- Published in Ophthalmology Rehabilitation Center, Services
Multiple Sclerosis
MULTIPLE SCLEROSIS (MS)
What is MS?
MS is an unpredictable autoimmune condition affecting the brain and spinal cord. The body attacks the protective sheath (myelin) that covers the nerve fibers. When the myelin sheath is damaged or destroyed, this can severely slow the process of transmitting information from the brain to the body. It can range from being benign
What are the signs and symptoms?
- Numbness or weakness in one or more limbs that typically occurs on one side of your body at a time, or the legs and trunk
- Electric-shock sensations that occur with certain neck movements
- Tremor, lack of coordination or unsteady gait
- Vision – partial or complete loss of vision (usually in one eye at a time), prolonged double vision, blurry vision
- Slurred speech
- Fatigue
- Dizziness
- Problems with sexual, bowel and bladder function
How is MS diagnosed?
There are no specific tests to diagnose MS but the doctor may rule out other conditions that have similar signs and symptoms. A series of tests and screening exams, medical history and thorough assessment helps in the diagnosis.
Role of Functional Medicine in MS
Functional Medicine is directed towards the underlying causes of the patient’s symptoms by addressing inflammation issues. The main goal is to enhance the body’s ability to care for itself and to support the immune system as a whole, reduce symptoms or delay the development of the disease.
The treatment plans vary per patient and their specific symptoms. Common approach would include nutritional assessment and revision of the patient’s diet, detect digestive problems and treat with FMT, eliminating possible toxins in the blood through antioxidants treatment, identifying infections, and appropriate physiotherapy activities.
- Published in Neurological Rehabilitation Center, Services
IN VITRO FERTILIZATION (IVF)
What is IVF?
IVF is considered an effective Assisted Reproductive Technology. It is a procedure used to help with fertility problems by conceiving a child through fertilization in the laboratory. Fertilization is done by extracting mature eggs from ovaries and a sperm sample and manually uniting both in a laboratory dish. Once eggs are fertilized fully, it is transferred to the uterus.
Functional Medicine’s Role in IVF
At Better Being Hospital, our Functional Medicine practice aims to support the extensive and expensive efforts of IVF. Nutritional, environmental, lifestyle, physiologic factors and many others are taken into consideration and evaluated to determine if there are any aspects that would have an impact on the chances of IVF’s success. In cases where patients experience implantation failure, Functional Medicine determines the contributing issues such as autoimmunity, inflammation or deficiencies and formulates a supportive treatment plan to improve the patient’s overall health.
- Published in Infertile Rehabilitation Center, Services
Hormone Imbalance
HORMONAL IMBALANCE
What is Hormonal Imbalance?
Hormonal is the excess or lack of certain hormones. Hormones are the body’s chemical
messenger. These are produced in endocrine glands and travel around through the blood to
regulate activities of cells and organs. It controls major body processes like metabolism and
reproduction. Small changes in the hormones can have serious effects on the bodily functions.
What are the types of Hormones?
The most common hormones and their functions are the following:
- Thyroid— regulates physical growth and development, weight, energy levels, internal temperature, and many more.
- Estrogen— development of female secondary sexual characteristics including breasts, endometrium, and regulation of the menstrual cycle. In males estrogen helps in maturation of the sperm and maintenance of a healthy libido.
- Progesterone— responsible for the regulation of uterine function during menstruation and plays a role in reproduction and maintaining the early stages of pregnancy.
- Testosterone— responsible for the development of male sexual characteristics, sperm production, sex drive, bone mass, fat distribution, muscle size and strength and many others.
What causes Hormonal Imbalances?
There are many known causes and conditions that impact the endocrine glands. Some are lifestyle habits and environmental factors.
- chronic or extreme stress
- Type 1 and Type 2 diabetes, hyperglycemia or hypoglycemia
- hypothyroidism or hyperthyroidism
- poor diet and nutrition
- obesity or anorexia
- hormonal replacement or birth control medications
- abuse of anabolic steroid medications
- pituitary tumors
- Diseases such as Cushing’s syndrome, Addison’s disease
- benign or malignant tumors and cysts affecting the endocrine glands
- injury to endocrine glands
- severe allergic reactions or infections
- chemotherapy and radiation therapy
- iodine deficiency (goiters)
- exposure to toxins, pollutants, and endocrine disrupting chemicals, including pesticides and herbicides
Common signs and symptoms
The symptoms depend on the glands and hormones affected, however there are a few
common symptoms that are indicative of a hormonal imbalance in general.
- unexplained weight gain or weight loss
- unexplained or excessive sweating
- difficulty sleeping
- changes in sensitivity to cold and heat
- very dry skin or skin rashes
- changes in blood pressure and heart rate
- brittle or weak bones
- changes in blood sugar concentration
- irritability and anxiety
- unexplained and long-term fatigue
- depression
- frequent headaches
- changes in appetite
- reduced sex drive
- thinning, brittle hair
- infertility
Role of Functional Medicine
Functional Medicine seeks to identify and treat the underlying cause, create and support
the balance of hormones to improve one’s health and reduce symptoms. It involves a careful
investigation and interpretation of various tests to detect markers for inflammation, oxidative
stress, metabolism, nutrient levels, genetic testing and chronic infections. Certain modifications in
diet and lifestyle may be advised as well as nutritional supplements and other beneficial therapies
such as Fecal Microbiota Transplantation, Antioxidants and stem cell therapy depending on the
cause of imbalance.
- Published in Functional Medicine Clinic, Services
FMT, Fecal microbiota transplant
FECAL MICROBIOTA TRANSPLANT (FMT)
What is FMT?
FMT is the process of transplanting intestinal microbiota (intestinal flora) of a healthy individual to a recipient (patient). The preparation is done from a meticulously screened and healthy stool donor. FMT promotes the restoration of the patient’s intestinal microbiota by introducing healthy bacteria. The goal of FMT is to remove the pathogenic infection and rebalance the gut flora in order to alleviate or stop the symptoms.
How is FMT done?
FMT can be administered orally by capsules or through enema – inserting a tube into the patient’s rectum and infusing the liquid solution into the colon.
Who are candidates for FMT?
People with certain chronic illnesses usually take antibiotics for long periods. Taking antibiotics repetitively causes a disruption in the normal ecosystem of protective bacterial species (intestinal flora) in the intestines. These bacteria are actually needed by the body, especially for the gut to function properly. Once the normal intestinal flora is damaged and not enough to compete with harmful pathogens in the gut, these pathogens reside in the gut and produce toxins that cause the patient’s symptoms.
Conditions that can benefit from FMT:
- Autoimmune diseases
- Neurological conditions
- Metabolic syndromes such as inflammatory bowel diseases (such as ulcerative colitis and Crohn’s disease etc.)
- Clostridium difficile infection
- Amyotrophic lateral sclerosis (ALS)
- Multiple sclerosis
- Autism
- Alzheimer’s syndrome
- Parkinson’s disease
- Type 2 diabetes
- Obesity
- Numerous gastrointestinal conditions
- Published in Gastrointestinal Rehabilitation Center, Services
CEREBRAL PALSY (CP)
CEREBRAL PALSY (CP)
What is CP?
Cerebral Palsy is a combination of problems that affects ones muscle tone, movement and motor skills. A person with CP does not have coordination of movement. It can affect other basic but essential body functions such as breathing, bladder and bowel control, eating and talking. It often stems from brain damage that occurs before or during birth or from 3-5 years of a child’s life. Conditions like vision, hearing and learning problems may arise from CP. However, it does not progress or get worse over time.
What causes CP?
There is no definite cause. It happens during the brain’s development. It may be due to one factor or a combination of many issues. Some known factors that contribute to CP are:
- infections during pregnancy
- brain damage due to several causes such as injuries or meningitis
- complications in premature birth (poor blood flow to the brain)
- untreated jaundice
- mother’s medical problems during pregnancy
What are the types of CP?
- Spastic Cerebral Palsy — most common. Decreased muscle tone causes stiffness and jerky movements.
- Dyskinetic – characterized by uncontrolled movements that can be twisting, repetitive, slow, or unpredictable. Can be very severe.
- Ataxic – characterized by shaky movements that affects balance, coordination, posture positioning and even eye movements.
Role of Functional Medicine in CP
The goal in CP patients is to assist in improving brain and neurological function and improve symptoms. Integrative and customized neuro-regenerative programs are designed for each patient depending on their condition. Adjuvant therapies can also be identified and combined with our physiotherapy programs such as Robotics Training, G-Factor and Transcranial Magnetic Stimulation.
- Published in Neurological Rehabilitation Center, Services
CANCER
What is cancer?
Cancer is a collection of diseases which starts when cells start to grow uncontrollably. Normally, human cells grow and divide to form new cells as needed by the body while old or damaged cells die. With cancer cells, there is an abnormal production and elimination of cells. These cells may grow and form into a tumor which if malignant, can spread and grow to other parts of the body.
Signs and symptoms of cancer will depend on the body part that is affected.
One’s predisposition to cancer may or may not be prevented. Depending on the type and period of detection, cancer can be treated.
Types of cancer
There are many types of cancer. Some examples are:
- Carcinomas – most common type of cancer which usually forms solid tumors. Examples are prostate cancer, breast cancer, lung cancer, and colorectal cancer.
- Sarcomas – usually developes in the tissues that support and connect the body such as fat, muscles, nerves, tendons, joints, blood vessels, lymph vessels, cartilage, or bone.
- Leukemias – more popular as cancer of the blood.
- Lymphomas – cancer that begins in the lymphatic system.
Role of Functional Medicine in Cancer
Functional Medicine focuses on the preventive and post-therapeutic condition of patients who are treated conventionally. Conventional approach to cancer would target the tumor or the affected area by popular means such as surgery, chemotherapy, radiation, and others. While Functional Medicine respects the therapeutic means of conventional medicine, it digs deeper and investigates how the body became susceptible to this illness, such as determining the patient’s risk factors, their stress levels, dietary habits, other health conditions that compromised their immune system. To get a better understanding of the tumor environment, objective testing is done with examination of lab values to help identify biomarkers of chronic inflammation, oxidative stress, glucose metabolism, insulin resistance and hormonal issues.
Once the doctor has taken all these in consideration, diet and lifestyle modification, nutrition supplementation, improving and strengthening immunity. Antioxidant therapy, acupuncture and hyperbaric oxygen therapy may be incorporated as well.
- Published in Cancer Rehabilitation Center, Services
SCI
Introduction: According to the National Spinal Cord Injury Association, as many as 430,It was estimated that 17,000 new SCIs occur in the U.S. Spinal cord injuries can be caused by many factors, such as road accidents (45%), falls from high places (20%), sports injuries (15%), violence (15%), and other activities (5%) BUT most of these are caused by trauma to the vertebral column, thereby affecting the spinal cord’s ability to send and receive messages from the brain to the body’s systems that control sensory, motor and autonomic function below the level of injury.
According to the Centers for Diseases Control and Prevention (CDC), SCI costs the nation an estimated 10 billion USD each year.
. Osteoporosis and spinal tumors can also cause spinal fractures. These conditions account for 80% of spinal fractures in patients between the ages of 18-25 years. As such, males are approximately four times more likely than females to experience spinal fractures.
Sign and Symptom: Symptoms will depend on the severity and location of the spinal cord injury. Individuals who present with spinal cord injuries may experience neck pain, back pain, or pain in other affected areas, as well as lack of sensation (numbness), muscle tension, fatigue, and incontinence. Some people can also experience paralysis, which indicates an injury to both the nervous system and spinal cord. A complete SCI produces total loss of all motor and sensory function below the level of injury. Nearly 50% of all SCIs are complete. Both sides of the body are equally affected. Even with a complete SCI, the spinal cord is rarely cut or transected. More commonly, loss of function is caused by a contusion or bruise to the spinal cord or by compromise of blood flow to the injured part of the spinal cord.
In an incomplete SCI, some function remains below the primary level of the injury. A person with an incomplete injury may be able to move one arm or leg more than the other or may have more functioning on one side of the body than the other.
SCIs are graded according to the American Spinal Injury Association (ASIA) grading scale, which describes the severity of the injury. The scale is graded with letters:
- ASIA A: injury is complete spinal cord injury with no sensory or motor function preserved.
- ASIA B: a sensory incomplete injury with complete motor function loss.
- ASIA C: a motor incomplete injury, where there is some movement, but less than half the muscle groups are anti-gravity (can lift up against the force of gravity with a full range of motion).
- ASIA D: a motor incomplete injury with more than half of the muscle groups are anti-gravity.
- ASIA E: normal.
The more severe the injury, the less likely a recovery will occur.
Spinal concussions can also occur. These can be complete or incomplete, but spinal cord dysfunction is transient, generally resolving within one or two days. Football players are especially susceptible to spinal concussions and spinal cord contusions. The latter may produce neurological symptoms, including numbness, tingling, electric shock-like sensations and burning in the extremities.
Open or penetrating injuries to the spine and spinal cord, especially those caused by firearms, may present somewhat different challenges. Most gunshot wounds to the spine are stable; i.e., they do not carry as much risk of excessive and potentially dangerous motion of the injured parts of the spine. Depending upon the anatomy of the injury, the patient may need to be immobilized with a collar or brace for several weeks or months so that the parts of the spine fractured by the bullet heals. In most cases, surgery to remove the bullet does not yield much benefit and may create additional risks, including infection, cerebrospinal fluid leak and bleeding. However, occasional cases of gunshot wounds to the spine may require surgical decompression and/or fusion in an attempt to optimize outcome.
Diagnosis
Patients who have been involved in serious accidents, and present with the symptoms listed above, will need to be cautious with their range of movement, and will also require extra physical support such as wearing a back brace. After conducting a comprehensive physical examination of the patient, the doctor will issue a suitable diagnosis and treatment plan, such as a CT or MRI scan. An MRI scan is usually required in cases of suspected nervous system or spinal cord injury.
Treatment: Treatment of SCI begins before the patient is admitted to the hospital. Paramedics or other emergency medical services personnel carefully immobilize the entire spine at the scene of the accident. In the emergency department, this immobilization is continued while more immediate life-threatening problems are identified and addressed. If the patient must undergo emergency surgery because of trauma to the abdomen, chest or another area, immobilization and alignment of the spine are maintained during the operation.
Non-Surgical Treatments
If a patient has a SCI, he or she will usually be admitted to an intensive care unit (ICU). For many injuries of the cervical spine, traction may be indicated to help bring the spine into proper alignment. Standard ICU care, including maintaining a stable blood pressure, monitoring cardiovascular function, ensuring adequate ventilation and lung function and preventing and promptly treating infection and other complications, is essential so that SCI patients can achieve the best possible outcome.
Surgery
Occasionally, a surgeon may wish to take a patient to the operating room immediately if the spinal cord appears to be compressed by a herniated disc, blood clot or other lesion. This is most commonly done for patients with an incomplete SCI or with progressive neurological deterioration. Even if surgery cannot reverse damage to the spinal cord, surgery may be needed to stabilize the spine to prevent future pain or deformity. The surgeon will decide which procedure will provide the greatest benefit to the patient
What Makes Our Stem Cell Treatment for Spinal Cord Injury Effective ?
Since 2005, we have been developing comprehensive stem cell treatment for spinal cord injury protocols to overcome the limitations of conventional therapies. In our protocols, stem cells are combined with specialized therapies for spinal cord injury that not only focus on helping the patient to cope with their symptoms, but also treat the root cause of the condition by promoting the healing of the original injury. We believe that our comprehensive stem cell therapy for spinal cord injury gives the best chances of improvements, allowing for a better quality of life. Read more
Optionally and in addition to our stem cell treatment for spinal cord injury protocol, we are providing a cutting edge epidural stimulation technology* that helps neurological signals to bypass the injury site in the spinal cord, helping to regain function below the injury.
What potential improvements after therapy?
The purpose of stem cell therapy is to promote the healing of the original injury in order to restore neurological function. Thus, various kinds of improvement are possible after our treatment and our past patients have experienced the following*:
- Improved motor function
- Increased sensation
- Decreased spasticity
- Decreased neuropathic pain
- Improve bladder & bowel function
- Increase sweating function
- Pain relief
- Published in Services
Introduction Spinal muscular atrophy (SMA) is a genetic disease affecting the part of the nervous system that controls voluntary muscle movement.
Most of the nerve cells that control muscles are located in the spinal cord, which accounts for the word spinal in the name of the disease. SMA is muscular because its primary effect is on muscles, which don’t receive signals from these nerve cells. Atrophy is the medical term for getting smaller, which is what generally happens to muscles when they’re not active.
SMA involves the loss of nerve cells called motor neurons in the spinal cord and is classified as a motor neuron disease.
In the most common form of SMA (chromosome 5 SMA, or SMN-related SMA), there is wide variability in age of onset, symptoms and rate of progression. In order to account for these differences, the chromosome 5 SMA often is classified into types 1 through 4.
The age at which SMA symptoms begin roughly correlates with the degree to which motor function is affected: The earlier the age of onset, the greater the impact on motor function. Children who display symptoms at birth or in infancy typically have the lowest level of functioning (type 1). SMA onset in children (types 2 and 3), teens or adults (type 4) generally correlates with increasingly higher levels of motor function.
Chromosome 5 SMA is caused by a deficiency of a motor neuron protein called SMN, for “survival of motor neuron.” This protein, as its name implies, seems to be necessary for normal motor neuron function. Its deficiency is caused by genetic flaws (mutations) on chromosome 5 in a gene called SMN1. Neighboring SMN2 genes can in part compensate for nonfunctional SMN1 genes.
The primary symptom of chromosome 5-related (SMN-related) SMA is weakness of the voluntary muscles. The muscles most affected are those closest to the center of the body, such as those of the shoulders, hips, thighs and upper back. Special complications occur if the muscles used for breathing and swallowing are affected, resulting in abnormalities in these functions. If the muscles of the back weaken, spinal curvatures can develop.
There’s a great deal of variation in the age of onset and level of motor function achieved in chromosome 5-related SMA. These are roughly correlated with how much functional SMN protein is present in the motor neurons, which in turn is correlated with how many SMN2 genes a person has.
Sensory, mental and emotional functioning are entirely normal in chromosome-5 SMA.
Some forms of SMA are not linked to chromosome 5 or SMN deficiency. These forms vary greatly in severity and in the muscles most affected. While most forms, like the chromosome 5-related form, affect mostly the proximal muscles, other forms exist that affect mostly the distal muscles (those farther away from the body’s center) — at least in the beginning.
Causes
SMA types 0, 1, 2, 3 and 4 are inherited as autosomal recessive genetic disorders and are associated with abnormalities (mutations) in the SMN1 and SMA2 genes on chromosome 5 at chromosomal locus 5q11-q13. SMA1 is thought to be the primary disease-causing gene. Approximately 95-98% of affected individuals have deletions in the SMA1 gene and 2-5% have specific mutations in the SMA1 gene that result in a decreased production of the SMN protein. When three or more copies of the SMA2 gene are also present, the disease may be milder.
Genetic diseases are determined by the combination of genes for a particular trait that are on the chromosomes received from the father and the mother.
Recessive genetic disorders occur when an individual inherits the same abnormal gene for the same trait from each parent. If an individual receives one normal gene and one gene for the disease, the person will be a carrier for the disease, but usually will not show symptoms. The risk for two carrier parents to both pass the defective gene and, therefore, have an affected child is 25% with each pregnancy. The risk to have a child who is a carrier like the parents is 50% with each pregnancy. The chance for a child to receive normal genes from both parents and be genetically normal for that particular trait is 25%. The risk is the same for males and females.
Biological or surrogate markers for SMA are under development. These potential surrogate markers studied to date include:
1) Measuring the amount and ratio of full-length and truncated SMN2 RNA transcripts as well as the amount of SMN protein from white blood cells or fibroblast culture.
2) Counting motor units (Motor Unit Number Estimation, or MUNE) which have shown correlation with the SMN2 copy number, age, and function.
3) Quantitative ultrasound in assessing muscle changes in patients with SMA.
4) Electrical impedance myography.
5) The compound action potential determined by EMG in children with SMA. The authors point out that MUNE is difficult and not as reliable as initially thought. A longitudinally study of the surrogate markers will be necessary before any particular one can be used in an intervention study.
Subdivisions of Spinal Muscular Atrophy
- SMA type 0
- SMA type 1
- SMA type 2
- SMA type 3
- SMA type 4
Sign and Symptoms
SMA type 0 is the most severe form of the disease and is characterized by decreased fetal movement, joint abnormalities, difficulty swallowing and respiratory failure.
SMA type 1 is the most common type of SMA and is also a severe form of the disease. Infants with SMA type 1 experience severe weakness before 6 months of age and never sit independently. Muscle weakness, lack of motor development and poor muscle tone are the major clinical manifestations of SMA type I. Infants with the gravest prognosis have problems sucking or swallowing. Some show abdominal breathing in the first few months of life. Muscle weakness occurs on both sides of the body and the ocular muscles are not affected. A twitching of the tongue is often seen. Intelligence is normal. Most affected children die before two years of age but survival may be dependent on the degree of respiratory function. For more information about SMA type 1, chose “Werdnig Hoffman” disease as your search term in the Rare Disease Database.
The onset of weakness in SMA type 2 patients is usually between 6 and 12 months. Affected children are able to sit independently early in development but are unable to walk even 10 feet independently. A trembling (tremor) of the fingers is almost always seen in SMA type 2. Approximately 70% of those affected do not have deep tendon reflexes. Those affected with SMA type 2 are usually not able to sit independently by the mid-teens or later.
Patients with SMA type 3 (Kugelberg-Welander syndrome) learn to walk but fall frequently and have trouble walking up and down stairs at 2-3 years of age. The legs are more severely affected than the arms. The long-term prognosis depends on the degree of motor function attained as a child. For more information about SMA3 chose “Kugelberg Welander syndrome” as your search term in the Rare Disease Database.
The onset of muscle weakness for those with SMA type 4 is after age 10 years; these patients usually are ambulatory until age 60 years.
Complications of SMA include scoliosis, joint contractures, pneumonia and metabolic abnormalities such as severe metabolic acidosis and dicarboxylic aciduria.
Diagnosis
The diagnosis of SMA is suspected when symptoms are present and the diagnosis can be confirmed with molecular genetic testing. Molecular genetic testing is used to determine if a mutation is present in the SMN1 gene. SMA types 0, 1, 2, 3 and 4 are caused by a partial or complete loss of the SMN1 gene and about 95% of those affected will show a deletion of both copies of a specific portion (exon 7 or exon 8) of the gene. About 5% of those affected will show a deletion of exon 7 in one copy of the SMN1 gene and a different mutation in the other copy of the SMN1 gene. Molecular genetic testing can also be used to determine the number of copies of the SMN2 gene.
Prior to the availability of molecular testing, neurophysiologic studies and muscle biopsy were used for diagnosis, but these tests are no longer necessary unless SMN gene testing is normal.
Carrier testing for SMA is available using a molecular genetic test in which the number of copies of the SMN1 gene is determined.
Molecular genetic testing for the VAPB gene is available to diagnose Finkel type SMA.
Care for individuals with SMA is symptomatic and includes physical therapy, occupational therapy, monitoring of respiratory function and nutritional status, orthotics and adaptive equipment. Respiratory support for SMA1 using a breathing machine called BiPAP (bi-level positive airway pressure) has been shown to increase comfort and life expectancy in some affected children.
Genetic counseling is recommended for affected individuals and their families
Treatment
The management of children with spinal muscular atrophy starts with the diagnosis and classification into 1 of the 5 categories. Health issues specific to spinal muscular atrophy are as follows:
Pulmonary management: Children with SMA1 can survive beyond 2 years of age when offered tracheostomy or noninvasive respiratory support.
An intermittent positive-pressure breathing device (mechanical in-exsufflator) has proven effective.
Nutrition: Bulbar dysfunction is universal in SMA1 patients. Early gastrostomy should be considered as part of the management of such patients. The bulbar dysfunction eventually becomes a serious problem for spinal muscular atrophy II patients and only very late in the course of disease for spinal muscular atrophy III patients.
Scoliosis: Scoliosis is a major problem in most SMA2 patients and in half of SMA3 patients.
The vertical expandable prosthetic titanium rib (VEPTR) was approved by the FDA in 2004 as a treatment for thoracic insufficiency syndrome (TIS) in pediatric patients. TIS is a congenital condition where severe deformities of the chest, spine, and ribs prevent normal breathing and lung development. The VEPTR is an implanted, expandable device that helps straighten the spine and separate ribs so that the lungs can grow and fill with enough air to breathe. The length of the device can be adjusted as the patient grows. The titanium rib was developed at the University of Texas Health Science Center in San Antonio. It is manufactured by Synthes Spine Co.
Hip dislocation: Hip dislocation is another orthopedic concern in patients with spinal muscular atrophy. If the hip dislocation is asymptomatic, surgery is not indicated.
Behavior issues: Compared to siblings and normal controls, patients with spinal muscular atrophy were quite well adjusted. Concern was, however, raised about unaffected siblings, who had a 2 to 3-fold higher rate behavioral problems than normal children.
Sleep disorders: Sleep-disordered breathing may develop prior to respiratory failure. Night-time use of continuous positive airway pressure with a nasal mask may be helpful.
In 2017, Spinraza (nusinersen) was FDA approved as the first drug to treat children and adults with SMA. Spinraza is manufactured by Biogen.
How Functional medicine can help this condition?
What Makes our Stem Cell Treatment for SMA Effective?
Since 2005, we have been developing comprehensive protocols regarding stem cell treatment for Spinal Muscular Atrophy (SMA) to overcome the limitations of conventional therapies. In our protocols, stem cells are combined with specialized therapies for spinal muscular atrophy that not only focus on helping the patient to cope with their symptoms, but also treat the direct cause of the symptoms by promoting the healing of the injury in the spinal cord. We believe that our comprehensive stem cell treatment for spinal muscular atrophy gives our patients the best chances of improvements, allowing for a better quality of life. Different types of spinal muscular atrophy can be considered for treatment such as SMA type 1, SMA type 2, SMA type 3 (Kugelberg-Welander syndrome) and more.
What potential improvements after the treatment?
The purpose of our treatment for spinal muscular atrophy is to promote the healing of the injury in the spinal cord in order to restore neurological function. Thus, various kinds of improvement are possible after our treatment and our past patients have experienced the following*:
- Improved range of movements
- Increased muscle mass
- Increased muscle strength
- Better coordination
- Improved balance
- Improved development
Decreased muscle rigidity
- Published in Services
Spinal bifida
Introduction: Spina bifida is a condition that affects the spine and is usually apparent at birth. It is a type of neural tube defect (NTD).
Spina bifida can happen anywhere along the spine if the neural tube does not close all the way. When the neural tube doesn’t close all the way, the backbone that protects the spinal cord doesn’t form and close as it should. This often results in damage to the spinal cord and nerves.
Spina bifida might cause physical and intellectual disabilities that range from mild to severe. The severity depends on:
- The size and location of the opening in the spine.
Whether part of the spinal cord and nerves are affected.
Causes of spina bifida
The cause of spina bifida is unknown, but a number of factors can increase the risk of a baby developing the condition.
These include:
- low folic acid intake during pregnancy
- having a family history of spina bifida
- medication – taking certain medications during pregnancy has been linked to an increased risk of having a baby with spina bifida
Sign and Symptom: Types of Spina Bifida
The three most common types of spina bifida are Myelomeningocele (sounds like: my-low-ma-nin-jo-seal; hear how “myelomeningocele” sounds
When people talk about spina bifida, most often they are referring to myelomeningocele. Myelomeningocele is the most serious type of spina bifida. With this condition, a sac of fluid comes through an opening in the baby’s back. Part of the spinal cord and nerves are in this sac and are damaged. This type of spina bifida causes moderate to severe disabilities, such as problems affecting how the person goes to the bathroom, loss of feeling in the person’s legs or feet, and not being able to move the legs.
Meningocele (sounds like: ma-nin-jo-seal; hear how “meningocele” sounds
Another type of spina bifida is meningocele. With meningocele a sac of fluid comes through an opening in the baby’s back. But, the spinal cord is not in this sac. There is usually little or no nerve damage. This type of spina bifida can cause minor disabilities.
Spina Bifida Occulta (sounds like: o-cult-tuh; hear how “occulta” sounds
Spina bifida occulta is the mildest type of spina bifida. It is sometimes called “hidden” spina bifida. With it, there is a small gap in the spine, but no opening or sac on the back. The spinal cord and the nerves usually are normal. Many times, spina bifida occulta is not discovered until late childhood or adulthood. This type of spina bifida usually does not cause any disabilities.
Diagnosis: Diagnosing spina bifida
Most cases of spina bifida are detected during the mid-pregnancy anomaly scan, which is offered to all pregnant women between 18 and 21 weeks of pregnancy.
If tests confirm that your baby has spina bifida, the implications will be discussed with you.
This will include a discussion about the possible problems associated with the condition, the treatment and support your child may need if you decide to continue with the pregnancy, and what your options are regarding ending the pregnancy, if that’s your choice.
Tests after birth
Once the baby is born, a number of tests may be carried out to assess the severity of the condition and help decide which treatments are appropriate.
Tests may include:
- monitoring your child’s head growth and carrying out a brain scan, using an ultrasound scan, CT scan or MRI scan, to check for hydrocephalus (excess fluid on the brain)
- ultrasound scans of the bladder and kidneys to check whether your baby stores urine normally
- an assessment of your baby’s movements to check for paralysis
In most cases, surgery to repair the spine will be recommended soon after your baby is born.
Treating spina bifida
Treatments for the symptoms or conditions associated with spina bifida include:
- surgery soon after birth to close the opening in the spine and treat hydrocephalus
- therapies to help make day-to-day life easier and improve independence, such as physiotherapy and occupational therapy
- assistive devices and mobility equipment, such as a wheelchair, or walking aids
- treatments for bowel and urinary problems
With the right treatment and support, many children with spina bifida survive well into adulthood.
It can be a challenging condition to live with, but many adults with spina bifida are able to lead independent and fulfilling lives.
Read more about treating spina bifida
Treatment: Treatments for the symptoms or conditions associated with spina bifida include:
- surgery soon after birth to close the opening in the spine and treat hydrocephalus
- therapies to help make day-to-day life easier and improve independence, such as physiotherapy and occupational therapy
assistive devices and mobility equipment, such as a wheelchair, or walking aids
- treatments for bowel and urinary problems
With the right treatment and support, many children with spina bifida survive well into adulthood.
It can be a challenging condition to live with, but many adults with spina bifida are able to lead independent and fulfilling lives.
What Makes our Treatment for Spina Bifida Effective?
Since 2005, we have been developing comprehensive stem cell therapy protocols for Spina Bifida to overcome the limitations of conventional therapies. In our protocols, stem cells are combined with specialized therapies for spina bifida that not only focus on helping the patient to cope with their symptoms, but also treat the root cause of the condition by promoting the healing of the original spinal cord/brain injury. We believe that our comprehensive therapy approach for spina bifida gives our patients the best chances of improvements, allowing for a better quality of life.
What potential improvements after the treatment?
The purpose of the treatment is to promote healing of the original spinal cord/brain injury in order to restore neurological function. Thus, various kinds of improvement are possible after our treatment and our past patients have experienced the following*:
- Improved motor function
- Increased sensations
- Improved development
- Improved mental abilities
- Increased muscle strength
- Reduced epilepsy seizures
- Enhanced bladder & bowel function
- Published in Neurological Rehabilitation Center, Services