CREST-H sites will be drawn from actively-enrolling CREST-2 centers. The additional
information obtained in CREST-H in this protocol will be the MR or CT imaging, which will
be done at baseline for all patients enrolled in CREST-H, and at 1 year for those with
hemodynamic impairment at baseline. The protocol will recommend an unblinded investigator
at each CREST-H site who will order and obtain the study-related MRI sequences, upload
de-identified image files to the CREST-2 central imaging site at U Maryland, and maintain
blinding of the hemodynamic imaging data for their site (see Blinding below). Image
analysis will be done at UCLA (for perfusion studies) and at Mayo Rochester for
structural scans -- silent infarcts, WMH and microbleeds. Data management and statistical
analysis will be done at UAB, which serves this role for CREST-2.
Cognitive Assessment.
CREST-H will use existing CREST-2 cognitive assessment infrastructure -- the Survey
Research Unit at University of Alabama Birmingham. Added to the current CREST-2 battery
is the Oral Trail Making A & B as an additional measure of executive function, which will
be administered to every CREST-2 patient, regardless of their participation in CREST-H.
Cognitive assessments in CREST-H must take place prior to revascularization or within two
weeks after assignment to medical therapy alone. Testing in CREST-2 is repeated at 1
year, and every year thereafter up to 4 years. At each test interval, a composite (mean)
Z-score is derived from published normative samples for each test outcome. The CREST-H
primary outcome will be at 1 year in which the change in the composite Z-score from
baseline will be calculated. Covariates will include age, education and depression. The
test battery will be administered by a blinded assessor the same way for all CREST-2 and
CREST-H enrolled patients. The cognitive domains being assessed in CREST-2/H are entirely
consistent with those encompassed within the NINDS Common Data Elements (CDE).
Imaging protocol.
Multimodal MRI or CT perfusion imaging will be performed at baseline on every study
subject.
Multimodal MRI, including routine parenchymal sequences and PWI utilizing dynamic
susceptibility contrast technique, will be acquired at each participating CREST H site
who have been approved for this imaging modality. CT perfusion, using iodinated contrast,
will be used as an alternative PWI image for sites approved for this modality. Imaging
will take place within 14 days after CREST-H enrollment and prior to any CREST 2
intervention for those randomized to CEA or CAS.
Standardized contrast agent injection protocol, appropriate preparation, and IV setup is
used to ensure good scan quality. An antecubital vein IV catheter of 18-20 gauge is
required. A test injection will be performed with approximately 10 ml of normal saline
solution.
MRI image acquisition DWI/ADC (b=0, 1000 s/mm2 applied in each of three principal
gradient directions), FLAIR, high-resolution T1, and GRE sequences will be acquired on
1.5-3.0 T scanners equipped with echo-planar imaging capability, using standard clinical
protocols at participating CREST-H sites Total scanning time will be approximately 40
minutes. PWI acquisition protocol will be standardized across all CREST-H sites, using
sequential T2*-weighted (gradient echo) EPI time sequence scanning. A modified 2-phase
contrast injection scheme will be used to perform CEMRA and DSC perfusion imaging,
without need for additional contrast.
CT perfusion imaging will follow the protocol outlined in the updated Imaging MOP for
CREST-H. The CT perfusion study is identical to the clinical CTP protocol used for acute
stroke imaging in most institutions.
Perfusion imaging analysis.
PWI source images will be sent to the core laboratory at UCLA and processed with the
OleaSphere software platform, using deconvolution of tissue and arterial signals in an
expedited manner, yielding standardized data regardless of the acquisition system at each
site. Hemodynamic impairment is defined as TTP >1.25 sec in the middle cerebral artery
and anterior cerebral artery territories of the ipsilateral hemisphere to the carotid
lesion compared with the same territory in the opposite hemisphere. Longitudinal analyses
will investigate the change in the TTP >1.25 sec lesion at 1 year comparing the
revascularization versus the medical only arm. Continuous values for this volumetric
change will be used to calculate the correlation between degree of cognitive change and
degree of perfusion change. The continuous Tmax variable, as well as standard perfusion
parameters of CBV, CBF Tmax, and MTT will be analyzed on the serial imaging studies in
each case with MR imaging. Co-registered, voxel-based changes in serial perfusion values
will also be explored with multiparametric (e.g. CBV, CBF, Tmax, MTT) values.
Image de-identification and blinding.
All MR or CT image files will be de-identified under the supervision of an unblinded
Investigator (UI) at each institution and uploaded to the CREST-2 Imaging Core site at U
Maryland. In order to assure that the PWI scan information from CREST-H does not
compromise the integrity of the parent trial, the results of the perfusion scan will be
blinded to the investigator team.
Image transfer.
Participating sites will utilize the same file transfer protocol (ftp) to transfer images
to U Maryland for CREST-H as is already established for CREST-2. The images will be
stored in a HIPAA-compliant, firewall protected server within the U Maryland archival
system. A CREST-2 dedicated ftp linkage between the VIC at U Maryland and UCLA; and the
VIC at U Maryland and Mayo-Rochester will be utilized to make each perfusion image file
available for download by UCLA (Liebeskind lab) and each structural image (DWI, FLAIR,
GRE) by Mayo-Rochester (Huston lab).
MRI structural analysis.
Structural MRI analysis at Mayo-Rochester will utilize NIH NINDS Common Data Elements
developed for the CREST-2 grant. The following definitions apply:
1. silent infarct --- non-confluent hyperintense lesion >1mm on FLAIR sequence on
1-year MRI not present on baseline FLAIR MRI.
2. Cerebral microbleed - hypointense 1-2mm non-confluent lesion on baseline GRE
sequence.
3. WMH volume -- White matter hyperintensity volume refers to confluent periventricular
high intensity lesions on FLAIR imaging, and will be derived using an automated T2
WMH quantification at the Huston lab.
Data from image analysis (TTP delay, WMHV, silent infarct count, microbleed count)
performed at UCLA and Mayo-Rochester will be entered electronically on CREST-H data forms
via the CREST-2 SDCC website at UAB, where it will be stored on a separate webpage linked
to the rest of the CREST-2 data, including baseline and yearly cognitive assessments. The
electronic data entry system (eDES) for CREST-2 is a mature system, successfully reviewed
by FDA audit in other studies, providing standard approaches for
entry-confirmation-locking of data forms, and supporting range and validity checking for
data provided.
. Analysis.
Specific Aim 1. To determine whether cognition can be improved by revascularization among
a subset of CREST-2 patients with hemodynamic impairment at baseline.
The primary hypothesis is to assess if the magnitude of the treatment differences
(revascularization versus medical management alone) differs between those with flow
failure compared to those without flow failure using the Z-scored cognitive outcomes (C0,
C(1). That is, the primary hypothesis is an interaction hypothesis that will be assessed
using linear regression, specifically: (C1 - C0) = β0 + β1T + β2F + β3TF + β4C0 + (other
covariates), where C1 is the cognitive z-score at year 1, C0 the cognitive z-score at
baseline, T the treatment indicator variable, F the flow failure indicator variable, and
βi the regression parameters to be estimated. The parameter of interest for the primary
hypothesis is then β3 that would assess if the magnitude of treatment difference in the
change in cognitive score between baseline and 1-year is similar for those with versus
without flow failure.
Secondary Aims: To determine if the number of silent infarcts and white matter
hyperintensity volume at 1 year is different between the revascularization and the
medical-only arms.
For the secondary aims we will calculate the number of new silent cerebral infarctions
occurring over the first year, and the change in the WMH volume. The approach for
analysis of the number of new silent infarcts will depend on the average number and
distribution of the number of new infarcts. The analytic approach will be linear
regression if the number of new infarcts is large (considered more likely the case), or
Poisson Regression if the number is smaller (considered less likely the case). The
analysis of the change in WMH will use a linear regression approach.