Texas Spinal Cord Injury Attorney
Do you need an experienced Texas spinal cord injury attorney who is Board Certified in Civil Trial Law and also in Personal Injury Trial Law? If you or someone you love has suffered a spine injury, we can help. The Stephens Law Firm have a combined 23 years of experience successfully representing people who have been severely injured due to someone elses negligence and have successfully handled many spinal cord injury cases over the years. A serious spine injury can be an incredibly devastating event not only for the injured but for loved ones as well. We will do whatever we can to help you get the compensation you deserve for your pain and suffering. If you or someone close to you has suffered a spinal cord injury caused by someone or something else such as a defective product, we believe we can help. We have recovered millions for our past personal injury clients and will do everything we can to do the same for you. There is never any up front fee for us to handle your case. If fact, you pay absolutely nothing unless we win. Call us today for a free case evaluation. We make home and hospital visits and will come to you no matter where you are in Texas . We truly go the extra mile for our clients and we believe our experience, past results , and personal attention make us different than most other Texas personal injury attorneys.
Spinal Cord Injury Information
Of all the catastrophic injuries, spinal cord injury is the most
complex. Spinal cord injury is an uncommon condition that has
significant impact on the injured person's functional, medical,
psychological and economic well being. Every year in this country
alone, 8,000 to 12,000 people have a non-fatal spinal cord injury
(SCI) and there are currently more than 200,000 Americans with
SCI. The average age at the time of injury is 15 to 35 years old,
with a male to female ratio of approximately 2:1. Spinal cord
injuries most frequently occur on weekends, specifically between
Friday night from 6:00 p.m. to Sunday morning at 6:00 a.m. The
peak season of the year for spinal cord injury is in the summer.
The most common causes are motor vehicle accidents, followed by
falls, sports injuries and violence. Injury prevention remains
the most effective method of decreasing the incidence of spinal
cord injuries.
Spinal cord injury rehabilitation requires comprehensive medical and therapeutic patient management. It is a multi-step process that starts immediately after the accident and continues for the remainder of the patient's life. Rehabilitation intervention commences at the time of injury with management of the acute trauma. This is the most critical time as the patient is at highest risk for SCI complications, including death. Acute rehabilitation follows with interdisciplinary intervention from physicians, rehabilitation nurses, physical, occupational and respiratory therapists, speech pathologists, case managers, psychologists, social workers and therapeutic recreation therapists.
A spinal cord injury can be a devastating incident, to say the least. Too many victims are left paralyzed as a result of these types of injuries. It is estimated that the annual incidence of spinal cord injury (SCI), not including those who die at the scene of the accident, is approximately 40 cases per million in the United States . Each year, there are approximately 11,000 new cases of spinal cord injury.
Spinal cord injuries most commonly result from automobile
accidents. Other common causes are falls, sporting accidents,
bicycling accidents, or some form of violence. Any injury to the
spinal cord can affect its ability to send and receive messages
from the brain to and from other parts of the body. This is why
injuries to this area must be taken seriously. The costs
associated with spinal cord injuries can be astronomical, aside
from the loss in wages, benefits, and productivity.
There are different levels of severity in spinal cord injury. A
spinal cord injury can be "complete" or "incomplete."
- Complete. The nerve damage blocks all signals from the brain to the body parts located below the injury site.
- Incomplete. The nerve damage only affects some of the signals from the brain. The closer the injury is to the brain, the greater the loss of feeling and function.
For example: "Paraplegia" results in loss feeling and the
inability to move the lower parts of the body. Quadriplegia or
Tetraplegia results in the loss of feeling and the inability to
move both the upper and lower parts of the body.
Anatomically, the spine, or vertebral column, is comprised of
vertebral bodies separated by intervertebral discs and supported
by many ligaments. The vertebral column is divided into cervical,
thoracic, lumbar, sacral and coccygeal regions. There are seven
cervical, twelve thoracic, five lumbar, five fused sacral and
four fused coccygeal vertebrae. Structurally, a typical vertebra
is comprised of an anterior portion called the vertebral body and
a posterior portion called the neural arch. The neural arch
consists of a pair of anterolateral pedicles, a pair of
posterolateral laminae, four articular processes, two transverse
processes and one spinous process. The bony portion of the spine
provides structural integrity to the entire vertebral
column.
The spinal cord is encased in supporting structures that protect
its fragile, gelatinous nature. These supporting structures
include bone and ligaments. Although there are eight ligaments
that help to maintain spinal stability, the most important
supporting structures are the anterior longitudinal ligament, the
posterior longitudinal ligament and the intervertebral discs.
When there are insignificant or no bony fractures in a spinal
injury, the stability of the vertebral column lies with the
integrity of the ligaments.
The bony vertebral column and the supporting ligaments determine
the amount of motion that is possible in the spine. In the
cervical spine, there is greater range of lateral flexion and
rotation than in any other portion of the spinal column. Maximum
bending in flexion and extension occurs between C4 and C6. The
thoracic region is less flexible but more stable than the
cervical region because of the limitations provided by the rib
cage. The lower thoracic and lumbar spine has the capability to
resist an imposed load (stiffness) secondary to the design of the
facet joints in these areas.
SPINAL CORD INJURIES
Traumatic spinal cord injuries are associated with skeletal and
ligamentous as well as intraspinal pathology. The most common
cervical level for spinal cord injury is C5, followed by C6 and
then C4. T12 is the most common thoracic level for spinal cord
injury.
Traumatic spinal cord injuries are most commonly secondary to
motor vehicle accidents and gunshot wounds, followed by falls,
bicycle accidents, and pedestrian verses auto accidents.
Fractures, dislocations, bleeding and swelling can precipitate
trauma to the cord. A common misnomer is that the cord is
"transected" when injured; however, the spinal cord is rarely
physically transected. It may be stated that the cord is
"physiologically transected" as it loses it's supply of oxygen
and glucose as a result of traumatized blood vessels that supply
that level of the cord, inducing inflammation and irreversible
damage to the central neurons.
Depending on the type of skeletal and intraspinal pathology
sustained in a spinal cord injury, an associated neurologic
picture will result. This neurologic picture is based on the
organization that is present in the spinal cord where motor,
sensory and autonomic nerve tracts run systematically from the
periphery to the brain. In the majority of traumatic spinal cord
injuries, there is skeletal as well as ligamentous damage
associated with spinal instability, which necessitates surgical
intervention such as fusion. However, there are cases such as gun
shot wounds, where mere shock waves can induce enough trauma to
the cord to produce swelling and hemorrhage, leaving the
vertebral column intact but resulting in a complete lesion.
SCI CLASSIFICATION
The classification for spinal cord injury is based upon the
initial neurologic examination. The term "tetraplegia" has
replaced "quadriplegia," and refers to injury to the cervical
region of the spinal cord. The term "paraplegia" refers to injury
to the spinal cord in the thoracic, lumbar, and sacral
segments.
The spinal cord "level of injury" is named for the last
preserved or normal level of motor and sensory function.
Therefore, with a C5 quadriplegia, the motor and sensory nerves
are intact down to the C5 level; C6 and below are affected.
Spinal cord injuries can either be complete or incomplete in
nature. Complete injuries are defined as having no detectable
motor or sensory findings below the level of injury and abnormal
autonomic function. Incomplete injuries have some preserved
motor, sensory or autonomic function below the level of
injury.
The American Spinal Injury Association has defined the ASIA
IMPAIRMENT SCALE for spinal cord injury. This taxonomy supersedes
the previously well used Frankel Classification system.
- = Complete: No motor or sensory function is preserved in the sacral segments S4-S5.
- = Incomplete: Sensory but not motor function is preserved below the neurologic level and extends through the sacral segmentsS4-S5.
- = Incomplete: Motor function is preserved below the neurologic level and the majority of key muscles below the neurological level have a muscle grade of less than 3.
- = Incomplete: Motor function is preserved below the neurologic level and the majority of key muscles below the neurological level have a muscle grade greater than or equal to 3.
- = Normal: Motor and sensory function is normal.
The ASIA Classification is divided into complete and
incomplete injuries and utilizes the nomenclature A, B, C, and D.
A patient with ASIA A has more neurologic deficits than a person
with ASIA D. Keep in mind that the more neurologic function
preserved, the more potential a patient has regarding activities
of daily living and mobility. Therefore, a patient with a C6 ASIA
Classification of D has potential for a more functional lifestyle
than one with a C6 ASIA Classification of A. In spinal cord
injury rehabilitation, long and short-term goals are established
based upon the patient's neurologic level and degree of preserved
function below the level of injury.
Key Muscles for Determining the Level of Lesion are as
follows:
C5 Elbow flexors (biceps flexes forearm)
C6 Wrist Extensors (cock-up wrist)
C7 Elbow Extensors (triceps straightens elbow)
C8 Finger flexors (flex fingers to grip)
T1 Small finger abductors (spreads fingers)
L2 Hip Flexors (flexes hip)
L3 Knee Extensors (quadriceps straightens knee)
L4 Ankle dorsiflexors (bends ankle up and lifts foot)
L5 Long toes extensors (lifts big toe)
S1 Ankle plantarflexors (calf muscles push foot down)
The following Clinical Syndromes of Spinal Cord Injury are
recognized:
Central Cord Syndrome
A lesion, occurring almost exclusively in the cervical region,
that produces sacral sparing and greater weakness in the upper
limbs than in the lower limbs.
Brown-Sequard Syndrome
A lesion that produces rather greater ipsilateral (same-sided)
proprioceptive and motor loss and contralateral (other side) loss
of sensitivity to pin and temperature.
Anterior Cord Syndrome
A lesion that produces variable loss of motor function and of
sensitivity to pin and temperature, while preserving
proprioception.
Conus Medullaris Syndrome
Injury of the sacral cord (conus) and lumbar nerve roots within
the neural canal that usually results in areflexic (reflex loss)
bladder, bowel and lower limbs. Sacral segments may occasionally
show preserved reflexes (bulbocavernosus and micturition
reflexes).
Cauda Equina Syndrome
Injury to the lumbosacral nerve roots within the neural canal
resulting in areflexic bladder, bowel and lower limbs.
ACUTE MANAGEMENT
The emergency medical care system is the patient's point of
entry into the medical care system. The goal during this period
is for the SCI patient is to immobilize the spine to prevent
further damage to the spinal cord prior to reaching the emergency
room. Maintenance of an adequate airway, cardiopulmonary
resuscitation, and fluid management are required to ensure
survival and limit secondary damage.
The acute management of traumatic spinal cord injury is unique
and requires specialized medical training. Among the issues
addressed are spinal stabilization, pulmonary rehabilitation,
gastrointestinal and urinary function, hemodynamics and
thermodynamics. Although this discussion will focus on these
medical issues, it should be remembered that SCI is associated
with psychosocial adjustment, and oftentimes substance abuse
withdrawal and head injury.
In acute spinal cord injury, it is considered standard of care
to implement high doses of intravenous (IV) steroids
(methylprednisolone), which has been scientifically shown to
decrease the swelling in the spinal cord after a traumatic
insult. The protocol is administered within the first eight hours
of the injury and is completed within 24 hours. There has been no
documented medical benefit supporting the administration of
methylprednisolone after the initial eight-hour period. In spinal
cord injury research and development, there are nerve
regenerating medications as well as surgeries that are being
investigated throughout the country. Most notable is the Gm-1
Ganglioside (Sygen). The intended purpose of this medication is
to improve the patient's neurologic function when administered
within 72 hours of injury. The results of the multi-center
investigation are slated to be available February 1998.
As stated above, spinal cord injury is most often associated
with skeletal instability. This can occur at the cervical,
thoracic or lumbar level. Patients are optimally managed in a
rotokinetic bed, but may be "log-rolled" by trained staff every
two hours. The rotokinetic bed acts as a body cast to stabilize
the spine until surgical fusion. Cervical injuries, in addition,
usually require weighted traction via a halo ring or tongs. After
cervical fusion, depending on the type of surgical stabilization,
continued external immobilization via a halo vest or a cervical
orthotic (Philadelphia collar) is required for a period of time
defined by the surgeon. Although spinal stabilization is
necessary to correct fractures and dislocations, it must be
remembered that it rarely improves the neurologic function of the
patient. In the majority of cases, therefore, the neurologic
level that the patient has at the time of injury is the level of
function that the patient has to work with during rehabilitation
and live with for a lifetime.
In the acute trauma setting, patients with spinal cord injury are routinely hypotensive. This is manifest by low blood pressure that is most often corrected by intravenous fluids. However, this type of hypotension is a result of neurogenic shock or "spinal shock," which is secondary to autonomic nervous system dysfunction. Until the patient is determined to be spinal cord injured, high volumes of IV fluids are introduced which puts the patient at a hemodynamic disadvantage, and places the respiratory status at risk for pulmonary edema. Once the patient is known to be spinal cord injured above the level of T9, IV fluids are gingerly administered and the pulmonary status must be monitored very closely. Blood gases are ordered. The patient typically receives oxygen via nasal canula and begins respiratory therapy exercises. There is a low threshold for intubation especially in patients with cervical injury and a history of smoking or asthma. In the acute spinal cord setting, the two most common causes of death are infection and respiratory complications. The patient's pulmonary status is aggressively monitored and treated.
In addition to neurogenic shock, other organ systems also slow
down. An ileus develops (bowel functions slows or ceases) in the
gastrointestinal system, and the risk for associated stress
gastritis is present. The patient is treated with bowel rest and
IV administration of an H2 blocker. Occasionally, with severe
gastritis, blood transfusions are necessary. The bladder is also
affected by these autonomic changes, becoming hypotonic and
non-contractile. Treatment is with indwelling (Foley)
catheterization.
Finally, during spinal shock, patients have difficulty
maintaining a stable core body temperature. They tend to take on
the room temperature; if it is hot, they are hot, and conversely
if it is cold, they will be cold. Patients commonly arrive at the
acute care setting with hypothermia or hyperthermia, and must be
managed by someone skilled in the rehabilitation of acute spinal
cord injury.
Preventing pressure sores is an ongoing challenge during the
acute care phase. In the supine position, the back of the head,
the sacrum and heels are at particularly risk. Special mattresses
are available as well as seating cushions. While in bed, a
regular turning schedule is emphasized. Non-blanching erythema
(redness) is considered a grade I ulcer and a precursor to skin
ulceration.
Joint contractures should be prevented by frequent range of
motion and orthotics may be needed as well. The individual in bed
with a spinal cord injury is at significant risk for a deep
venous thrombosis and prophylaxis (up to twelve weeks) should be
started early with a short-acting anti-coagulant (such as low
molecular weight heparin) which can be supplemented with support
stocking and intermittent compression boots.
SCI REHABILITATION
In a comprehensive rehabilitation facility, interdisciplinary
intervention begins as soon as the patient is medically stable
enough to tolerate therapy. This may be as soon as the day
following injury. In fact, the sooner therapies begin, the better
chance there is of preventing SCI complications such as the
formation of joint contractures. The Rehabilitation Team should
be meeting two to three times per week to facilitate progress in
the patient's short and long-term goals, modifying them
appropriately as the medical status dictates. An example of this
is an associated head injury where the cognitive signs may not
become apparent until therapies ensue, necessitating drastic
changes in anticipated long-term goals.
During rehabilitation, the patient learns the fundamentals of spinal cord injury with the ultimate goal of being as independent as the neurologic level and ASIA Classification allow. Discharge planning, mobility, self care, cognition, bowel and bladder, durable medical equipment, education, vocational retraining, adjustment to disability and family training are among the areas addressed during aninpatient stay.
LEVEL OF INJURY |
MOBILITY |
ADL’S |
C1, C2, C3, C4 |
power wheelchair (chin drive or sip-n-puff) dependent transfers |
dependent for all careadapted computer use |
C5 |
power wheelchair (arm |
self-feed after set up, light |
C6 |
manual and/or power chairsliding board transfers |
above plus: 25% dressing modified weight shifts |
C7 |
manual chair transfers w/o sliding board |
above plus: 50% dressing depression weight shifts |
C8 |
same as above |
(has finger function) independent with all ADL’s |
T1-T6 |
same as above |
independent with all ADL’s |
T7 - T11 |
same as above with better |
independent with all ADL’s |
T12 and below |
same as above may potentially ambulate |
independent with all ADL’s |
It is apparent that the more function a patient has, the more independent he or she may be. The neurologic level generally dictates the potential functional capability of the injured person for rehabilitation. Breathing with or without assistance is no exception. A C1, C2, or C3 complete (ASIA A) tetraplegic will be ventilator dependent. C1 and C2 tetraplegics have the potential for the surgical implantation of phrenic nerve pacemakers so that they may breathe without a ventilator attached to the tracheotomy. Otherwise healthy patients with a C4 injury or below can be weaned completely from the ventilator. A C3 complete tetraplegic like Christopher Reeves may breathe for short periods off the ventilator and talk using a special "talking" trach. Functional expectations similarly apply to mobility and self care. The following table represents general capabilities of an ASIA A tetraplegic with the stated level of injury. Some patients may do more and some less depending on many factors including age, motivation, premorbid health, home environment, and associated diagnoses such as head injury or depression.
Independence and privacy are significant issues in the self-care activity of bowel and bladder management. Learning how to manage these functions of elimination is a complex and sensitive task. Oftentimes a family member, such as a spouse or mother, must perform the care because the patient does not have enough function to master it independently. The neurogenic bladder is optimally managed with intermittent catheterization via the clean technique approximately every 4-5 hours. This requires a clean (but not necessarily sterile) urinary catheter and lubricant. Although debated, another preferred method of management of the male bladder is a sphincterotomy and condom catheter. The choice between the two is usually physician-specific. The next best way to care for the bladder is with a suprapubic catheter, followed by an indwelling urethral catheter. It is important to note that any indwelling catheter increases the risk of urinary tract infection, and it is still unclear as to whether prophylactic antibiotics are beneficial. In a neurogenic bowel, the gastrointestinal tract functions normally until the fecal matter reaches the descending colon, where peristalsis essentially stops. For evacuation to occur, a scheduled bowel program is performed. It consists of oral and rectal medications plus digital stimulation. Again, someone often must perform this personal activity other than the patient, as it requires adequate hand (finger) function.
With spinal cord injury being so complex, many complications are possible in the short and long term. In the acute medical setting, after the resolution of spinal shock, autonomic dysreflexia (or hyperreflexia) may occur and is considered a medical emergency. Most physicians do not know what this problem is or how to treat it; therefore, patients and families should not leave the hospital without thoroughly understanding how to recognize the symptoms of dysreflexia and what to do about it. In patients with lesions above T9, the dysfunctional autonomic nervous system can induce dangerously high blood pressures when a noxious stimulus affects the body below the level of injury. This stimulus is most frequently a distended bladder, but may be a urinary tract infection, full bowel, new decubitus ulcer, ingrown toenail, or even sunburn. The symptoms of autonomic dysreflexia are severe headache, flushing of the face, sweating above the level of injury, post nasal drip, anxiety...signs that the sympathetic nervous system has been hyper-activated. Blood pressures of 200/100 may develop in patients whose pressures are normally 90/60 now that they have a spinal injury. The consequences of untreated, ongoing dysreflexia may be devastating leading to stroke, coma, seizure or death. The treatment of this SCI-related phenomenon focuses on safely lowering the blood pressure and removing the initial noxious stimulus. Patients should carry cards or medals that will identify the syndrome and outline appropriate medical intervention.
Another complication of SCI is the development of decubitus ulcers that may occur at any time in the person's life. The more severe (large and deep) the sore is, the more at risk for a complication such as superimposed infection. The consequences of a severe decubitus may be as radical as amputation or death, and the costs incurred are potentially staggering. Although treatment may require bed rest, dressing changes, or flap surgery, prevention is the best way to deal with pressure sores which is why frequent pressure relief via weight shifts is imperative.
Less devastating but equally important complications of spinal cord injury are spasticity, contractures, and heterotopic ossification. Spasticity is considered a normal part of SCI as it is a manifestation of an injury to the central nervous system. The management pyramid stretches from range of motion and medications to baclofen pumps and the surgical release of tendons. Joint contractures may develop as a result of severe spasticity and are not only disfiguring but can diminish the amount of function (and therefore independence) a person has. Heterotopic ossification is the development of bone across a joint, leading to less range and therefore less function. It may cause a once adequate wheelchair to become non-useful, as the person cannot sit properly or activate the arm drive. It most commonly occurs in the hips and knees, but can also be seen in the shoulders and elbows. There is no known reason as to why heterotopic ossification develops in one patient and not another, and treatment with oral medications such as NSAIDs or etidronate are controversial and often not effective. Research is ongoing for successful early intervention. In the meantime, aggressive range of motion is useful in its early stages of development.
Rehabilitation is a lifelong process for the person with a spinal cord injury. Formal training may continue from the inpatient setting to outpatient and home as appropriate. It takes months of learning and practice for a patient to physically manage paralysis; yet it often takes much longer to emotionally accept his or her life as a disabled person. The transition from inpatient to outpatient or home and from home to community-based services should therefore be well coordinated via case management to ensure the most successful outcome possible.
Future is brighter
Generally, the earlier recovery begins and the more rapid its
progress, the better the prognosis. In scientific studies, most
recovery occurs during the first six months, and may continue up
to two years post injury. Patients with incomplete spinal cord
injury lesions have a better chance of recovery than those with
complete lesions.
Research and development for "fixing severed spinal cords" has
been ongoing for decades. Allocation of funds for this disorder,
however, is scarce when compared to more common maladies such as
coronary artery disease. Since the unfortunate accident of
Christopher Reeves that rendered him a ventilator-dependent
tetraplegic, SCI has entered into the limelight and more money
has been donated from the private sector. It is therefore hoped
that within the next few decades a breakthrough for SCI may be
established. It is the dream of many individuals that complete
paralysis of acute SCI may be prevented and chronically injured
persons may regain motor function.
In the meantime, because of medical advances in early and appropriate intervention in acute SCI, patients are living longer and experiencing more related complications as a result. The medical cost may be considerable as the SCI patient may live many years post injury. Experience shows that the more comprehensive the initial education and training are, the better the patient and family are in understanding the manifestations of spinal injury and in preventing complications through the years.
A person with SCI, especially with a diagnosis of ASIA A tetraplegia, should be regularly followed by a team of physicians including a primary care practitioner annually, a specialist in SCI rehabilitation (such as a physiatrist) at least every other year and for special circumstances and a urologist per medical discretion. Referrals to medical and ancillary specialists should not be delayed. One example of potential cost savings is to have a therapist rather than a vendor evaluate a patient for a new wheelchair. With more patients "recovering" from SCI as well as living longer, money should be thoughtfully spent as penny-wise in the short run may prove to be pound-foolish in the long run. The goal is to provide first-rate, cost-effective medical care to this disabled population
Rehabilitation of the spinal cord injured patient is complex. It is a continuum of treatment provided by specialty-trained professionals who assist the patient in learning to deal with his or her new disability. Intervention should begin as early as the day of injury and continue throughout the patient's lifetime. Despite being permanently disabled, patients have the potential to be as independent as they can, provided they are given appropriate tools and training. Comprehensive spinal cord injury rehabilitation can create accomplishment and independence from catastrophe and disability, offering hope and optimism to patients with spinal cord injury.
Spinal Cord Injury Statistics
The number of people in the United States who are alive in July
2005 who have Spinal Cord Injury (SCI) has been estimated to be
approximately 250,000 persons, with a range of 225,000 to 288,000
persons. Since 2000, the average age at injury is 37.6 years.
More than half of those who sustain an injury are between the
ages of 16 and 30. Moreover, the percentage of persons older than
60 years of age at injury has increased from 4.7% prior to 1980
to 10.9% among injuries occurring since 2000. Motor vehicle
crashes account for 47.5% of reported SCI cases. The next most
common cause of SCI is falls, followed by acts of violence
(primarily gunshot wounds), and recreational sporting activities.
The proportion of injuries that are due to sports has decreased
over time while the proportion of injuries due to falls has
increased. Acts of violence caused 13.3% of spinal cord injuries
prior to 1980, and peaked between 1990 and 1999 at 24.8% before
declining to only 13.8% since 2000.
Learning how to live with a spinal cord injury is only part of the problem. The financial burden the victims of such injuries face can be overwhelming, particularly if the injury was due to the negligence of another person or entity. The cost of the injury itself varies, depending upon the severity of the injury, but in addition to the cost of hospitalization, surgery bills, and rehabilitation, it has been estimated that spinal cord injuries average over $60,000 per year for the average person based on education, severity of injury, and pre-injury employment history.
Joe Stephens is a double Board Certified in the fields of Personal Injury Trial Law, and Nationally as a Civil Trial Advocate by the National Board of Trial Advocacy. He has tried many cases involving spinal cord injuries. The spinal cord injury attorneys at The Stephens Law Firm can help. We make home and hospital visits and will come to you wherever you are in Texas. Call us today to schedule your free consultation and let us help you like weve helped many others in your situation.
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