Page 3«..2345..1020..»

Archive for the ‘Spinal Cord Injury’ Category

Spinal Cord Injury: Signs, Causes & Prevention

What is a Spinal Cord Injury?

A spinal cord injury, or damage to the spinal cord, is an extremely serious type of physical trauma. It will likely have a lasting and significant impact on most aspects of daily life.

According to the National Institutes of Health, the group that is most at risk for spinal cord injuries are males between the ages of 15 and 35. Most people who are injured are both young and in good health at the time the trauma occurs (NIH).

The spinal cord is a bundle of nerves and other tissue contained and protected by the vertebrae of the spine, which are the bones stacked on top of each other that make up the spine. It is composed of many nerves, and extends from the brains base down the back, ending close to the buttocks.

The spinal cord is responsible for transporting impulses (messages) from the brain to all parts of the body, and from the body to the brain. We are able to perceive pain and move our limbs because of messages transmitted through the spinal cord.

If the spinal cord is injured, some or all of these impulses may be prevented from getting through. The result is a complete or total loss of sensation and mobility below the injury. Therefore, a spinal cord injury closer to the neck will typically cause paralysis throughout a larger part of the body than one in the lower back area.

Some signs that a person may have a spinal cord injury include:

Spinal cord injuries are often the result of unpredictable accidents and/or violent events. The following can all result in damage to the spinal cord:

Anyone who believes they or someone else has sustained a spinal cord injury should follow the tips below:

When the person arrives at the hospital, doctors will do a physical exam as well as a complete neurological exam. This will help them determine whether the spinal cord was indeed injured and, if so, where. CT scans, MRIs, X-rays of the spine, and evoked potential testing (which measures how quickly nerve signals reach the brain) are all diagnostic tools that doctors may use.

See the article here:
Spinal Cord Injury: Signs, Causes & Prevention

Spinal Cord Injury Zone

May 23, 2015 - Scientists Meet in Louisville to Share Research That Could Improve Treatments for Spinal Cord, Head Injury

LOUISVILLE, Ky. (5/23/15) More than a dozen leading basic scientists from around the nation and the world studying neurological function made presentations to 160 fellow researchers in Louisville Wednesday and Thursday. The goal? To facilitate collaborations that will advance science leading to improved spinal cord and head injury rehabilitation. Scientists from Sweden, Canada and Continue Reading

A new thought-controlled robotic arm taps into a different part of the brain than most, which its creators say may give its paralyzed users an easier learning curve and allow for more fluid movements. They report on the success of their first patient, Erik G. Sorto, in a paper published Thursday in Science. When Sorto, Continue Reading

Erik Sorto, a 34-year old American, has been unable to move his arms or legs for more than a decade, since a gunshot wound left him paralysed from the neck down. Even now, he misses the little things. I want to be able to drink my own beer to be able to take a Continue Reading

Clinton Township Charlie Parkhill talks with his hands. Its remarkable, given that 17 years ago, an accident left him unable to move his body below his neck. Parkhill was a CPA with his own business when, in 1998, he went on vacation with his wife to Mexico. While he was coming out of the Continue Reading

The first two patients to receive InVivos Neuro-Spinal Scaffold for spinal cord injury are showing improvement three-to-six months after surgery. The first spinal cord injury patient was treated in October 2014 at Barrow Neurological Institute in Phoenix and the second was treated in January 2015 at Carolinas Medical Center in Charlotte.

See the original post here:
Spinal Cord Injury Zone

Spinal cord trauma: MedlinePlus Medical Encyclopedia

The spinal cord contains the nerves that carry messages between your brain and body. The cord passes through your neck and back.

Spinal cord trauma can be caused by injuries to the spine, such as:

A minor injury can damage the spinal cord if the spine is weakened, such as from rheumatoid arthritis or osteoporosis. Injury can also occur if the spinal canal protecting the spinal cord has become too narrow (spinal stenosis) due to the normal aging process.

Direct injury, such as bruises, can occur to the spinal cord if the bones or disks have been weakened. Fragments of bone (such as from broken vertebrae, which are the spine bones) or fragments of metal (such as from a traffic accident or gunshot) can damage the spinal cord.

Direct damage can occur if the spinal cord is pulled, pressed sideways, or compressed. This may occur if the head, neck, or backis twisted abnormally during an accident or intense chiropractic manipulation.

Bleeding, fluid buildup, and swelling can occur inside or outside the spinal cord (but within the spinal canal). Thebuildup of blood or fluid canpress onthe spinal cord and damage it.

Most spinal cord trauma happens to young, healthy individuals. Men ages 15to 35 are mostoften affected. The death rate tends to be higher in young children with spinal injuries.

Risk factors include:

Older people with weakenedbones (from osteoporosis) or persons with other medical problems (such as stroke) that make them more likely to fallmay also have spinal cord injury.

Read the rest here:
Spinal cord trauma: MedlinePlus Medical Encyclopedia

Spinal Cord Injury Information Page: National Institute of …

A spinal cord injury usually begins with a sudden, traumatic blow to the spine that fractures or dislocates vertebrae. The damage begins at the moment of injury when displaced bone fragments, disc material, or ligaments bruise or tear into spinal cord tissue. Most injuries to the spinal cord don't completely sever it. Instead, an injury is more likely to cause fractures and compression of the vertebrae, which then crush and destroy axons -- extensions of nerve cells that carry signals up and down the spinal cord between the brain and the rest of the body. An injury to the spinal cord can damage a few, many, or almost all of these axons. Some injuries will allow almost complete recovery. Others will result in complete paralysis.

Improved emergency care for people with spinal cord injuries and aggressive treatment and rehabilitation can minimize damage to the nervous system and even restore limited abilities. Respiratory complications are often an indication of the severity of spinal cord injury About one-third of those with injury to the neck area will need help with breathing and require respiratory support. The steroid drug methylprednisolone appears to reduce the damage to nerve cells if it is given within the first 8 hours after injury. Rehabilitation programs combine physical therapies with skill-building activities and counseling to provide social and emotional support.Electrical simulation of nerves by neural prosthetic devices may restore specific functions, including bladder, breathing, cough, and arm or leg movements, though eligibility for use of these devices depends on the level and type of the spinal cord injury.

Spinal cord injuries are classified as either complete or incomplete. An incomplete injury means that the ability of the spinal cord to convey messages to or from the brain is not completely lost. People with incomplete injuries retain some motor or sensory function below the injury. A complete injury is indicated by a total lack of sensory and motor function below the level of injury. People who survive a spinal cord injury will most likely have medical complications such as chronic pain and bladder and bowel dysfunction, along with an increased susceptibility to respiratory and heart problems. Successful recovery depends upon how well these chronic conditions are handled day to day.

Surgery to relieve compression of the spinal tissue by surrounding bones broken or dislocated by the injury is often necessary, through timing of such surgery may vary widely. A recent prospective multicenter trial called STASCIS is exploring whether performing decompression surgery early (less than 24 hours following injury) can improve outcomes for patients with bone fragments or other tissues pressing on the spinal cord.

The National Institute of Neurological Disorders and Stroke (NINDS) conducts spinal cord research in its laboratories at the National Institutes of Health (NIH) and also supports additional research through grants to major research institutions across the country. Advances in research are giving doctors and patients hope that repairing injured spinal cords is a reachable goal. Advances in basic research are also being matched by progress in clinical research, especially in understanding the kinds of physical rehabilitation that work best to restore function. Some of the more promising rehabilitation techniques are helping spinal cord injury patients become more mobile.

Follow this link:
Spinal Cord Injury Information Page: National Institute of ...

Spinal cord injury – Wikipedia, the free encyclopedia

A spinal cord injury (SCI) is an injury to the spinal cord resulting in a change, either temporary or permanent, in the cord's normal motor, sensory, or autonomic function.[1] Common causes of damage are trauma (car accident, gunshot, falls, sports injuries, etc.) or disease (transverse myelitis, polio, spina bifida, Friedreich's ataxia, etc.). The spinal cord does not have to be severed in order for a loss of function to occur. Depending on where the spinal cord and nerve roots are damaged, the symptoms can vary widely, from pain to paralysis to incontinence.[2][3] Spinal cord injuries are described at various levels of "incomplete", which can vary from having no effect on the patient to a "complete" injury which means a total loss of function.

Treatment of spinal cord injuries starts with restraining the spine and controlling inflammation to prevent further damage. The actual treatment can vary widely depending on the location and extent of the injury. In many cases, spinal cord injuries require substantial physical therapy and rehabilitation, especially if the patient's injury interferes with activities of daily life.

Research into treatments for spinal cord injuries includes controlled hypothermia and stem cells, though many treatments have not been studied thoroughly and very little new research has been implemented in standard care.

The American Spinal Injury Association (ASIA) first published an international classification of spinal cord injury in 1982, called the International Standards for Neurological and Functional Classification of Spinal Cord Injury. Now in its sixth edition, the International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI) is still widely used to document sensory and motor impairments following SCI.[4] It is based on neurological responses, touch and pinprick sensations tested in each dermatome, and strength of the muscles that control ten key motions on both sides of the body, including hip flexion (L2), shoulder shrug (C4), elbow flexion (C5), wrist extension (C6), and elbow extension (C7).[5] Traumatic spinal cord injury is classified into five categories on the ASIA Impairment Scale:

Dimitrijevic[6] proposed a further class, the so-called discomplete lesion, which is clinically complete but is accompanied by neurophysiological evidence of residual brain influence on spinal cord function below the lesion.[7]

Signs recorded by a clinician and symptoms experienced by a patient will vary depending on where the spine is injured and the extent of the injury. These are all determined by the area of the body that the injured area of the spine innervates. A section of skin innervated through a specific part of the spine is called a dermatome, and spinal injury can cause pain, numbness, or a loss of sensation in the relevant areas. A group of muscles innervated through a specific part of the spine is called a myotome, and injury to the spine can cause problems with voluntary motor control. The muscles may contract uncontrollably, become weak, or be completely paralysed. The loss of muscle function can have additional effects if the muscle is not used, including atrophy of the muscle and bone degeneration.

A severe injury may also cause problems in parts of the spine below the injured area. In a "complete" spinal injury, all functions below the injured area are lost. An "incomplete" spinal cord injury involves preservation of motor or sensory function below the level of injury in the spinal cord.[8] If the patient has the ability to contract the anal sphincter voluntarily or to feel a pinprick or touch around the anus, the injury is considered to be incomplete. The nerves in this area are connected to the very lowest region of the spine, the sacral region, and retaining sensation and function in these parts of the body indicates that the spinal cord is only partially damaged. This includes a phenomenon known as sacral sparing which involves the preservation of cutaneous sensation in the sacral dermatomes, even though sensation is impaired in the thoracic and lumbar dermatomes below the level of the lesion.[9] Sacral sparing may also include the preservation of motor function (voluntary external anal sphincter contraction) in the lowest sacral segments.[8] Sacral sparing has been attributed to the fact that the sacral spinal pathways are not as likely as the other spinal pathways to become compressed after injury.[9] The sparing of the sacral spinal pathways can be attributed to the lamination of fibers within the spinal cord.[9]

A complete injury frequently means that the patient has little hope of functional recovery.[10] The relative incidence of incomplete injuries compared to complete spinal cord injury has improved over the past half century, due mainly to the emphasis on faster and better initial care and stabilization of spinal cord injury patients.[11] Most patients with incomplete injuries recover at least some function.[10]

Determining the exact "level" of injury is critical in making accurate predictions about the specific parts of the body that may be affected by paralysis and loss of function. The level is assigned according to the location of the injury by the vertebra of the spinal column closest to the injury on the spinal cord.

Cervical (neck) injuries usually result in full or partial tetraplegia (Quadriplegia). However, depending on the specific location and severity of trauma, limited function may be retained.

View original post here:
Spinal cord injury - Wikipedia, the free encyclopedia

Spinal cord – Wikipedia, the free encyclopedia

The spinal cord is a long, thin, tubular bundle of nervous tissue and support cells that extends from the medulla oblongata in the brainstem to the lumbar region of the vertebral column. The brain and spinal cord together make up the central nervous system (CNS). The spinal cord begins at the occipital bone and extends down to the space between the first and second lumbar vertebrae; it does not extend the entire length of the vertebral column. It is around 45cm (18in) in men and around 43cm (17in) long in women. Also, the spinal cord has a varying width, ranging from 13mm (12in) thick in the cervical and lumbar regions to 6.4mm (14in) thick in the thoracic area. The enclosing bony vertebral column protects the relatively shorter spinal cord. The spinal cord functions primarily in the transmission of neural signals between the brain and the rest of the body but also contains neural circuits that can independently control numerous reflexes and central pattern generators. The spinal cord has three major functions: as a conduit for motor information, which travels down the spinal cord, as a conduit for sensory information in the reverse direction, and finally as a center for coordinating certain reflexes. [1]

The spinal cord is the main pathway for information connecting the brain and peripheral nervous system. The length of the spinal cord is much shorter as compared to the length of the vertebral column. The human spinal cord extends from the foramen magnum and continues through to the conus medullaris near the second lumbar vertebra, terminating in a fibrous extension known as the filum terminale.

It is about 45cm (18in) long in men and around 43cm (17in) in women, ovoid-shaped, and is enlarged in the cervical and lumbar regions. The cervical enlargement, located from C3 to T2 spinal segments, is where sensory input comes from and motor output goes to the arms. The lumbar enlargement, located between L1 and S3 spinal segments, handles sensory input and motor output coming from and going to the legs.

The spinal cord (and brain) are protected by three layers of tissue, called spinal meninges, that surround the canal. The dura mater is the outermost layer, and it forms a tough protective coating. Between the dura mater and the surrounding bone of the vertebrae is a space called the epidural space. The epidural space is filled with adipose tissue, and it contains a network of blood vessels. The arachnoid mater is the middle protective layer. Its name comes from the fact that the tissue has a spiderweb-like appearance. The space between the arachnoid and the underlying pia mater is called the subarachnoid space. The subarachnoid space contains cerebrospinal fluid (CSF). The medical procedure known as a lumbar puncture (or "spinal tap") involves use of a needle to withdraw cerebrospinal fluid from the subarachnoid space, usually from the lumbar region of the spine. The pia mater is the innermost protective layer. It is very delicate and it is tightly associated with the surface of the spinal cord. The cord is stabilized within the dura mater by the connecting denticulate ligaments, which extend from the enveloping pia mater laterally between the dorsal and ventral roots. The dural sac ends at the vertebral level of the second sacral vertebra.

In cross-section, the peripheral region of the cord contains neuronal white matter tracts containing sensory and motor neurons. Internal to this peripheral region is the grey matter. The nerve cell bodies of the grey matter is contained in the three grey columns of the spinal cord that give the butterfly-shaped central region its shape. This central region surrounds the central canal, which is an extension of the fourth ventricle and contains cerebrospinal fluid.

The spinal cord has a shape that is compressed dorso-ventrally, giving it an elliptical shape. The cord has grooves in the dorsal and ventral sides. The posterior median sulcus is the groove in the dorsal side, and the anterior median fissure is the groove in the ventral side. In the spinal cord there are some tracts that brings information from the brain.

The human spinal cord is divided into 31 different segments. At every segment, right and left pairs of spinal nerves (mixed; sensory and motor) form. Six to eight motor nerve rootlets branch out of right and left ventro lateral sulci in a very orderly manner. Nerve rootlets combine to form nerve roots. Likewise, sensory nerve rootlets form off right and left dorsal lateral sulci and form sensory nerve roots. The ventral (motor) and dorsal (sensory) roots combine to form spinal nerves (mixed; motor and sensory), one on each side of the spinal cord. Spinal nerves, with the exception of C1 and C2, form inside intervertebral foramen (IVF). Note that at each spinal segment, the border between the central and peripheral nervous system can be observed. Rootlets are a part of the peripheral nervous system.

In the upper part of the vertebral column, spinal nerves exit directly from the spinal cord, whereas in the lower part of the vertebral column nerves pass further down the column before exiting. The terminal portion of the spinal cord is called the conus medullaris. The pia mater continues as an extension called the filum terminale, which anchors the spinal cord to the coccyx. The cauda equina ("horse's tail") is the name for the collection of nerves in the vertebral column that continue to travel through the vertebral column below the conus medullaris. The cauda equina forms as a result of the fact that the spinal cord stops growing in length at about age four, even though the vertebral column continues to lengthen until adulthood. This results in the fact that sacral spinal nerves actually originate in the upper lumbar region.

The spinal cord can be anatomically divided into 31 spinal segments based on the origins of the spinal nerves. Each segment of the spinal cord is associated with a pair of ganglia, called dorsal root ganglia, which are situated just outside of the spinal cord. These ganglia contain cell bodies of sensory neurons. Axons of these sensory neurons travel into the spinal cord via the dorsal roots.

Ventral roots consist of axons from motor neurons, which bring information to the periphery from cell bodies within the CNS. Dorsal roots and ventral roots come together and exit the intervertebral foramina as they become spinal nerves.

See the article here:
Spinal cord - Wikipedia, the free encyclopedia

Spinal Cord Injury Support – Paraplegic and Quadriplegic

Welcome to Apparelyzed, a free spinal cord injury peer support website run by individuals with spinal cord injuries. Here you will find health information which has been submitted, and is discussed between the spinal injury community. Please use the links on the left of this page to navigate the website, and the section index below to navigate this page. We hope you find the website useful, and consider joining in on some of the discussions in the spinal cord injury forum. Spinal Cord Injury Homepage Quick Links What is a Spinal Cord Injury ? A spinal cord injury (SCI) is generally defined as damage or trauma to the spinal cord that results in a loss or impaired function. The paralysis from the damaged spinal cord may affect mobility, sensation, bladder function, bowel function or sexual function. When a person has been paralysed due to a spinal cord injury, paraplegic and quadriplegic (tetraplegic) are terms used to describe the resultant medical condition. The classification of spinal cord injury depends on the spinal cord injury level and severity of a persons paralysis, and how it affects their limbs. The spinal cord injury level is usually referred to alpha numerically, relating to the affected segment in the spinal cord, ie, C4, T5, L5 etc. Common causes of damage to the spinal cord are trauma (car/motorcycle accident, gunshot, falls, sports injuries, physical attacks), or disease (Transverse Myelitis, Polio, Spina Bifida, Friedreich's Ataxia, spinal cord tumour, spinal stenosis, etc.). The resulting damage to the spinal cord is known as a lesion, and the paralysis is known as quadriplegia or quadraplegia / tetraplegia if the injury is in the cervical (neck) region, or as paraplegia if the injury is in the thoracic, lumbar or sacral region. It is possible for someone to suffer a broken neck,or a broken back without becoming paralysed. This occurs when there is a fracture or dislocation of the vertebrae, but the spinal cord has not been damaged. Sometimes minor swelling of the spinal cord will result in temporary paralysis, which can be recovered from after several weeks or months.

If you would like to read more about people's experiences of Cauda Equina Syndrome, please visit the discussion area of the Cauda Equina Syndrome Forum.

Read the rest here:
Spinal Cord Injury Support - Paraplegic and Quadriplegic

Spinal Cord Injury: Hope Through Research: National …

Scientists continue to investigate new ways to better understand and treat spinal cord injuries.

Much of this research is supported by the National Institute of Neurological Disorders and Stroke (NINDS), a part of the National Institutes of Health (NIH). Other NIH components, as well as the Department of Veterans Affairs, other Federal agencies, research institutions, and voluntary health organizations, also fund and conduct basic to clinical research related to improvement of function in paralyzed individuals.

Many hospitals have developed specialized centers for spinal cord injury care. Many of these bring together spinal cord injury researchers from a variety of disciplines for partnerships regarding basic and clinical research, clinical care, and knowledge translation.

Current research is focused on advancing our understanding of four key principles of spinal cord repair:

Neuroprotectionprotecting surviving nerve cells from further damage

Regenerationstimulating the regrowth of axons and targeting their connections appropriately

Cell replacementreplacing damaged nerve or glial cells

Retraining CNS circuits and plasticity to restore body functions

A spinal cord injury is complex. Repairing it has to take into account all of the different kinds of damage that occur during and after the injury. Because the molecular and cellular environment of the spinal cord is constantly changing from the moment of injury until several weeks or even months later, combination therapies will have to be designed to address specific types of damage at different stages of the injury.

Neuroprotection

Read the original post:
Spinal Cord Injury: Hope Through Research: National ...

Spinal Cord Injury Recovery Treatment – Neuroxcel

Neuroxcels innovative Comprehensive Activity-based Strength Training (C.A.S.T) program offers new hope to postrehabilitation clients recovering from spinal cord injury, stroke andother neurological disorders at our Inclusive Fitness Strength and Conditioning Training Facility.

Based in South Florida, Neuroxcel is the only facility in the State of Florida to offer robotic-assisted gait strengthtraining and functional pattern movement exercises to the public. Neuroxcel takes individuals with spinal cord injury, stroke and other neurological disorders through apost rehabilitation functional movement exercise strength and condtioning training program. Neuroxcel's client's regain the most strength and lost physical ability as a by product of the strength and conditioning training they recieve in the shortest period of time.

Neuroxcels clients are ready to achieve results because they have researched their injury and Neuroxcels C.A.S.T program. They're ready to make the commitment it takes to maximize their individual results. Our degreed and certified exercise training specialists who work with special populations help clients achieve peak physical condition by building total body muscle mass, enhancing muscle memory with exercises,facilitate weight bearing activites andother functional strengtheningexercises for people with neurological conditions.

With our help and the clients commitment, stroke, spinal cord injured andother people with neurological conditions donot have to accepta life of muscle atrophy, loss of strength, function and overall debilitation. We incorporate cutting-edge technologies, including the Hocoma Lokomat Pro, into each qualified clients' weekly routine. Monthly membership includes up to 3 hours in the C.A.S.T. program, available 5 days a week.

Neuroxcel's Inclusive Fitness Strength and Condtioning Training Facility, located in beautiful Palm Beach County, offers year round sunshine and an affordable and accessible living environment. Our clients not only train with us but have the opportunity to enjoy the many educational opportunities, recreational amenities, and social activities with friends and family.

At a cost of less than $54.92 per hour, no other program or facility can compare to the Inclusive Fitness strength and conditioning training Neuroxcel can offer you! Call 1-866-391-62471-866-391-6247 today to set up a tour of Neuroxcels South Florida facility.

Read the original here:
Spinal Cord Injury Recovery Treatment - Neuroxcel

Spinal Cord Injuries Causes and Types – WebMD

The spinal cord is the major bundle of nerves carrying impulses to and from the brain to the rest of the body. Rings of bone, called vertebrae, surround the spinal cord. These bones constitute the spinal column or back bones.

Spinal cord injury is the result of a direct trauma to the nerves themselves or indirect damage to the bones and soft tissues and vessels surrounding the spinal cord.

Visiting the ER for Chronic Pain

Youre a chronic pain patient who takes several prescription narcotics to control your symptoms. Then one weekend, excruciating pain lands you in the emergency room. There, a doctor grills you about your medications, in part to make sure that youre a legitimate pain patient, not someone seeking drugs. What can you do to help the ER doctor to believe you? Its not always easy to tell chronic pain patients from drug-seeking patients, says Howard Blumstein, MD, FAAEM, president of the American Academy...

Read the Visiting the ER for Chronic Pain article > >

Spinal cord damage results in a loss of function, such as mobility or feeling. In most people who have spinal cord injury, the spinal cord is intact. Spinal cord injury is not the same as back injury, which may result from pinched nerves or ruptured disks. Even when a person sustains a break in a vertebra or vertebrae, there may not be any spinal cord injury if the spinal cord itself is not affected.

Spinal cord injuries may result from falls, diseases like polio or spina bifida (a disorder involving incomplete development of the brain, spinal cord, and/or their protective coverings), motor vehicle accidents, sports injuries, industrial accidents, and assaults, among other causes. If the spine is weak because of another condition, such as arthritis, minor injuries can cause spinal cord trauma.

There are two kinds of spinal cord injury -- complete and incomplete. In a complete injury, a person loses all ability to feel and voluntarily move below the level of the injury. In an incomplete injury, there is some functioning below the level of the injury.

View post:
Spinal Cord Injuries Causes and Types - WebMD

Spinal Cord Injury Spotlight – Julia O. at Project Walk San Francisco – Video


Spinal Cord Injury Spotlight - Julia O. at Project Walk San Francisco
Julia suffered a C4 spinal cord injury in 2008. Each month she adds another milestone to her quickly growing list of accomplishments. Here we highlight two of her more recent milestones.

By: Project Walk

See original here:
Spinal Cord Injury Spotlight - Julia O. at Project Walk San Francisco - Video

Wings for Life World Run 2015 – Event Clip – Video


Wings for Life World Run 2015 - Event Clip
Athletes across 35 locations pushed themselves to the limit in the global charity run which raises money to help find a cure for spinal cord injury, and it proved to be a record-breaking day...

By: WingsforLifeWorldRun

See more here:
Wings for Life World Run 2015 - Event Clip - Video

Gong Chen research – spinal cord injury – Video


Gong Chen research - spinal cord injury
Our revolutionary technology holds promise as a potential treatment for many brain and spinal cord injuries and disorders. We recently discovered a way to transform one type of a patient's...

By: PSU Science Media Relations and Public Information

Continue reading here:
Gong Chen research - spinal cord injury - Video

Chris Chappell SCI (Spinal Cord Injury) – Video


Chris Chappell SCI (Spinal Cord Injury)

By: Chris Chappell

View post:
Chris Chappell SCI (Spinal Cord Injury) - Video

Spinal cord Injury The End of my Career-07/22/14 0906 am – Video


Spinal cord Injury The End of my Career-07/22/14 0906 am
The Truck that not only ended my 18yr 2.5 million mile "No Accident" career, After 5 weeks I ended up with 6 bulging discs, spinal cord compression on the right side C3-C4, and the spinal cord...

By: David Godfrey

The rest is here:
Spinal cord Injury The End of my Career-07/22/14 0906 am - Video

OT Lab Final: Spinal Cord Injury – Video


OT Lab Final: Spinal Cord Injury

By: Taryn Graham

More:
OT Lab Final: Spinal Cord Injury - Video

UVA: Tissue Engineering Advances Hold Promise – Video


UVA: Tissue Engineering Advances Hold Promise
Today UVA chemical engineers partner with clinicians to make advances in one of medicine's new frontiers. Tissue engineers harness nature and some synthetic compounds to create tissue-like...

By: University of Virginia

Read more:
UVA: Tissue Engineering Advances Hold Promise - Video

Baltimore’s State Attorney: Gray Death a Homicide – Video


Baltimore's State Attorney: Gray Death a Homicide
The death of Freddie Gray, the 25-year-old man that suffered a fatal spinal cord injury in police custody, has been ruled a homicide.

By: CBN News

See original here:
Baltimore's State Attorney: Gray Death a Homicide - Video

LAB FINAL: Spinal Cord Injury – Video


LAB FINAL: Spinal Cord Injury

By: Taryn Graham

Follow this link:
LAB FINAL: Spinal Cord Injury - Video

Should ‘thug’ be considered a racial slur? – Video


Should 'thug' be considered a racial slur?
Massive protests are underway in Baltimore and other major cities across the U.S., all stemming from the death of Freddie Gray. The 25-year-old was arrested on April 12 and died one week later...

By: HLN

See the original post here:
Should 'thug' be considered a racial slur? - Video

“Is The Caliph Dead” ? What Happens To ISIS? – Video


"Is The Caliph Dead" ? What Happens To ISIS?
Reports are Al-Baghdadi is dead or injured with a spinal cord injury and can't move http://www.paulbegleyprophecy.com also https://www.facebook.com/paul.begley.37 also ...

By: Paul Begley

More here:
"Is The Caliph Dead" ? What Happens To ISIS? - Video

Freddie Gray’s Funeral & Baltimore Mayor Stephanie Rawlings-Blake Condones Riots by Offering Space – Video


Freddie Gray's Funeral Baltimore Mayor Stephanie Rawlings-Blake Condones Riots by Offering Space
Baltimore MA, Freddie Gray was miss treated by Baltimore police which lead to a spinal cord injury and resulted to his death. Baltimore Maryland Mayor Stephanie Rawlings-Blake gave ok to...

By: News Crashers

View original post here:
Freddie Gray's Funeral & Baltimore Mayor Stephanie Rawlings-Blake Condones Riots by Offering Space - Video

Dont Tell Me I Cant: Disability in a Modern World | Cheryl Stowe | TEDxFurmanU – Video


Dont Tell Me I Cant: Disability in a Modern World | Cheryl Stowe | TEDxFurmanU
After a devastating car crash left her in a wheelchair with an incomplete spinal cord injury, Cheryl Stowe tells how we can grow from our pain and be our own heroes. She even shows that we...

By: TEDx Talks

Read more:
Dont Tell Me I Cant: Disability in a Modern World | Cheryl Stowe | TEDxFurmanU - Video

Do Baltimore police have a ‘rough ride’ history? – Video


Do Baltimore police have a 'rough ride' history?
Joe Johns reports from Baltimore, drawing a connection between Freddie Gray's death and a previous fatal spinal cord injury following police transport.

By: CNN

See the article here:
Do Baltimore police have a 'rough ride' history? - Video

Spinal Cord Injury Spotlight – Alexandria T. at Project Walk Boston – Video


Spinal Cord Injury Spotlight - Alexandria T. at Project Walk Boston
Alexandria Teixeira was involved in a car accident in December of 2014, suffering what doctors called a C4 complete spinal cord injury. Project Walk Boston was her first stop after being released...

By: Project Walk

Originally posted here:
Spinal Cord Injury Spotlight - Alexandria T. at Project Walk Boston - Video

Archives