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.
Before and after spine surgery the surgeon and medical staff prepare you for recovery. The recovery process can take a long time and be extremely challenging.
Pain after spine surgery is normal, but how to tell if it�s beyond the typical pain during recovery?
What indicates that the surgery failed?
Chiropractor Dr. Alex Jimenez has dealt with this issue throughout his career and discusses symptoms associated with failed back surgery syndrome (FBSS, also known as failed back surgery (FBS) or post-laminectomy syndrome).
Back Pain the most common symptom
Chronic back pain is the most common symptom from failed back surgery.
With FBSS, chronic pain in one patient can be very different from pain in another.
People with FBSS can experience a range of different types of pain based on:
Spinal disorder
Spinal procedure
The underlying cause of failed back surgery syndrome
Types of back and neck pain people with failed back surgery may experience. Some may have one or more types.
Chronic pain:
Sustained pain that lasts for more than 12 weeks.
Chronic pain is the opposite of acute pain, which is short-term�severe pain.
Acute pain is expected during spine surgery recovery but should fade during the healing.
Nociceptive pain:
Localized pain that can be dull or sharp.
This is the type of pain patients may experience immediately after surgery
Example: The pain felt around where the incision was made.
When most people think of pain, nociceptive pain is the type.
Neuropathic pain (neuropathy):
Nerve-related pain is caused by damage to the nerves or spinal cord.
Neuropathic pain shoots and moves around, thus affecting large areas of the body.
Examples of this type of pain include:
Numbness
Burning
Tingling
Weakness
Abnormal sensations (called paresthesia)
Radicular pain (radiculopathy):
A branch of nerve pain (neuropathy) is called radiculopathy, or radicular pain.
Radicular pain radiates from one area to another.
Examples include from the:
Low back
Down the buttocks
Legs
Feet
And then starts all over again, or goes in a different order.
Other symptoms:
The original symptoms return:
When the symptoms that put the patient in the surgery room return, then there is a definite possibility of failed back surgery.
New pain presents:
New pain, meaning pain in a different part of the spine or a different type merits a discussion with your doctor.
Mobility Reduced :
It does take time to recover and that process can affect:
Endurance
Flexibility
Movement
However, if mobility or limitation is different from what was talked about with the surgeon or develops after recovery, then it should be discussed with your doctor.
Example: A limited range of motion in the neck or low back.
Headaches begin to present:
If headaches were not an original part of your medical history, this may point to a nerve problem.
Nerve Symptoms & Quality of Life
Neuropathic pain/ neuropathy or nerve-related pain is the most complex, debilitating, and difficult-to-treat.
People who experience this type of pain find it lowers their quality of life.
An online survey of 1,000-2000 patients that underwent low back surgery responded and revealed the following:
94% of respondents reported post-surgery low back pain
A separate study noted that nerve-related pain suffered by people with FBSS is more life-altering than pain caused by joint and nerve disorders.
Patients with FBSS and neuropathic pain go through higher levels of pain and have less quality of life/physical function compared with people with osteoarthritis, rheumatoid arthritis, and fibromyalgia.
FBS Symptoms Emergency Treatment
After surgery, it can be difficult to tell whether the pain is within the bounds of normal recovery pain.
At follow-up appointments ask questions about the progress of your recovery and about any concerns.
Pain after surgery is normal, but there are some signs and symptoms that merit emergency attention.
If you experience any of the red flag symptoms, call your doctor immediately:
Symptoms of Failed Back Surgery Syndrome Are Different for Every Patient
Every patient goes through a unique surgical experience and if it fails, patients may experience unique symptoms.
Because failed back surgery has several possible causes, the symptoms are going to be different for each patient.
Before you are discharged and even before you go under, ask your surgeon questions about what to expect during the recovery process.
Educating yourself with possible expectations during recovery, you�ll be best positioned to know when things aren�t going as they should.
Low Back Pain Management El Paso, TX Chiropractor
Denise suffered an auto accident injury which resulted in back pain. When she realized she could not sit, walk or sleep for lengthy periods of time without having painful symptoms, Denise found chiropractic care with Dr. Alex Jimenez at El Paso, TX. Once she received therapy for her automobile accident injuries, Denise experienced relief from her symptoms and she was able to execute her regular tasks once again. Thanks to the education and maintenance Dr. Alex Jimenez supplied, Denise regained her initial health and health.
Back pain is more most common, with roughly nine out of ten adults undergoing it at some time in their lifetime, and five functioning adults developing it annually. Some quote around 95 percent of Americans will experience back pain at some time in their lifetime. It is undoubtedly the typical cause of chronic pain since it’s also a substantial contributor to missed work and handicap. In the United States alone, acute cases of lower back pain are the fifth most frequent reason for doctor visits and cause 40% of missed days off work. What’s more, it is the leading cause of disability worldwide.
NCBI Resources
Aside from the obvious invasiveness of the procedure as well as recovery time and probable physical therapy that would be required as part of your aftercare. Say you have neck or back pain. How will you treat it? Many people will go to a medical doctor who will look at the symptoms, such as pain, and treat it with a prescription or over the counter medications. In some cases, they may recommend surgery to manage the pain or correct the problem.
Microglial cells make up about 10 to 15 percent of all the glial cells in the human body, which can be found in the central nervous system (CNS) and play a fundamental role in the human brain. Microglial cells are responsible for maintaining and regulating changes in the physiological and pathological condition of the CNS by changing their morphology, phenotype and function. In an average physiological state, the microglial cells are continuously in charge of controlling their environment. �
However, when the homeostasis of the brain is interrupted, the microglia change into an amoeba-like shape and become a phagocyte where they can actively reveal a variety of antigens. If the homeostasis interruption in the CNS continues, the microglial cells will then trigger at a much stronger state, which is known as microglial priming. Microglia are the “Bruce Banner” of the CNS. However, once they go into protective “Hulk” mode, primed microglia become much more sensitive to stimulation and they have a much stronger possibility of reacting to stimulation, even reacting towards normal cells. �
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Microglial priming can become a double-edged sword. As a matter of fact, primed microglia are created from different phenotypes of microglia and the phenotypes are context-dependent, which means they are associated to the sequence and duration of their exposure to different varieties of stimulation in a variety of pathologies. In the article below, we will demonstrate the effect of microglial priming on the central nervous system (CNS), especially in neurological diseases. �
Role of Microglial Cells in the CNS
Microglial cells are commonly found in the central nervous system (CNS), where they are considered to be one of the most flexible types of brain cells. Microglial cells are created from precursor cells found within mesoderm bone marrow, or more specifically found in the mesodermal yolk sac, and they are divided in different densities throughout several regions of the brain. As mentioned above, microglia will remain in a dormant state when the homeostasis of the brain remains stable. �
Microglia have a small cell body and morphological branches which extend towards all directions to help maintain and regulate the overall function of the CNS. Changes in their microenvironment can trigger microglia into an “activated� state. Research studies have demonstrated that microglia play a fundamental role in brain development and a variety of functions, including synaptic pruning and clearing out cell debris. Moreover, microglia create an immune surveillance system in the human brain and control fundamental processes associated with a variety of pathologies, including the clearance and uptake of A? and abnormal tau protein as well as the production of neurotrophic factors and neuroinflammatory factors. �
Microglial Priming Overview
Microglial priming activates when continuous interruptions in the brain’s microenvironment trigger a much stronger microglial response compared to an initial interruption which simply triggers microglial activation. Primed microglia in the CNS are also much more sensitive to possibly minor stimulation. This increased response involves microglial proliferation, morphology, physiology, and biochemical markers or phenotype. However, these changes will ultimately promote an increase in cytokines and inflammation mediator production which can have a tremendous impact on synaptic plasticity, neuronic survival, individual cognitive and behavioral function. Below is an overview of the effects of microglial priming in the CNS. �
Mechanisms of Microglial Priming in the CNS
The microenvironment of the central nervous system (CNS), by way of instance, is one of the main factors which can affect the microglial cells. Increased oxidative stress, lipid peroxidation and DNA damage associated with brain aging can all commonly trigger microglial priming. Another common factor for microglial priming includes traumatic brain injury. Research studies have shown that traumatic CNS injury activates microglia as well as the development of primed microglia. �
Many research studies have also shown that both focal and diffuse traumatic brain injury increase inflammation in the brain associated with microglia and astrocytes. CNS infections can also trigger microglial priming where viruses are the main cause of CNS infection. Both DNA and RNA viruses can trigger microglial priming including microglia and astrocytes. Recent research studies have shown that complement dysfunction can change the expression of complement receptors and trigger microglial priming after continuous activation following a variety of functions, including synapse maturation, immune product clearance, hematopoietic stem/progenitor cells (HSPC) mobilization, lipid metabolism, and tissue regeneration. �
Moreover, research studies have shown that there is increased priming of the microglia in a variety of neurological diseases. By way of instance, microglial cells with a morphological phenotype are found in large numbers in the human brain. In the last several years, research studies have suggested that neuroinflammation can continuously activate the microglia and trigger microglial priming. Furthermore, all of the previously mentioned situations are closely associated with neuroinflammation. Research studies have also demonstrated that neuroinflammation, as well as microbial debris and metabolic effects, are associated with central sensitization in neurological diseases, such as fibromyalgia, also referred to as the “brain on fire”. �
In the context of the previous situations mentioned above, microglia are primed though a series of pro-inflammatory stimulation, such as lipopolysaccharide (LPS), pathogenetic proteins (e.g., A?), ?synuclein, human immunodeficiency virus (HIV)-Tat, mutant huntingtin, mutant superoxide dismutase 1 and chromogranin A. There is also a variety of signaling pathways and it is common for different types of cells to express special pattern recognition receptors (PRRs) which can affect inflammatory signaling pathways. By way of instance, several signaling pathways, known as pathogen-associated molecular patterns (PAMPs), which can commonly increase in infected tissue, could also control microbial molecules. �
Additionally, peptides or mislocalized nucleic acids identified as misfolded proteins through a series of pathways, known as danger-associated molecular patterns (DAMPs), can also cause microglial priming. Toll-like receptors (TLRs) and carbohydrate-binding receptors commonly function in these pathways. There are also many different receptors found in microglia, including triggering receptors expressed on myeloid cells (TREM), Fc? receptors (Fc?Rs), CD200 receptor (CD200R), receptor for advanced glycation end products (RAGE), chemokine receptors (CX3CR1, CCR2, CXCR4, CCR5, and CXCR3), which can be recognized and mixed in with other signaling pathways, although some pathways are still not clear. �
Consequences of Microglial Priming in the CNS
Microglia show a low rate of mitosis in their normal state and a high rate of proliferation after microglial priming, showing that the microglia have the ability to affect cell turnover and pro-inflammation stimulation. With continued stimulation, microglia activate from their resting state, changing into amoeboid microglial cells in morphology. However, the changes in the shape of the microglia cannot differentiate the characteristics of microglial activation and the function of primed microglia depends on their phenotypes which are associated with receptors and molecules which they create and recognize. �
The different types of tissue macrophages, under microenvironmental impetus, are able to differentiate M1 and M2 phenotypes. First, M1 polarization, also known as classical activation, ultimately needs interferon-? (IFN-?) to be mixed with TLR4 signaling which then causes the production of inducible nitric oxide synthases (iNOS), reactive oxygen species (ROS), proinflammatory cytokines, and finally, ultimately reduces the release of neurotrophic factors, ultimately causing inflammation with increased markers of main histocompatibility complex II (MHC II), interleukin-1? (IL-1?) and CD68. �
Moreover, M2 polarization, also known as alternative activation, is ultimately believed to be associated with tissue-supportive in the situation of wound healing, reducing inflammation and improving tissue repair of collagen form. They trigger in response to IL-4 and IL-13 in vivo. M2 polarization is characterized by the increased expression of neurotrophic factors, proteases, enzymes arginase 1 (ARG1), IL-10 transforming growth factor-? (TGF-?), scavenger receptor CD206 and coagulation factors as well as improving phagocytic activity. As a matter of fact, there are currently no clear boundaries between the two polarizations and the M1 phenotype shares many similar characteristics with the M2 phenotype. �
Another phenotype of primed microglia, known as acquired deactivation, has been recently discovered. This new phenotype overlaps with M2 and has the ability to improve anti-inflammatory and functional recovery. Additionally, a research study conducted ultra-structural analyses and identified a brand-new phenotype, known as �dark microglia�, which is rarely seen in the microglial cell’s resting state. Systemic inflammation triggers microglia into an activated state to promote cell and tissue recovery and achieve homeostasis. Microglial priming is ultimately the second interruption in the CNS microenvironment. �
The primed microglia is a double-edged sword for brain health. Many research studies in vivo and in vitro have shown that neurological diseases are associated with microglial activation. The inflammatory phenotypes of the microglia create neurotoxic factors, mediators and ROS which can affect the CNS. Primed microglia play a fundamental and beneficial role in neuronal regeneration, repair, and neurogenesis. Primed microglia are also much more sensitive and respond much stronger to brain injury, inflammation, and aging as well as increase the activation of microglial cells by switching from an anti-inflammation, potentially protective phenotype to a pro-inflammation destructive phenotype, as shown in (Figure 1). �
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In the early stages of microglial priming, the ability and function to phagocytize cell debris, misfolded proteins, and inflammatory medium are increased where more protective molecules, such as IL-4, IL-13, IL-1RA, and scavenging receptors, are created. The changes can affect wound healing and damage tissue repairment, neuron protection, and homeostasis recovery. Classically activated microglia (M1) make up a large proportion of all microglia and promote an increased creation of neurotoxic factors, such as IL-1?, TNF-?, NO and H2O2 (6), where more microglia are primed immediately afterward. �
This increased and extended neuroinflammation caused by primed microglia can ultimately be associated with the development and clustering of the protein tau and A?. Furthermore, it can lead to loss of neurons as well as the decrease of cognitive function and memory, such as in Alzheimer’s disease. Although the mechanisms are not clear enough, people have reached an agreement that primed microglia cause a chronic proinflammatory response and a self-perpetuating cycle of neurotoxicity. And this is believed to be the key factor in brain health issues resulting in neurological diseases. �
Microglia are known as the protectors of the brain and they play a fundamental role in maintaining as well as regulating the homeostasis of the CNS microenvironment. Constant stimulation causes the microglia to trigger at a much stronger state, which is known as microglial priming. Microglial cells are the “Bruce Banner” of the CNS. However, once they go into protective “Hulk” mode, primed microglia become much more sensitive to stimulation and they have a much stronger possibility of reacting to stimulation, even reacting towards normal cells. �- Dr. Alex Jimenez D.C., C.C.S.T. Insight
Microglial cells make up about 10 to 15 percent of all the glial cells in the human body, which can be found in the central nervous system (CNS) and play a fundamental role in the human brain. Microglial cells are responsible for maintaining and regulating changes in the physiological and pathological condition of the CNS. 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.
Neural Zoomer Plus for Neurological Disease
Dr. Alex Jimenez utilizes a series of tests to help evaluate neurological diseases. The Neural ZoomerTM Plus is an array of neurological autoantibodies which offers specific antibody-to-antigen recognition. The Vibrant Neural ZoomerTM Plus is designed to assess an individual�s reactivity to 48 neurological antigens with connections to a variety of neurologically related diseases. The Vibrant Neural ZoomerTM Plus aims to reduce neurological conditions by empowering patients and physicians with a vital resource for early risk detection and an enhanced focus on personalized primary prevention. �
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.
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For your convenience and review of the XYMOGEN products please review the following link.*XYMOGEN-Catalog-Download�
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What exercise/stretches help reduce sciatic nerve pain?
Here are 4 exercise/stretches that your chiropractor/physical therapist may recommend to help you reduce sciatic nerve pain:
Pelvic tilt
Knee to chest
Lower trunk rotations
Arm and leg extensions
Pelvic Tilt
Its purpose is to strengthen the lower abdominal muscles and stretch the lower back.
How to do it:
Lie on back
Exhale and tighten abdominal muscles while pushing the belly button toward the floor and flatten the lower back
Hold the position for 5 seconds
Repeat 10 times holding the position for 5 seconds each
Am I doing it right?
Place the pinky finger on the hip bone and thumb on the lowest rib (same side).
When tightening the abdominal muscles, the amount of space between the pinky finger and thumb should get smaller.
Pelvic tilts help strengthen the lower abdominal muscles and stretch the low back.
Knee to Chest
Its purpose is to help reduce nerve compression in the low back, that can help alleviate lower back pain.
Lie on back
Start with either� left or right knee and use hands to gently pull the bent knee toward chest
Hold for 10 seconds
Repeat movement on opposite knee
Perform 3 to 5 times holding position for 10 seconds each
Use hands to gently pull both knees toward chest
Hold for 10 seconds
Repeat movement with both knees 3 to 5 times holding position for 10 seconds each
Knee to chest exercise/stretches can help reduce nerve compression on the lumbar spine alleviating lower back pain.
Lower Trunk Rotation
Its purpose is to increase the spine�s mobility and flexibility.
Lie on back with both knees bent upright and both feet flat on the floor (aka the hook lying position).
Hold both knees together, rotate knees to one side
Hold for 3 to 5 seconds
There will be a gentle stretching sensation on the opposite side of lower back and hip area
Contract abdominal muscles and rotate both knees to opposite side
Hold for 3 to 5 seconds
Repeat 10 times on each side
Lower body rotations can help you strengthen your lower abdominal muscles and stretch your low back.�
All Fours Opposite Arm and Leg Extensions
Its purpose is to strengthen the abdominal muscles, low back and stabilize the areas.
Get in crawling position on all fours.
Contract abdominal muscles to keep back flat and straight
Raise one leg upward behind you and straighten outward
Hold for 3 to 5 seconds
Repeat the movement on the opposite side
Once this�exercise/stretch can be performed 10 times with functional pain, add arm movement with each leg extension:
Extend the arm (opposite side of leg) upward and outward in front of body
Hold for 3 to 5 seconds
Repeat on the opposite side
Perform 10 times
How do these exercise/stretches reduce sciatic pain
Abdominal and spinal muscles are essential components of the spine�s system.
These exercises/stretches can help:
Strengthen the spine
Increase flexibility
Increase range of motion
These exercises can help keep the spine�s structural components strong and healthy along with reducing pain and speeding up healing.
Regular exercise causes the body to release endorphins or hormones that interact with the pain receptors in the brain that reduce the perception of pain.
Will exercising with sciatica cause/exacerbate injury
Do not to perform any of these exercises without consulting your doctor,� spine specialist or chiropractor.
Whatever level of fitness, remember even trained professional athletes exercise with a doctor, physical therapist, or other healthcare expert’s approval and clearance.
Obtaining an accurate diagnosis for the exact cause of the sciatic pain
Is essential before considering any exercise program
Be gentle with your spine, don�t push too hard while doing exercises. This is to avoid exacerbating sciatic pain or creating a new injury.
If exercise increases pain or causes nerve-related symptoms like:
Weakness
Tingling sensation
Numbness
Stop and contact your doctor or chiropractor immediately!
El Paso, TX Best Sciatica Chiropractor Treatment
Sandra Rubio discusses Dr. Alex Jimenez and his team will help relieve your sciatica symptoms. Chiropractic care can improve pain and discomfort as well as reduce irritation and inflammation brought on by sciatica. Additionally, a chiropractor such as Dr. Jimenez can also offer nutritional and fitness tips for sciatic nerve pain. Other treatment procedures, such as deep-tissue massage, can help alleviate sciatica symptoms. Dr. Alex Jimenez is the homeopathic, noninvasive option for sciatic nerve disease and its related symptoms.
Sciatica is generally caused by the compression of lumbar or thoracic nerves or by compression of the sciatic nerve. When sciatica is caused by compression of a lower back nerve root, it’s called lumbar radiculopathy. This can happen due to a spinal disc bulge or spinal disk herniation (a herniated intervertebral disc), or by roughening, extending, or misalignment (spondylolisthesis) of the fascia, or as a result of degenerated discs that could reduce the diameter of the lateral foramen by which nerve roots exit the spine.
NCBI Resources
Sciatica is characterized by a shooting pain that originates in the lower back and travels down through the hip, buttock, and back of the leg. The pain can be so severe that it inhibits mobility and can prevent people from working, taking care of their home, or just enjoying their life. Doctors have treated the condition with medications and some invasive therapies, but chiropractic treatments have been found to be extremely effective in alleviating the pain and curing the condition.
Low-level laser therapy (LLLT), also known as photobiomodulation, is the use of low-power lasers or light-emitting diodes (LEDs) for treatment purposes. When LLLT is used on the brain, it is known as transcranial LLLT or transcranial photobiomodulation. Many research studies have shown that LLLT can help treat a variety of brain health issues. �
Different from high-intensity surgical lasers, low-powered lasers do not cut or burn tissue. Instead, these lasers stimulate a biological reaction and promote cells to function properly. Moreover, it�s also easy to use LLLT utilizing red and near-infrared light on your own home. In the article below, we will discuss the brain health benefits of low-level laser therapy (LLLT). �
How Low-Level Laser Therapy Works
Research studies show that red and near-infrared light between the wavelengths of 632 nanometers (nm) and 1064 nm can have brain health benefits. For brain cells or neurons, the optimal range for the wavelengths seems to be between 800 nm and 1000 nm as these can penetrate the scalp and skull to reach the brain. Most devices ultimately fall within this range. �
The light given off from these devices stimulate a photochemical response within neurons or brain cells, which can increase the natural healing process and can also cause beneficial changes in their behavior by supporting the mitochondria. The mitochondria are the �powerhouses of the cell,� producing most of the energy in the human body in the form of adenosine-5- triphosphate (ATP). ATP is the cell’s main source of energy. The brain constantly needs to use it to function properly. �
Proper mitochondrial function and ATP production are fundamental for neuroprotection and cognitive enhancement as well as for the prevention and treatment of a variety of neurological diseases. Research studies have shown that transcranial LLLT promotes proper mitochondrial function and considerably improves the production of ATP in the human brain. �
The mitochondria have photoreceptors which absorb the photons from light and turn them into ATP or energy which can be utilized to perform cellular tasks and biological processes. This system is similar to that of plant photosynthesis where sunlight is absorbed by plants and turned into energy for the plants to grow. Furthermore, by stimulating the mitochondria and producing more ATP, LLLT gives brain cells or neurons even more ATP energy to better heal and repair themselves. �
On top of this, low-level laser therapy has also been shown to: �
Decrease free radicals and oxidative stress in the brain
Increase blood flow and circulation, including within the frontal cortex
Reduce pain by supporting the human body�s opioids or natural pain relievers
Increase rate of oxygen consumption in the frontal cortex
Increase serotonin
Many traumatic brain injuries and neurological diseases can be treated with LLLT, including anxiety, depression, post-traumatic stress disorder (PTSD), post-concussion syndrome, stroke, Alzheimer’s disease, and dementia. We will discuss how low-level laser therapy (LLLT) has been shown to help each of the brain health issues, among others, demonstrated below. �
LLLT for Traumatic Brain Injury
Traumatic brain injury (TBI) is a growing brain health issue where approximately 1.7 million people experience some type of TBI in the U.S. every year. Mild TBIs or concussions make up about 75 percent of all traumatic brain injuries. Military personnel frequently experience TBI and many of them often struggle with PTSD, anxiety, and depression. �
Several research studies have shown that patients with chronic mild TBI have experienced improved cognition, memory and sleep with LLLT. One research study also evaluated whether LLLT could help treat 11 patients with chronic mild TBI symptoms. Two patients had cognitive dysfunction and four patients had multiple concussions. �
After 18 LLLT sessions, the patient’s cognition, memory and verbal learning improved. Participants also said that they slept better and had fewer PTSD symptoms. Coworkers, friends, and family also reported improved social, interpersonal, and occupational functioning. In another research study, 10 people with chronic TBI were given 10 LLLT sessions and experienced reduced headaches, cognitive dysfunction, sleep problems, anxiety, depression and irritability. �
Several mice research studies also show that LLLT can prevent cell death and increase neurological performance after TBI. Researchers believe that LLLT improves TBI symptoms because the mitochondria in the brain can become dysfunctional after TBI, resulting in an inadequate supply of ATP. LLLT can support the mitochondria and increase ATP production. �
After traumatic brain injury (TBI) there is also poor blood flow and oxygenation, and increased inflammation and oxidative stress in the brain. This can ultimately cause brain damage, however, LLLT can help treat these brain health issues as well as help increase antioxidants, promote neurogenesis, and relieve chronic symptoms, among other brain health benefits. �
LLLT for Depression and Anxiety
Research studies in both rats and humans have shown that LLLT can improve mood and reduce symptoms of depression. In 2009, researchers took 10 patients with a history of major anxiety and depression, including PTSD and substance abuse, and utilized LLLT for four weeks. At the end of the research study, six of the 10 patients experienced remission of their depression and seven of the 10 patients experienced remission of their anxiety. There were no observable side-effects. �
Several research studies have shown that depression is associated with abnormal blood flow in the frontal cortex of the brain. LLLT increases blood flow and circulation. Other research studies have shown that participants report improved positive emotions and reduced depressive symptoms after LLLT treatment. Participants with TBI also experienced a decrease in anxiety, depression, irritability, and insomnia as well as an overall improvement in quality of life after LLLT. �
LLLT for Alzheimer’s Disease and Dementia
Research studies show that LLLT can boost performance and improve cognitive function, including attention and memory, in animals, young healthy people and elderly people. Preliminary research studies also show that LLLT may ultimately help slow down the progression of Alzheimer�s disease by decreasing a protein in the brain which is associated with dementia. �
The downregulation of brain-derived neurotrophic factor (BDNF) occurs early in the progression of Alzheimer’s disease and dementia. Research studies have shown that LLLT can also help prevent brain cell or neuron loss by upregulating BDNF. �
Researchers have also utilized LLLT in middle-aged mice and discovered that the memory and cognitive performance of the middle-aged mice improved so much that it became similar to that of young mice. The researchers concluded that LLLT should be utilized in cases of general cognitive impairment in elderly people or even for Alzheimer’s disease and dementia. �
Several other research studies have shown that LLLT increases alertness, awareness and sustained attention as well as improves short-term memory and reaction time. Research study participants also made fewer errors during tests. Another research study found that LLLT enhanced cognition by promoting neuroprotection and supporting the mitochondria. �
LLLT for Stroke
Numerous studies also show that LLLT reduces neurological problems and improves behavior in rats and rabbits after stroke. It also increases the growth of new brain cells or neurons, improving their overall recovery. Multiple other research studies also show that LLLT can considerably reduce brain damage and improve recovery outcome measures after a stroke. �
In one research study, researchers utilized LLLT on patients approximately 18 hours after they experienced a stroke. Five days after the stroke, they found considerably greater improvements in the LLLT-treated group. The improvements continued 90 days after the stroke. At the end of the research study, 70 percent of the patients treated with LLLT had successful outcome measures in comparison with only 51 percent of the control subjects in the research study. �
Follow up research studies with over 600 stroke patients found similar brain health benefits associated with low-level laser therapy (LLLT). Researchers believe that the increase in the production of ATP is responsible for the improvements. �
Low-level laser therapy, or LLLT, is a non-invasive treatment approach which utilizes low-power lasers or light-emitting diodes for the treatment of brain health issues and neurological diseases. Many research studies with both animal and human trial have demonstrated that LLLT provides many brain health benefits without harmful side-effects. Healthcare professionals can help improve the symptoms of brain health issues and neurological diseases with a variety of treatment methods and techniques. Proper diagnosis is fundamental for proper treatment. – Dr. Alex Jimenez D.C., C.C.S.T. Insight
Low-level laser therapy (LLLT), also known as photobiomodulation, is the use of low-power lasers or light-emitting diodes (LEDs) for treatment purposes. In the article above, we discussed the brain health benefits of low-level laser therapy (LLLT) on a variety of brain health issues and neurological diseases. 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.
Neural Zoomer Plus for Neurological Disease
�
Dr. Alex Jimenez utilizes a series of tests to help evaluate neurological diseases. The Neural ZoomerTM Plus is an array of neurological autoantibodies which offers specific antibody-to-antigen recognition. The Vibrant Neural ZoomerTM Plus is designed to assess an individual�s reactivity to 48 neurological antigens with connections to a variety of neurologically related diseases. The Vibrant Neural ZoomerTM Plus aims to reduce neurological conditions by empowering patients and physicians with a vital resource for early risk detection and an enhanced focus on personalized primary prevention. �
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.
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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.
Pain and discomfort, tingling sensations, burning sensations, numbness, and even balance problems are common symptoms associated with peripheral neuropathy. Dr. Valerie Monteiro, leading expert on peripheral neuropathy and recovery. Peripheral neuropathy is a health issue resulting from damage or injury to the nerves in the arms, hands, legs, and feet.
Dr. Valerie Monteiro discusses the 5 most common myths associated with peripheral neuropathy symptoms. Peripheral neuropathy can be treated utilizing the proper treatment approach. Dr. Alex Jimenez, a chiropractor in El Paso, TX, can also help patients with peripheral neuropathy, among other health issues.
Peripheral Neuropathy Myths & Facts | El Paso, TX (2019)
Neuropathy�affects about 8 percent of individuals over the age of 55. Your nervous system is composed of 2 parts: the central nervous system and the peripheral nervous system. The nerves of your peripheral nervous system transmit messages between your central nervous system, that is your brain and spinal cord, along with the rest of the body.
These nerves regulate a massive range of functions throughout the body, such as voluntary muscle movement, involving the motor nerves, involuntary organ action, through the autonomic nerves, and also the perception of stimuli, involving the sensory nerves.
Peripheral neuropathy, which is often simply referred to as �neuropathy,� is a state that happens when your nerves become damaged or injured, oftentimes simply disrupted. It�s estimated that neuropathy affects roughly 2.4 percent of the general populace and approximately 8 percent of people older than age 55. However, this quote doesn�t include people affected by neuropathy caused by physical trauma to the nerves.
Neuropathy Types
Neuropathy can affect any of the three types of peripheral nerves:
Sensory nerves, which transmit messages from the sensory organs, eyes, nose to your brain
Motor nerves, which track the conscious movement of your muscles
Autonomic nerves, which regulate the involuntary functions of your own body
Sometimes, neuropathy will only impact one nerve. This is medically referred to as mononeuropathy and instances of it include:
Ulnar neuropathy, which affects the elbow
Radial neuropathy, which affects the arms
Peroneal neuropathy, which affects the knees
Femoral neuropathy, which affects the thighs
Cervical neuropathy, which affects the neck
Sometimes, two or more isolated nerves in separate regions of the body can become damaged, injured or disrupted, resulting in mono neuritis multiplex neuropathy. Most often, however, multiple peripheral nerves malfunction at the same time, a condition called polyneuropathy. According to the National Institute for Neurological Disorders and Stroke, or the NINDS, there are over 100 kinds of peripheral neuropathies.
Neuropathy Causes
Neuropathies are often inherited from birth or they develop later in life. The most frequent inherited neuropathy is the neurological disease Charcot-Marie-Tooth disease, which affects 1 in 2,500 people in the USA. Although healthcare professionals are sometimes not able to pinpoint the exact reason for an acquired neuropathy, medically referred to as idiopathic neuropathy, there are many known causes for them, including systemic diseases, physical trauma, infectious diseases, and autoimmune disorders.
A systemic disease is one which affects the whole body. The most frequent systemic cause behind peripheral neuropathy is diabetes, which can lead to chronically high blood glucose levels that harm nerves.
A number of other systemic issues can cause neuropathy, including:
Kidney disorders, which permit high levels of nerve-damaging toxic chemicals to flow in the blood
Toxins from exposure to heavy metals, including arsenic, lead, mercury, and thallium
Certain drugs and/or medications, including anti-cancer medications, anticonvulsants, antivirals, and antibiotics
Chemical imbalances because of liver ailments
Hormonal diseases, including hyperthyroidism, which disturbs metabolic processes, potentially inducing cells and body parts to exert pressure on the nerves
Deficiencies in vitamins, such as E, B1 (thiamine), B6 (pyridoxine), B12, and niacin, that can be vital for healthy nerves
Alcohol abuse, which induces vitamin deficiencies and might also directly harm nerves
Cancers and tumors that exert damaging pressure on nerve fibers and pathways
Chronic inflammation, which can damage protective tissues around nerves, which makes them more vulnerable to compression or vulnerable to getting inflamed and swollen
Blood diseases and blood vessel damage, which may damage or injure nerve tissue by decreasing the available oxygen supply
Neuropathy Complications
Peripheral�neuropathy�may result in several complications, as a result of disease or its symptoms. Numbness from the ailment can allow you to be less vulnerable to temperatures and pain, making you more likely to suffer from burns and serious wounds. The lack of sensations in the feet, for instance, can make you more prone to developing infections from minor traumatic accidents, particularly for diabetics, who heal more slowly than other people, including foot ulcers and gangrene.
Furthermore, muscle atrophy may cause you to develop particular physical disfigurements, such as pes cavus, a condition marked by an abnormally high foot arch, and claw-like deformities in the feet and palms.
We are blessed to present to you�El Paso�s Premier Wellness & Injury Care Clinic.
It is essential for people with this condition to not take the simple symptoms like numbness lightly as it can cause some serious problems with time. For example, if you are feeling a sensation of numbness in your feet then you will not realize it if you even step on broken glass. For this reason, you must never ignore even the simplest of the symptoms as it can lead to severe results. You must visit www.neuropathycure.org�for more details.
About 6 million people in the United States have Alzheimer�s disease (AD) and about 50 million people worldwide have dementia. There aren’t many treatments to treat these neurological diseases. Scientists in a 2018 research study on red light therapy and mice described that �treatment for Alzheimer�s disease and dementia has not been effective for more than 100 years.� Another research study described that there is currently “no treatment to prevent brain health issues. �
However, research studies on red light therapy as a treatment for Alzheimer�s disease and dementia have been positive over the last few years in laboratory settings with rodent models. Based on this lab data, researchers recommend red light therapy and near-infrared light therapy in human patients with AD and dementia. In this article, we will look at what the initial human research studies on red light therapy and Alzheimer�s disease/dementia have shown over the last few years. �
Red Light Therapy for Alzheimer�s and Dementia
The first few double-blinded, placebo-controlled human trials on red light therapy for AD, dementia, and other neurological diseases published in 2017 had very positive results. The data showed that red light therapy caused changes in executive function, clock drawing, immediate recall, memory, visual attention, and task switching, among other positive results. One research study showed that patients treated with transcranial light therapy experienced improvements, such as: �
Increased cognitive function
Better sleep
Fewer angry outbursts
Less anxiety
Less wandering
The research study noted that there were �no negative side-effects� on transcranial light therapy for neurological diseases. The research study concluded that transcranial light therapy shows potential for the treatment of brain health issues. �
More Human Trials with Red Light Therapy in Progress
The results of these initial human trials are encouraging for Alzheimer’s disease and dementia patients and families looking for better treatment options, especially natural and non-invasive treatments with no drugs/medications or side effects. �
In early 2019, three more human trials on red light therapy and AD/dementia have been in progress at the University of California and a hospital system in France. With the previous positive results, more and larger research studies and human trials are being organized. Scientists hope that in the following years, the base of positive evidence will be large enough to recommend red light therapy as a treatment for Alzheimer�s disease and dementia, among other neurological diseases. �
The results from human trials over the last few years have established a much bigger base of similarly positive results from research studies of rodent brains in Alzheimer�s disease and dementia models, both of which are outlined below. �
Red Light Therapy Reduces Oxidative Stress and Improves Memory
A 2018 research study of mice in an age-related AD/dementia model showed that red light therapy considerably reduced oxidative stress levels and restored memory function. The researchers also praised red light therapy for being a non-invasive treatment option as well as having a high rate of tissue penetration and low phototoxicity. The researchers additionally found that red light therapy not only prevented early-stage memory decline but also recovered late-stage memory deficits. �
Researchers in a similar 2015 research study with a mouse AD/dementia model utilized near-infrared (NIR) light instead of red light therapy. The NIR treatments also reduced oxidative stress in the cerebellar cortex. The researchers concluded that NIR treatments had the ability to prevent brain degeneration in every region of the mouse brain. The research studies concluded that light therapy opens a promising opportunity to translate LED-therapy into treatments for patients. �
Red Light Therapy Prevents Brain Degeneration
Several research studies have shown that red light therapy can suppress the buildup of Beta-amyloid (A?), a protein which causes senile plaques in people with Alzheimer�s disease and dementia. Synaptic dysfunction, due to the disruptive binding of (A?) in the brain, is one of the symptoms of AD and dementia responsible for causing initial cognitive decline. Preventing synaptic dysfunction can be an effective treatment for AD and dementia, helping to regulate and manage symptoms. �
Red Light Therapy Improves Memory, Motor Skills, and Recognition
Research studies in 2017 evaluated the hippocampus of rat brains in an Alzheimer�s model with light therapy. Both research studies considerably reduced A? plaques in the rats treated with light therapy. Both research studies also tested the subjects and found that treatments reduced hippocampal neurodegeneration and improved spatial memory, recognition, and basic motor skills in the light therapy groups. Another research study also showed considerable A? reduction and noted that NIR light can reduce synaptic dysfunction from A?, showing that NIR light therapy is a viable treatment for AD and dementia. �
Red Light Therapy Shows Promise for Neurological Diseases
The initial research studies on red light therapy for Alzheimer�s disease and dementia have ultimately been encouraging for researchers. Red light therapy is not FDA-approved for the treatment of Alzheimer�s Disease or dementia, however, there is hope that more positive results in human trials will show that light therapy is fundamental for AD and dementia treatment. �
Based on the available base of positive evidence, however, red light therapy shows promise as a natural, non-invasive, drug/medication-free treatment for brain degeneration where pharmacological solutions have long failed. �
By reducing oxidative stress and preventing the accumulation of the Beta-amyloid which causes brain plaques and synapse dysfunction, red light therapy offers hope towards delaying the onset of Alzheimer�s disease and dementia symptoms as well as hopefully even reversing or preventing brain degeneration and cognitive function decline. Researchers, patients, and families affected by AD and dementia will be watching closely in the following years as more positive results emerge. �
Research studies have demonstrated positive results on red light therapy for Alzheimer’s disease and dementia. Initial research studies on mice and rat models have shown the effects of light therapy on neurological diseases. Although, more human trials are still necessary to establish the effectiveness of red light therapy for AD and dementia, the base positive results are promising. Many healthcare professionals can help treat the symptoms associated with a variety of neurological diseases, among other health issues. – Dr. Alex Jimenez D.C., C.C.S.T. Insight
Research studies on red light therapy for AD and dementia have been positive over the last years. The initial human research studies on red light therapy and Alzheimer�s disease/dementia have been promising. 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.
Neural Zoomer Plus for Neurological Disease
Dr. Alex Jimenez utilizes a series of tests to help evaluate neurological diseases. The Neural ZoomerTM Plus is an array of neurological autoantibodies which offers specific antibody-to-antigen recognition. The Vibrant Neural ZoomerTM Plus is designed to assess an individual�s reactivity to 48 neurological antigens with connections to a variety of neurologically related diseases. The Vibrant Neural ZoomerTM Plus aims to reduce neurological conditions by empowering patients and physicians with a vital resource for early risk detection and an enhanced focus on personalized primary prevention. �
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.
Ever wonder what goes through your chiropractors head when treating your moderate back pain? Using a patient as an example, Dr. Jimenez shares his thought process through the treatment of a patient with moderate low back pain. All the way through the first appointment through to the recovery process.
Patient’s Background
Louis is a 47-year-old programmer who plays tennis regularly, especially tournaments.
However, low back pain has put Louis’ game on hold as he�s not able to manage the pain with the regular heating pad, ice, and over-the-counter pain reliever.
His primary physician referred him to Dr. Jimenez.
Louis’ is referred to chiropractic
Dr. Jimenez: Louis’ primary physician referred him to me instead of a spine surgeon because first, the pain is not yet serious enough for surgery. And so there was a window to treat with a non-invasive approach. Secondly, I specialize in sports medicine and so maximize conservative, non-operative techniques/methods.
The United States has 5 times the surgical rate of other countries, so going to a non-operative spine specialist/chiropractor is the best approach at the beginning before the pain becomes severe/acute/chronic.
Louis’ first appointment, medical history, and current back pain
Dr. Jimenez: Once I went through his medical history, I saw it was pretty straightforward. So I dug deeper into other areas of Louis’ lifestyle.
I asked about:
Diet
Physical activity
Emotional well-being
Smoking status
Also, a factor, his occupation was contributing to his pain. He�s a programmer, so spends a lot of time sitting at a desk. Sitting for prolonged periods and usually improperly/poor posture are two of the worst things you can do to your spine.
Sitting for a long time without moving around causes the hip muscles to get tight, and glutes and spine muscles to weaken.
Louis sits most of the day working and spends the weekend if not doing house chores, then playing tennis. Just imagine using weakened muscles during the week and then jumping into a sports activity on the weekend will definitely cause pain.
Louis said that his pain would worsen when serving, hitting a forehand and bending over to pick up a ball. The pain would ease down once he was resting and sleeping.
Louis’ physical exam
Dr. Jimenez: With the physical examination, I looked at
Alignment
Motion
Inflexibilities (not just the spine but the hips and lower extremities)
Muscular imbalances
Weaknesses
I saw that Louis had a flattened lumbar lordosis, meaning the gentle curve in his low back was now flat. Restricted motion in one direction� or a flexion. And weakness in the buttock muscles and hips, and tightness in the lower extremity muscles.
Pushing on certain areas along his spine, presented tenderness in the mid to lower lumbar spine and joint areas.
Initial treatment for Louis’ moderate low back pain
Chiropractic
Physical therapy
Exercises
Stretching
Re-education – proper sitting/standing
Diet
Foot orthotics if necessary
The best initial treatment is to work chiropractically on the muscular imbalances of the spine and lower extremities that are affecting the body’s biomechanics.
Other exams?
Dr. Jimenez: If necessary, a functional movement screening examination.
This test is used in sports medicine to check for imbalances from the feet all the way up to the neck.
After this, Louis would be tested to see if foot orthotics could help and receive specially designed exercises from a physical therapist to address the muscular imbalances.
Radiographic, CT, or MRI imaging
Dr. Jimenez: Many believe that imaging tests are essential to the diagnostic process.
My goal for Louis and all my patients is to get them pain-free, functional and back to health.
Are imaging tests important?
Dr. Jimenez: Imaging tests are important when there are neurologic discoveries/complaints, like muscle weakness, sensory loss, and immobility, as this can indicate the need for surgery.
Imaging tests are helpful for guiding targeted treatment like an epidural injection.
And if your doctor believes there is something serious, e.g., a spinal tumor, infection, then get an imaging test right away.
Louis’ diagnosis
Dr. Jimenez: Because Louis’ pain worsened while playing tennis and then ease during sleep, I diagnosed him with mechanical low back pain.
This type of back pain comes on through mechanical activities or applying a load to the spine.
Non-mechanical low back pain is pain that exists all the time.
Thought process while developing Louis’ treatment plan
Dr. Jimenez: The treatment plan is focused on controlling pain and inflammation.
I first recommended chiropractic treatment, physical therapy/massage, and heat/ice compress.
After completing the course of treatment I suggested Louis take naturally derived supplements:
Turmeric
Bromelain
High-dose omega 3’s
This would help reduce inflammation.
They have been proven to be effective without the serious side effects of both over-the-counter and prescription medications.
Louis and I also discussed his diet
I recommended cutting back on carbohydrate and processed sugar intake thus curbing inflammation and upped healthy fat consumption of and natural sugars that are found in nuts and berries.
I taught Louis proper basic movement techniques, including positioning himself at work and stretches to do throughout the day.
I suggested that Louis work with a fitness physical therapist to build strength and flexibility, that would take shape in 4 to 6 weeks.
After a few sessions, the goal is to be able to do the exercises without help.
Return to tennis
Dr. Jimenez: Very soon, as long as, he uses his natural anti-inflammatory supplements and follows through with regular chiropractic/physical therapy.
Slow and steady is the key to pain relief. Jumping into a tennis set before finishing treatment would set him back and possibly cause new injuries.
I recommended he start by playing non-competitive tennis and just rally after completing the treatment and then take a day or 2 to see how it feels.
Taking it slow should bring back full strength within 2 months after the initial visit.
Preventive tips:
A proper tennis swing should put minimal force on the spine.
Tennis professionals start and stop, jump, slide, dive and run, run, run. That is where a significant overload of the lower back occurs and all the energy goes right into the spine.
The key to a proper swing is to rotate the hips, take the proper arm swing, and hit through the ball.
If you don�t have proper hip rotation, your body will pay for it through the spine.
Bending at the hips and knees when picking up balls will greatly reduce stress on your low back.
Work with a tennis pro that can teach you proper swing and specific tennis training especially movement.
This will help you play well, alleviate/avoid back pain and enjoy the game.
Low Back Pain Treatment | El Paso, Tx
Low back pain which gradually influenced his quality of life was developed. David Garcia was unable to walk as his symptoms worsened and his back pain became excruciating. He first visited Dr. Alex Jimenez, a chiropractor in El Paso, TX, following a recommendation from his sister. Dr. Jimenez managed to supply David Garcia with all the aid he deserved for his low back pain, restoring his well-being. David Garcia clarifies the wonderful service Dr. Alex Jimenez and his team have given him to offer him relief from his painful symptoms and he highly recommends chiropractic care as the non-surgical pick for low back pain, among other health problems.
NCBI Resources
A chiropractor is the ideal medical professional to consult with for any unexplained pain in the musculoskeletal system. They are highly qualified professionals that their specialty is treating conditions like moderate lower back pain and they are very affordable. 31 million Americans experience moderate low back pain at any given time. This condition affects many, but finding the exact cause can be a challenge. Chiropractors are spinal specialists that are trained to not only alleviate pain but also find and help correct the cause of the problem.
IFM's Find A Practitioner tool is the largest referral network in Functional Medicine, created to help patients locate Functional Medicine practitioners anywhere in the world. IFM Certified Practitioners are listed first in the search results, given their extensive education in Functional Medicine
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