness in the arms or legs
nausea
vomiting
changes in personality
difficulty with movement or balance
changes in hearing, speech, or vision
The type of treatment you’ll receive for the brain tumors depends on a variety of different factors, such as the size of the brain tumor, your age, and your overall health and wellness. The main types of treatment for brain tumors include: �
chemotherapy
radiation therapy
surgery
Neurodegenerative Diseases
Neurodegenerative disorders cause the brain and the nerves to gradually deteriorate as people age. They can affect an individual’s personality and cause confusion. They are also able to destroy the brain’s tissue and nerves. Brain disorders like Alzheimer’s disease may develop over time with age. It can slowly impair memory and thought processes. Other diseases, such as Tay-Sachs disease are genetic and can develop at any age. Common neurodegenerative diseases include: �
Huntington’s disease
ALS (amyotrophic lateral sclerosis), or Lou Gehrig’s disease
Parkinson’s disease
all types of dementia
Several of the most common symptoms of neurodegenerative diseases include: �
Memory loss
forgetfulness
apathy
anxiety
agitation
a loss of inhibition
mood changes
Neurodegenerative diseases can ultimately cause irreversible damage and symptoms generally have a tendency of becoming worse as the disease progresses. New symptoms can also continue to develop over time. Unfortunately, there’s no treatment for neurodegenerative diseases, however, treatment can help improve symptoms. The treatment goal for these health issues is to reduce symptoms and maintain quality of life. Treatment often involves the use of medications to control symptoms. �
Mental Disorders
Mental disorders, or mental illnesses, are a wide variety of health issues which affect behavior patterns. Much like the brain disorders previously mentioned, symptoms can also vary. Several of the most commonly diagnosed mental disorders are: �
depression
anxiety
bipolar disorder
post-traumatic stress disorder (PTSD)
schizophrenia
The symptoms of mental disorders can vary based on the health issue. Different people can experience exactly the same mental disorders differently. Make sure to speak with a healthcare professional if you notice any changes in your behavior, thought patterns, or mood. The two major types of treatments for mental disorders are medication and psychotherapy. Different treatments work better for different health issues. Many individuals find that a combination of both is best. �
If you believe that you may have a mental disorder, it’s important to speak to a healthcare professional for diagnosis in order to determine which treatment program is suitable for you. There are many resources available to treat mental disorders. �
What are the Risk Factors for Brain Disorders?
Brain disorders can affect anyone, however, the risk factors can ultimately vary for different types of brain disorders. Traumatic brain injury is most common in children under 4 years old, young adults between 15 and 25 years old, and adults 65 and older. Brain tumors may affect any individual at any given age. An individual’s risk for developing brain disorders generally depends on the individual’s genetics and their vulnerability to environmental risk factors, such as radiation. �
Older age and family history are the most important risk factors for neurodegenerative diseases. Mental disorders are extremely common. About 1 in 5 American adults have experienced a mental health issue. Your risk may be greater if you: �
have a family history of mental illness
have or have had traumatic or stressful life experiences
have a history of misusing drugs or alcohol
have or have experienced a traumatic brain injury
There are a variety of treatment approaches which can help improve brain disorders. The outlook for people with brain disorders depends on the type and severity of the brain disorder. Several of these health issues can be easily treated with the utilization of medication and other therapy methods and techniques. Other brain disorders, such as neurodegenerative diseases and several types of traumatic brain injuries have no cure, however, treatment approaches can help improve symptoms. – Dr. Alex Jimenez D.C., C.C.S.T. Insight
The purpose of the article above is to discuss the different types of brain disorders, including neurodegenerative diseases. Neurological diseases are associated with the brain, the spine, and the nerves. The scope of our information is limited to chiropractic, musculoskeletal and nervous health issues as well as functional medicine articles, topics, and discussions. To further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900 . �
Curated by Dr. Alex Jimenez �
Additional Topic Discussion: Chronic Pain
Sudden pain is a natural response of the nervous system which helps to demonstrate possible injury. By way of instance, pain signals travel from an injured region through the nerves and spinal cord to the brain. Pain is generally less severe as the injury heals, however, chronic pain is different than the average type of pain. With chronic pain, the human body will continue sending pain signals to the brain, regardless if the injury has healed. Chronic pain can last for several weeks to even several years. Chronic pain can tremendously affect a patient’s mobility and it can reduce flexibility, strength, and endurance.
Formulas for Methylation Support
XYMOGEN�s Exclusive Professional Formulas are available through select licensed health care professionals. The internet sale and discounting of XYMOGEN formulas are strictly prohibited.
Proudly,�Dr. Alexander Jimenez makes XYMOGEN formulas available only to patients under our care.
Please call our office in order for us to assign a doctor consultation for immediate access.
If you are a patient of Injury Medical & Chiropractic�Clinic, you may inquire about XYMOGEN by calling 915-850-0900.
�
For your convenience and review of the XYMOGEN products please review the following link.*XYMOGEN-Catalog-Download �
* All of the above XYMOGEN policies remain strictly in force. �
Subluxation describes what happens when the spinal joints get shifted out of alignment. This can be caused by:
Stress
Trauma
Chemical imbalance
The nervous system, which consists of the (spine/nerves/brain) is the central headquarters of the body. Subluxation removal helps the body function at its optimum level.
Chiropractic adjustments reduce pressure on the nerves and ease the flow of communication and signals going back and forth.
These adjustments trigger the release of endorphins, which cause instant pain relief.
Our hips are made durable, but with age and normal wear and tear, this cartilage wears down, which can lead to injury.
This also includes the:
Muscles
Tendons
Bones in and around the hip
And can be caused by a number of conditions, including:
Arthritis
Avascular necrosis (osteonecrosis)
Cancers
Bursitis
Hip fractures
Hip labral tear
Muscle/tendon strain
Tendinitis
If adjustments seem to be only temporary, this could be an indicator of problems beyond the spine.
Pain or other symptoms in the body start with the body�s foundation: the feet.
When we walk there are incremental-segmental movements of the spine that are small motions but are very important in proper function.
If there are foot problems:
Spinal subluxations
Pain
Degeneration throughout the body can happen.
Research has found that poor foot mechanics can create severe problems that affect the normal functions of the:
Ankle
Knee
Hip
Back
Symptoms of Vertebral Subluxation
Neck and back pain
Headaches
Dizziness
Balance issues
Spine muscle spasms
Tightness
Weakness
Spinal mobility
Pain
Numbness
Tingling
Joint pain
Tenderness
Stiffness
Treatment
If you are experiencing any of these symptoms, subluxation could be the cause.
Chiropractic treatment and custom orthotics are the best way to correct the subluxation.
Chiropractors are experienced in finding and correcting these problems. And the custom orthotics can help keep you and your spine in perfect alignment.
Get Rid of *LOW BACK PAIN* with Custom Foot Orthotics | El Paso, TX (2019)
Approximately 80 percent of the population will experience some type of back pain sometime throughout their lifetime. Low back pain and sciatica are several of the most common complaints frequently reported in a doctor office setting. But, did you know that low back pain and sciatica can be caused due to foot problems? Custom-made functional foot orthotics can help support and promote the natural alignment of the spine. Poor posture associated with foot problems and other health issues can be corrected through the utilization of custom-made functional foot orthotics. Because every individual has unique foot anatomy, custom-made foot orthotics can be beneficial for a variety of people with foot problems and other health issues. Dr. Alex Jimenez is the non-surgical choice for foot problems.
What’s Afoot
Although many people try to treat their low back pain on their own first, one of the fastest and best ways to treat it is through custom orthotics, which actually optimize the performance of your entire body, not just your feet and lower back. Over-the-counter orthotics do not provide proper support and can even cause more damage to the body. Chronic lower back pain is not a normal thing that has to do with age or lifestyle.
If you are experiencing lower back pain, call a chiropractor and ask about how custom orthotics can help you.
NCBI Resources
Chiropractors use specific methods to return the vertebrae in their proper locations or muster them to allow them to go freely when subluxations happen. These techniques are called spinal manipulations or adjustments. During an adjustment, the vertebra is freed in the misaligned location and returned to the right place in the spinal column. The adjustment permits the entire body to cure and preserve homeostasis once performed.
In humans, the nervous system consists of the central nervous system and the peripheral nervous system. The central nervous system, or CNS, consists of the brain and the spinal cord. It is in the CNS where the review of information occurs. The peripheral nervous system, or PNS, consists of the neurons and parts of neurons outside the CNS, including sensory neurons and motor neurons. Sensory neurons bring signals into the CNS, and motor neurons carry signals out of the CNS. �
The cell bodies of PNS neurons, such as the motor neurons which control skeletal muscles, are found in the CNS. These motor neurons have long extensions, known as axons, which run from the CNS all the way to the muscles with which they connect with or innervate. The cell bodies of additional PNS neurons, such as the sensory neurons which provide information on touch, pain, position, and temperature, are found outside the CNS, in which they are found in clusters known as ganglia. The axons of peripheral nerves which run through a common pathway are bundled together to form nerves. �
Types of Neurons
According to their roles, the neurons within the human nervous system can be separated into three different categories, including the sensory neurons, the motor neurons, and the interneurons. Below, we will describe the types of neurons. �
Sensory Neurons
The sensory neurons get information about what’s going on inside and outside the human body and they bring that information into the CNS where it could become processed. By way of instance, if you pick up a hot coal, the sensory neurons with nerve endings in your fingertips would communicate the information to your CNS that the hot coal is really hot. �
Motor Neurons
The motor neurons get information from other neurons and they communicate commands to your muscles, organs, and glands. In the previous circumstance where you picked up a hot coal, the motor neurons innervating the structures on your fingers would cause your hand to let go of the hot coal. This is only one example of the role of motor neurons. �
Interneurons
The interneurons, which can only be found in the CNS, connect one neuron to another. They get information from other neurons and communicate information to other neurons. When picking up a hot coal, the signals from the sensory neurons in your palms communicate to the interneurons on the spinal cord. Several of these interneurons communicate to the motor neurons controlling your finger muscles and cause your hand to let go of the hot coal. The motor neurons may communicate the signals to the interneurons in the spinal cord where it would ultimately create the perception of pain in the brain. �
Interneurons are the most numerous types of neurons and they are involved in processing information, both through basic neural circuits, such as those triggered by picking up a hot coal, as well as in much more complicated circuits in the brain. Different combinations of interneurons in the brain and spinal cord allow you to draw the conclusion that objects which look similar to a lump of hot coal shouldn’t be picked up and they will also help keep that information for future reference. �
Anatomy of a Neuron
Neurons, similar to other cells, consist of a cell body known as the soma. The nucleus of the neuron is found in the soma. Neurons need to create proteins and most neuronal proteins are synthesized in the soma. Various processes, known as appendages or protrusions, run from the cell body. These include many small, branching processes, known as dendrites, and another process which is generally longer than the dendrites, known as the axon. It is possible to generalize that most neurons have three standard functions. These neuronal functions are mirrored in the anatomy of the neuron, including: �
Communicating information or signals.
Combining incoming signals to determine whether or not the information should be passed along.
Communicate information or signals to target cells, including muscles, glands, or other neurons.
Dendrites
The first two functions of the neuron, receive and process incoming signals or information, generally occur in the dendrites and cell body. Incoming signals can be either excitatory, which means that they tend to make the neuron generate an electrical impulse, or even inhibitory, which means that they tend to keep the neuron from generating an electrical impulse. �
Most neurons receive many incoming signals or information throughout the dendrites. A single neuron can have more than one pair of dendrites and they may receive thousands of incoming information or signals. Whether or not a neuron is excited into firing an electrical impulse is dependent on the amount of each of the excitatory and inhibitory signals, or information, it receives. If the neuron does end up firing an electrical impulse, the action potential or nerve impulse runs down the axon. �
Axons
The axon separates into many branches and develops bulbous swellings known as axon terminals or neural terminals. These axon terminals communicate with target cells. Axons are different from dendrites in several ways, as demonstrated below. �
The dendrites generally taper and are frequently covered with little bumps known as spines. The axon generally stays the same diameter for most of its length and doesn’t have spines.
The axon exits from the cell body through a special region known as the axon hillock.
Last but not least, many axons are covered with a special insulating compound known as the myelin, which helps them communicate the nerve impulse quickly. The myelin is never found on dendrites.
Synapses
Neuron-to-neuron communications are created on the dendrites and cell bodies of other neurons. These connections, known as synapses, are regions where information is taken from the first neuron, or the presynaptic neuron, to the target neuron, or the postsynaptic neuron. The synaptic connections between neurons and skeletal muscles are known as neuromuscular junctions and the connections between neurons and smooth muscle cells or glands are known as neuroeffector junctions. �
Signals communicate through chemical messengers known as neurotransmitters. When an action potential runs down an axon and reaches the axon terminal, it triggers the release of neurotransmitters from the presynaptic cell. Neurotransmitters run through the synapse and connect to membrane receptors on the postsynaptic cell, communicating excitatory or inhibitory information. The first two basic functions of the neuron are important for the third basic function of the neuron. �
The third function of the neuron, communicating signals to target cells, is also completed through the function of the axon and the axon terminals. Just as one neuron may communicate through many presynaptic neurons, it may also ultimately communicate through synaptic connections on numerous postsynaptic neurons throughout different axon terminals. �
Glial Cells
The glia, or glial cells, are fundamental to the nervous system. There are more glial cells in the brain than there are neurons. There are four types of glial cells in the adult human nervous system. Three of these, the astrocytes, the oligodendrocytes, and the microglia, are only found in the central nervous system or the CNS. The fourth, the Schwann cells, are only found in the peripheral nervous system or the PNS. Below, we will discuss the four types of glial cells, or glia, and their functions. �
Astrocytes are the most numerous types of glial cell. There are also many different types of astrocytes and they each have a variety of different functions, such as regulating blood flow in the brain, maintaining the composition of the fluid which surrounds the neurons, and maintaining communications between nerves in the synapse. During development, astrocytes help neurons find their way and add to the development of the blood-brain barrier, which also helps protect the brain. � Microglia are associated to the macrophages of the immune system and act as scavengers to remove dead cells and debris. �
The oligodendrocytes of the CNS and the Schwann cells of the PNS share a similar function. Both types of glia, or glial cells, create myelin, or the insulating compound which develops a sheath around the axons of many neurons. Myelin increases the speed with which an action potential runs down the axon and it plays a fundamental role in nervous system function. �
Additional types of glial cells, along with the four main types of glia, include satellite glial cells and ependymal cells. �
Satellite glial cells cover the cell bodies of neurons in PNS ganglia. Satellite glial cells are believed to support the role of the nerves and function as a protective barrier, however, their role is still misunderstood. Ependymal cells, which line the ventricles of the brain and the central canal of the spinal cord, have hairlike cilia which help improve the flow of the cerebrospinal fluid found within the ventricles and spinal tract. The human nervous system is necessary for our function. �
Neurons are special cells found within the nervous system which communicate with other neurons in unique ways. The neuron is the basic working unit of the brain and it is designed to communicate information, or signals, to muscles, organs, gland, and other nerve cells. Most neurons consist of a cell body, an axon, and dendrites. The cell body contains the nucleus and the cytoplasm. Understanding the structure and function of the neuron is fundamental for overall health and wellness. – Dr. Alex Jimenez D.C., C.C.S.T. Insight
The purpose of the article above is to discuss the purpose of functional neurology in the treatment of neurological disease. Neurological diseases are associated with the brain, the spine, and the nerves. The scope of our information is limited to chiropractic, musculoskeletal and nervous health issues as well as functional medicine articles, topics, and discussions. To further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900 . �
Curated by Dr. Alex Jimenez �
Additional Topic Discussion: Chronic Pain
Sudden pain is a natural response of the nervous system which helps to demonstrate possible injury. By way of instance, pain signals travel from an injured region through the nerves and spinal cord to the brain. Pain is generally less severe as the injury heals, however, chronic pain is different than the average type of pain. With chronic pain, the human body will continue sending pain signals to the brain, regardless if the injury has healed. Chronic pain can last for several weeks to even several years. Chronic pain can tremendously affect a patient’s mobility and it can reduce flexibility, strength, and endurance.
Formulas for Methylation Support
XYMOGEN�s Exclusive Professional Formulas are available through select licensed health care professionals. The internet sale and discounting of XYMOGEN formulas are strictly prohibited.
Proudly,�Dr. Alexander Jimenez makes XYMOGEN formulas available only to patients under our care.
Please call our office in order for us to assign a doctor consultation for immediate access.
If you are a patient of Injury Medical & Chiropractic�Clinic, you may inquire about XYMOGEN by calling 915-850-0900.
�
For your convenience and review of the XYMOGEN products please review the following link.*XYMOGEN-Catalog-Download �
* All of the above XYMOGEN policies remain strictly in force. �
Functional neurology primarily focuses on the fundamentals of neuron health and it is mainly based on neuroplasticity theories. It’s believed that the brain and the nervous system are capable of changing, and can become malleable, due to a reaction to certain stimulation. The brain can be shaped by sensory, motor, cognitive, or emotional experiences. �
The creation of synapses in the nervous system depends on the stimulation they receive. Neurons which receive too much stimulation are the ones which become stronger and those which don’t receive stimulation become weaker and eventually diminish. It is believed that it is possible to create new neurons even after there has been damage to the nervous system. �
The Role of Functional Neurology
Functional neurology evaluates changes in the nervous system before these become severe health issues. The practice of functional neurology has been adopted by several modalities of practice, such as chiropractic, psychology, occupational therapy and even by conventional healthcare professionals. Functional neurology is commonly practiced by chiropractors. �
The practice of neurology involves applying neuroscience research from laboratory studies to determine how it can be practically applied in health care. The brain is protected by supporting the nervous system. The ultimate goal of functional neurology is to treat brain and nervous system health issues without the utilization of drugs or together with conventional treatment approaches. Functional neurologists can help treat a wide variety of neurological health issues, including: �
Neurodegenerative disorders: Alzheimer�s disease, Parkinson�s disease, dementia, and multiple system atrophy.
Demyelinating conditions: Multiple sclerosis, transverse myelitis, and leukodystrophies.
Trauma and brain injuries: Concussions and whiplash-associated disorders.
Vestibular conditions: Motion sickness, dizziness/disequilibrium, labyrinthitis, vertigo, and Meniere’s disease.
Movement disorders: Tics, restless leg syndrome, myoclonus, and dystonia.
Neuro-developmental conditions: Autism spectrum disorders, ADHD, Asperger’s syndrome, Tourette syndrome, dyslexia, processing disorders, and global developmental delay.
Headaches and pain syndromes: Cluster headaches, complex regional pain syndrome, migraines, and fibromyalgia
Functional neurological disorders which are best referred to as a group of physical, sensory and cognitive symptoms which do not seem to have an identifiable organic etiology.
Functional Neurology Treatment
The primary goal of functional neurology is to promote, support, and restore the optimal function of the brain and the nervous system, as opposed to the absence of pathology. Sometimes it’s not always possible to determine the natural source of a person’s neurological disease and its symptoms. Functional neurology can be particularly beneficial in these instances. �
The patient’s medical history and a non-invasive evaluation are required for diagnosis. Treatment is determined based on the patient’s current and targeted well-being. Any blood tests, x-rays, MRIs and/or other tests are also evaluated. During the evaluation, the healthcare professional will observe all aspects of the patient, including eye movements and posture, which can demonstrate the function of the brain and the nervous system. Blood pressure, pulse, and reflexes are also evaluated. �
Neuro-developmental conditions and behavioral disorders are generally treated with functional neurology. Anxiety is commonly increased in patients with these type of health issues, therefore, it is recommended that the non-invasive evaluation is performed in a way which does not trigger anxiety in the patient. Functional neurology treatment is individualized and every part of the treatment approach is customized to the individual’s treatment requirements. �
Functional neurology emphasizes on encouraging patients to practice self-care so that face-to-face treatment with a healthcare professional does not continue for months or years without end. Home exercise programs are developed to treat the associated health issues, meaning that functional neurology treatment is incorporated into the patient’s daily activities. �
Biochemistry and Nutrition in Functional Neurology
Functional neurology treatment focuses on retraining the brain. Neurons need energy and stimulation to survive and thrive, therefore, functional neurology treatment may involve exercises, such as eye exercises, cognitive activities, balancing activities, and joint adjustments. Different stimulation can affect different regions and pathways in the human brain. �
Moreover, functional neurology treatment may also involve a nutritional and biochemical approach by eliminating several factors which may potentially affect neurons. These can ultimately include toxins, chemicals, and infection, among other factors. Dietary modifications and supplementation may also be included to provide optimal energy for neurons. �
An individualized treatment approach is applied to each individual otherwise there exists the risk of over-stimulating and exceeding the capacity of a patient’s nervous system. The goal of functional neurology treatment is to improve brain and nervous system health, neural processing, communication, and all signaling involving the brain and the entire human body. �
Functional neurology focuses on the diagnosis and treatment of the human brain and the nervous system utilizing sensory and cognitive based treatment methods and techniques to promote, support, and restore neuroplasticity, integrity, and functional optimization. Functional neurology can be utilized to help improve a variety of neurological diseases and health issues, including Alzheimer’s disease. Functional neurology is frequently practiced by chiropractors. – Dr. Alex Jimenez D.C., C.C.S.T. Insight
The purpose of the article above is to discuss the purpose of functional neurology in the treatment of neurological disease. Neurological diseases are associated with the brain, the spine, and the nerves. The scope of our information is limited to chiropractic, musculoskeletal and nervous health issues as well as functional medicine articles, topics, and discussions. To further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900 . �
Curated by Dr. Alex Jimenez �
Additional Topic Discussion: Chronic Pain
Sudden pain is a natural response of the nervous system which helps to demonstrate possible injury. By way of instance, pain signals travel from an injured region through the nerves and spinal cord to the brain. Pain is generally less severe as the injury heals, however, chronic pain is different than the average type of pain. With chronic pain, the human body will continue sending pain signals to the brain, regardless if the injury has healed. Chronic pain can last for several weeks to even several years. Chronic pain can tremendously affect a patient’s mobility and it can reduce flexibility, strength, and endurance.
Formulas for Methylation Support
XYMOGEN�s Exclusive Professional Formulas are available through select licensed health care professionals. The internet sale and discounting of XYMOGEN formulas are strictly prohibited.
Proudly,�Dr. Alexander Jimenez makes XYMOGEN formulas available only to patients under our care.
Please call our office in order for us to assign a doctor consultation for immediate access.
If you are a patient of Injury Medical & Chiropractic�Clinic, you may inquire about XYMOGEN by calling 915-850-0900.
�
For your convenience and review of the XYMOGEN products please review the following link.*XYMOGEN-Catalog-Download �
* All of the above XYMOGEN policies remain strictly in force. �
Chiropractic along with Other? Natural Treatments Can Help Reduce the Opioid Epidemic
As of now, there are over 2 million Americans dependent on opioids. For most of these individuals, the addiction comes from seeking pain management for an injury or chronic condition. The opioid crisis has become a national emergency causing overdose remedies to be sold over-the-counter.
Seeking chiropractic care can provide patients with relief, and aid in reducing any negative effects of the opioid epidemic.
The most commonly abused opioids are:
Fentanyl
Oxycodone
Tramadol
Opioids are often given to people battling cancer but are also prescribed following surgery and for people with chronic pain.
Taking opioids over a long period of time is the most dangerous because the effects can trick your brain to thinking the drugs are necessary to live.
Opioids are a convenient and fast remedy for pain, but only provide pain relief, and do not treat the actual issues.
That is why opioids should be a last resort.
A chiropractor can assess your body from head to toe and provide pain relief through:
Adjustments
Massage
Acupuncture
Electromagnetic therapy
Chiropractic is a drug-free approach to pain relief and pain management.
The American College of Physicians (ACP) recommends the use of non-invasive, drug-free treatments such as Chiropractic care, first for chronic and acute lower back pain.
Lower back pain is one of the primary causes of opioid dependency.
Lower back pain can be difficult to treat, due to identifying and the cause.
Many doctors prescribe pain killers to provide comfort, while the actual problem goes untreated.
Chiropractors can identify the root cause of the pain.
Lower back pain can be caused by issues with the feet, ankles, knees, or hips.
Chronic back pain is due to some form of musculoskeletal weakness or imbalance.
An imbalance in one or both of the feet can cause problems throughout the entire body, especially placing stress on the lower back. Chiropractors are trained to examine the feet when a patient complains of back pain. Once the cause is identified, they can treat an individual without any prescription drugs.
Treatments for chronic pain typically include:
Chiropractic adjustments
Custom orthotics to help maintain the effectiveness of the adjustments
You can be examined for custom orthotics in less than five minutes and have them sent directly to you or pick them up.
Custom orthotics help us stand for extended periods, and with walking/working out.
Custom orthotics help you function without pain, and prescription-free.
�Treat pain without the use of surgery and addictive drugs.
Control *FOOT MOTION & POSTURE* with Functional Foot Orthotics | El Paso, Tx (2019)
If you have low back pain�or have had it, you are not alone. Experts estimate that around�80% of people�will experience some type of back problem at some point in their lives.�The Global Burden of Disease 2010 lists low back pain as the number one cause of disability worldwide. The good news is the majority of back pain is mechanical in origin or is not organic. This means that infection, cancer, fracture, inflammatory arthritis, and other serious conditions are not the cause. In fact, you may benefit by looking to your feet, knees,�and hips as the culprits.
What’s Afoot
When there are problems with the feet, it can cause problems through the legs and all the way to the spine. This can cause the ankle to pronate, meaning it rolls inward. This alters the way the�bones of the foot�line up which extends through the tibia, or shin bone.
NCBI Resources
The most commonly prescribed opioids are hydrocodone products. They are used to treat pain from injuries, dental work, and typically moderate pain. Milder pain is often treated with codeine but it is also used to treat coughing as well as severe diarrhea. Overall, opioids are used to treat everything from cancer pain to post-op pain to osteoarthritis.
As humans, we depend on microbiomes to stay alive. Microbiomes are essential in fighting off germs and maintaining health. The development of microbiomes begins in utero where the microbes have been isolated to the placenta, fetal membranes, amniotic fluid, and umbilical cord blood, but are mainly transferred from mother to child during birth in a process referred to as “seeding” (1,2). “Seeding”� occurs as the child passes through the mothers vaginal canal and becomes coated in her microbiome. In addition to this, small amounts of microbiomes get transferred to the child as the mother breastfeeds. This early introduction from mother to infant serves as an inoculation process with long term health outcomes for the newborn (2). With the number of cesarean births being higher this decade than in the past, you may find yourself asking, “How does a cesarean birth affect my child’s microbiomes?”
Vaginal
With vaginal births still being the most common way of delivery (68%), these children are seen to have overall better health throughout their lifetime than those born via cesarian (2). Vaginal birth is the most effective way to spread the microbiomes to the child’s skin, but studies have found that microbiomes do differ between ethnic groups. Microbiomes are made up of multiple bacterias and specifically, women with a higher pH have a smaller community of protective biomes. It has also been seen that the gut microbiota in pregnant women with gestational diabetes, tend to have an increased abundance of disease-associated microbes (2). That being said, the pH and mothers gut microbes play a significant role in the types of microbiomes that get transferred to their child.
Cesarean
There are generally two ways a child ends up being born via cesarean, labor ending in a cesarean, or a planned cesarean with no labor attempted. Children who are born via cesarean with labor attempted first, have a slightly higher number of microbiomes due to the vaginal fluids exposed to them during labor than that born elective cesarean. The most effective way a mother can transfer microbiomes to their newborn via cesarean is to “incubate” a cloth for 1 hour in their vaginal canal. When the infant is born,� the doctors rub the child’s mouth, eyes, and skin with the cloth that was previously incubated within minutes after birth (2). This process ensures that the child will have microbiomes more closely related to those born vaginally. Children born elective cesarean without using the incubation method, show fewer gut microbiomes related to their mother, but rather have more skin and oral microbes, and bacteria due to the operating room (2).
Children who are born via cesarean, whether labor was attempted first or not, are more likely to develop immune-related disorders such as asthma, allergies,� inflammatory bowel disease, and obesity (2). This is directly linked to not being “seeded” by the mother. Furthermore, adults who were born via cesarean contain a fecal microbiota that is drastically different than adults who were born vaginally (2).
The purpose of the female reproductive system is to reproduce and birth. Therefore, the best route will always be vaginal if it is safe for baby and mom. This being said, a cesarean is not a bad way to bring a child into the world. The child will just face more skin irritability and have a greater risk of developing health issues due to not receiving the same microbiomes as a child born vaginally. – Kenna Vaughn, Health Coach Insight
References:
(1) Aagaard, Kjersti, et al. �The Placenta Harbors a Unique Microbiome.� Science Translational Medicine, U.S. National Library of Medicine, 21 May 2014, www.ncbi.nlm.nih.gov/pmc/articles/PMC4929217.
(2) Dunn, Alexis B, et al. �The Maternal Infant Microbiome: Considerations for Labor and Birth.� MCN. The American Journal of Maternal Child Nursing, U.S. National Library of Medicine, 2017, www.ncbi.nlm.nih.gov/pmc/articles/PMC5648605/.
Glutamate is the main excitatory neurotransmitter in the central nervous system, or CNS, of mammals and it primarily interacts with both metabotropic and ionotropic receptors to activate and regulate postsynaptic responses. Both AMPA and NMDA receptors are fundamental mediators of synaptic plasticity, the ability of synapses to strengthen or weaken, where dysregulation of those receptors leads to neurodegeneration in a variety of disorders, including Alzheimer’s disease. �
The main difference between AMPA and NMDA receptors is that sodium and potassium increases in AMPA receptors where calcium increases along with sodium and potassium influx in NMDA receptors. Moreover, AMPA receptors do not have a magnesium ion block while NMDA receptors do have a calcium ion block. AMPA and NMDA are two types of ionotropic, glutamate receptors. They are non-selective, ligand-gated ion channels, which mainly enable the passage of sodium and potassium ions. Furthermore, glutamate is a neurotransmitter which creates excitatory postsynaptic signals in the CNS. �
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What are AMPA Receptors?
AMPA, also known as ?-amino-3-hydroxy-5-methyl-4-isoxazole-propionate, receptors are glutamate receptors which are in charge of maintaining the rapid, synaptic transmission in the central nervous system. AMPA receptors have four subunits, GluA1-4. Moreover, the GluA2 subunit is not permeable to calcium ions because it contains arginine from the TMII region. �
Furthermore, AMPA receptors are involved in the transmission of the majority of the rapid, excitatory synaptic signals. The increase of the post-synaptic response depends on the amount of receptors in the post-synaptic surface. The type of agonist which activates the AMPA receptors is ?-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid. The activation of the AMPA receptors leads to the non-selective transportation of cations, such as sodium and potassium ions, into the cell. This generates an action potential in the postsynaptic membrane. Figure 1 below demonstrates a diagram of AMPA receptors. �
What are NMDA Receptors?
NMDA, also known as N-methyl-d-aspartate, receptors are glutamate receptors which are found in the postsynaptic membrane. The NMDA receptors are made up of two varieties of subunits: GluN1 and GluN2. The GluN1 subunit is fundamental for the role of the receptor. This subunit can associate with one of the four types of GluN2 subunits, GluN2A-D. �
Furthermore, the main utilization of the NMDA receptors is to maintain the synaptic response. In the resting membrane potential, these receptors are inactive due to the creation of a magnesium block. The agonist of the NMDA receptor is N-methyl-d-aspartic acid. L-glutamate, including glycine, can connect to the receptor to activate it. Upon stimulation, NMDA receptors activate the calcium influx along with the potassium and sodium influx. Figure 2 demonstrates NMDA receptors. �
Similarities Between AMPA and NMDA Receptors
AMPA, NMDA, and kainate receptors are the three main types of glutamate receptors.
These are ligand-gated ion channels which activate and regulate sodium and potassium ions.
These are known due to the type of agonist which activates the receptor.
Moreover, the activation of these receptors produces excitatory postsynaptic responses or ESPSs.
Furthermore, several protein subunits connect together to form these receptors.
Difference Between AMPA and NMDA Receptors
AMPA receptors are best known as a type of glutamate receptor which activates in excitatory neurotransmission and connects ?-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid which additionally works as a cation channel. Where the NMDA receptors are best known as a type of glutamate receptor which helps in excitatory neurotransmission and also connects N-methyl-D-aspartate. This is the most fundamental difference between AMPA and NMDA receptors. �
AMPA receptors have four subunits, GluA1-4 while NMDA receptors have a GluN1 subunit associated with one of the four GluN2 receptors, GluN2A-D. Activation can also be a difference between AMPA and NMDA receptors. AMPA receptors are only activated by glutamate while NMDA receptors are activated by different agonists. The agonist for AMPA receptors is ?-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid where the agonist for NMDA receptors is N-methyl-d-aspartic acid. �
Ion influx is a fundamental difference between AMPA and NMDA receptors. Activation of AMPA receptors results in the sodium and potassium influx while the activation of NMDA receptors leads to an increase in potassium, sodium, and calcium. Another distinction between AMPA and NMDA receptors is that AMPA receptors do not contain a calcium ion where NMDA receptors contain magnesium receptors. Also, AMPA receptors are responsible for the transmission of the majority of the rapid, excitatory synaptic signals while NMDA receptors are responsible for the modulation of the synaptic response. �
AMPA receptors are glutamate receptors which lead to the influx of sodium and potassium ions. NMDA receptors are another type of glutamate receptors which result in the influx of calcium ions with potassium and sodium ions. The main difference between AMPA and NMDA receptors is the type of ion influx associated with their activation and regulation. �
Several varieties of ionotropic glutamate receptors have been demonstrated in the following article. Three of these main excitatory neurotransmitter in the central nervous system, or CNS, are ligand-gated ion channels best known as AMPA receptors, NMDA receptors, and kainate receptors. These ionotropic glutamate receptors are best referred to after the agonists which activate and regulate them: AMPA or ?-amino-3-hydroxy-5-methyl-4-isoxazole-propionate, NMDA or N-methyl-d-aspartate, and kainic acid. – Dr. Alex Jimenez D.C., C.C.S.T. Insight
The purpose of the article above is to demonstrate the difference between AMPA and NMDA receptors for brain health. Neurological diseases are associated with the brain, the spine, and the nerves. The scope of our information is limited to chiropractic, musculoskeletal and nervous health issues as well as functional medicine articles, topics, and discussions. To further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900 . �
Curated by Dr. Alex Jimenez �
Additional Topic Discussion: Chronic Pain
Sudden pain is a natural response of the nervous system which helps to demonstrate possible injury. By way of instance, pain signals travel from an injured region through the nerves and spinal cord to the brain. Pain is generally less severe as the injury heals, however, chronic pain is different than the average type of pain. With chronic pain, the human body will continue sending pain signals to the brain, regardless if the injury has healed. Chronic pain can last for several weeks to even several years. Chronic pain can tremendously affect a patient’s mobility and it can reduce flexibility, strength, and endurance.
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