Impossible to tell what is occurring, the damage diagnosis does not help any layperson understand this.
https://consultqd.clevelandclinic.org/2017/10/first-trial-of-dbs-for-stroke-recovery-initial-patients-functional-progress-continues-through-5-months/?utm_campaign=qd%20tweets&utm_medium=social&utm_source=twitter&utm_content=171018%20stroke%20recovery&cvosrc=social%20network.twitter.qd%20tweets&cvo_creative=171018%20stroke%20recovery
A trial status update and overview of investigational aspects
The first patient to ever undergo deep brain stimulation (DBS) to
enhance motor rehabilitation following hemiparesis after ischemic stroke
has experienced significant and steady functional improvements
throughout the first five months of management pairing DBS with
rehabilitative therapy. The 59-year-old woman had a DBS electrode
surgically implanted in her cerebellum in December 2016 as the first
participant in a first-in-human clinical trial of DBS for stroke
rehabilitation, which is being conducted at Cleveland Clinic. This
article briefly reviews the patient’s progress and our study’s
rationale, design details and current status.
Essentials of the trial
Our trial is examining a novel strategy — stimulation of the
dentatothalamocortical pathway to enhance excitability and plasticity
across spared cerebral cortical regions — with the aim of promoting
recovery of motor function following stroke. The primary hypothesis is
that by applying DBS to the connections between the cerebellum and
cerebral cortex, we can facilitate the plasticity that occurs in the
surviving cortical regions around the stroke and thereby promote
recovery of function beyond what rehabilitative therapy alone can
accomplish.
For this initial trial, we plan to enroll 12 patients who, despite
traditional rehabilitative therapy, have persistent, severe residual
hemiparesis from an ischemic stroke 12 to 36 months earlier. In addition
to the patient reported here, a second patient has undergone DBS
electrode implantation but hasn’t completed enough subsequent therapy
for results to be reported.
The study is being conducted solely at Cleveland Clinic with funding
support from the National Institutes of Health’s BRAIN initiative.
Initial treatment protocol — and first patient’s response
The trial’s initial protocol began as follows:
- One month of twice-weekly rehabilitative (physical plus occupational) therapy to establish baseline function
- Surgery to implant the DBS electrode and battery
- Four-week resting period at home to recover from surgery
- Eight weeks of therapy without the DBS device turned on, to establish a new functional baseline
- Four weeks of programming the DBS device with the aid of transcranial magnetic stimulation
- Four months of therapy with the DBS device turned on continuously
Within a few weeks of when the DBS device was turned on, the trial’s
first patient reported she could move her affected arm in ways she
hadn’t been able to since her stroke (Figure 1). Her function has
steadily and progressively improved ever since, as measured by the upper
extremity subscale of the Fugl-Meyer Assessment of Motor Recovery after
Stroke. She reports that she is now able to use her affected arm to
cook, play games with her grandchildren, fold laundry and perform many
other routine tasks. Her functional progress had not yet plateaued as of
this writing, approximately five months after stimulation was started.
Continuing improvement prompts protocol revision
The initial trial protocol called for a slow weaning from stimulation
over the course of a month after completion of four months of
concurrent DBS and physical therapy. However, continued progress by the
first patient across even the fourth month of stimulation prompted us to
obtain FDA approval to revise the protocol and extend therapy.
Concurrent DBS and physical therapy will now continue for several
additional months to afford the patient the opportunity for additional
improvement, with stimulation weaned after nine months of treatment or
when the patient’s motor improvement appears to have plateaued
(whichever comes first).
Additional aspects of our investigation
In addition to the above functional outcomes that are the centerpiece
of this trial, we are conducting many other investigations to better
understand the relevant anatomy and refine the DBS technique used in
this novel setting of stroke recovery. These investigations include the
following:
7T magnetic resonance imaging (MRI). Each
trial participant undergoes 7T MRI prior to surgery to allow optimal
visualization of target brain structures. Our team’s engineers use these
images to develop patient-specific models of the pathways that we are
attempting to modulate in order to achieve the therapeutic goal. These
7T images and the resulting models will help create a guidebook to
elucidate the relevant anatomy for neuromodulation for stroke
rehabilitation moving forward. While postoperative 7T MRI evaluation
would be valuable as well, the DBS device used is currently incompatible
with MRI.
Serial positron emission tomography (PET).
All patients undergo a series of four FDG-PET imaging studies — at
enrollment, after DBS electrode implantation, during DBS treatment and a
month after stimulation is turned off. These studies will test our
hypothesis that metabolic activity along the brain pathway being
targeted with DBS will increase in conjunction with any observed
therapeutic improvements. Below is a baseline FDG-PET image from the
trial’s first patient showing a right hemisphere stroke (Figure 2).
We are supplementing our initial 7T imaging guidance with
intraoperative SSEP and EEG recordings at the time of DBS lead
placement. These techniques may allow us to determine which electrical
contacts along the octopolar lead are showing greater representation of
motor-related neural activity and to assess changes in activity in
response to acute stimulation in different areas. Given that
neuromodulation for stroke rehabilitation — in contrast to movement
disorders — does not allow immediate motor feedback once stimulation is
started, this type of intraoperative testing can be invaluable in
helping to determine which contacts to use for chronic therapy.
Transcranial magnetic stimulation (TMS) to assess cortical changes.
Our team is using TMS as part of the acute programming sessions to
assess whether DBS is enhancing excitability across the areas of cortex
where we hope to achieve functional change. Additionally, TMS is being
used to map the representation of motor activity for different regions
of the body across those same spared cortical regions in order to
identify whether any functional reorganization of the cortex is being
achieved in response to therapy.
On the horizon
We also plan to introduce several additional assessments for trial participants going forward, including:
- Non-motor testing by a neuropsychologist to ensure there is no
disruption of cognitive processes involving the stimulated brain region
- Use of a robotic device on which patients perform video game-like
tasks to assess reaction and movement time, jerkiness of movement and
similar performance measures
An additional goal is to initiate the development of paired
associative stimulation paradigms that use the electrophysiological
information that we record from the dentate nucleus to provide
stimulation in a timing-dependent manner. The result would be a
“smarter” closed-loop system that actively reinforces a patient’s
attempted movements instead of relying on constant reinforcement.
Clearly, many questions remain, but we are encouraged by the positive
results so far in our trial’s initial patient. We look forward to
learning much more as this study continues.
Dr. Machado is a neurosurgeon and Chairman of Cleveland Clinic’s Neurological Institute.
Dr. Baker is a neuroscientist in the Department of Neurosciences in Cleveland Clinic’s Lerner Research Institute.
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