Skip to main content
PMC home page
NIHPA Author Manuscripts logoLink to NIHPA Author Manuscripts
. Author manuscript; available in PMC: 2022 Nov 1.
Published in final edited form as: J Pediatr Hematol Oncol. 2021 Nov 1;43(8):e1062–e1068. doi: 10.1097/MPH.0000000000002103

Transcranial Doppler Screening in a Current Cohort of Children with Sickle Cell Anemia: Results from the DISPLACE Study

Julie Kanter 1, Shannon Phillips 2, Alyssa Schlenz 3, Martina Mueller 2,4, Mary Dooley 2, Logan Sirline 4, Robert Nickel 5, R Clark Brown 6, Lee Hilliard 7, Cathy Melvin 4, Robert Adams 8
PMCID: PMC8481351  NIHMSID: NIHMS1664975  PMID: 33625093

Abstract

Stroke prevention guidelines for sickle cell anemia (SCA) recommend transcranial Doppler (TCD) screening to identify children at stroke risk; however, TCD screening implementation remains poor. This report describes results from Part 1 of the 28-site DISPLACE (Dissemination and Implementation of Stroke Prevention Looking at the Care Environment) study, a baseline assessment of TCD implementation rates. This report describes TCD implementation by consortium site characteristics; characteristics of TCDs completed; and TCD results based on age. The cohort included 5247 children with SCA, of whom 5116 were eligible for TCD implementation assessment for at least one study year. The majority of children were African American or Black, non-Hispanic and received Medicaid. Mean age at first recorded TCD was 5.9 years and 10.5 years at study end. Observed TCD screening rates were unsatisfactory across geographic regions (mean 49.9%; range 30.9–74.7%) independent of size, institution type, or previous stroke prevention trial participation. The abnormal TCD rate was 2.9%, with a median age of 6.3 years for first abnormal TCD result. Findings highlight real-world TCD screening practices and results from the largest SCA cohort to date. Data informed the Part 3 implementation study for improving stroke screening and findings may inform clinical practice improvements.

Keywords: pediatrics, sickle cell anemia, transcranial Doppler screening

Introduction

Stroke is a devastating complication of sickle cell disease (SCD). Ischemic stroke is more common in the first decade of life while hemorrhagic stroke is more common in the 2nd-3rd decades. Although stroke can occur in all genotypes, ischemic stroke is more common in sickle cell anemia (SCA). In 1998, the Stroke Prevention Trial in Sickle Cell Anemia (STOP) demonstrated that a high risk group of children with SCA could be identified using transcranial Doppler ultrasound (TCD) and that chronic red cell transfusion (CRCT) could reduce risk of first ischemic stroke by over 90%.1 The STOP protocol was further validated in follow-up studies which demonstrated a persistent, significantly reduced rate of ischemic stroke.2, 3 Prior to STOP protocol implementation, the estimated chance of overt stroke by age 20 was 11%.4

The STOP protocol has been incorporated into several SCD-related treatment recommendations, including endorsement from the National Heart, Lung, and Blood Institute (NHLBI) following the STOP study, health supervision recommendations from the American Academy of Pediatrics in 2002, recommendations from the 2014 NHLBI Evidence-Based Management of Sickle Cell Disease: Expert Panel Report, and the recently published 2020 American Society of Hematology (ASH) cerebrovascular guidelines.57 The STOP protocol recommends children with SCA, ages 2–16, undergo an annual TCD to identify those individuals with abnormal (high) blood flow who are at high risk of stroke. The protocol then recommends initiating CRCT therapy for children with abnormal TCD. This is one of few endorsements designated as a “Strong Recommendation, High-Quality Evidence” in the NHLBI’s graded report.

Despite this recommendation, a retrospective study using Medicaid Claims Data and the recent Post-STOP study, as well as single-center projects, show poor implementation.812 Although a few institutions have conducted quality improvement projects for TCD screening at their institutions,9, 13, 14 a systematic, multi-site assessment of implementation of TCD screening in a nationally-representative sample of institutions caring for children with SCA has not been undertaken. A real-world assessment of TCD implementation overcomes limitations of prior studies that rely on successfully billed TCD screenings and do not capture unbillable screenings, such as those conducted in the clinic setting and those not conducted by a certified ultrasonographer. In addition, studies conducted only with Medicaid databases do not capture screenings for children with all types of third-party payers. In 2016, the DISPLACE (Dissemination and Implementation of Stroke Prevention Looking at the Care Environment) study was funded by NHLBI to evaluate implementation of TCD screening, assess barriers and facilitators to evidence-based stroke prevention for children with SCA, and test novel implementation strategies to overcome barriers across a large, multicenter consortium of 28 sites. DISPLACE was divided into three parts:

  • Part 1: Retrospective cohort study using rigorous chart review to assess the gap between current and recommended evidence-based stroke prevention practices (both risk identification and preventive intervention) as an assessment of current practice.

  • Part 2: Quantitative and qualitative multilevel assessment of barriers and facilitators to stroke prevention practices.

  • Part 3: A novel implementation multi-level trial to enhance implementation of stroke screening.

This report describes findings from DISPLACE Part 1, highlighting real-world implementation of stroke screening practices and TCD results from the largest SCA cohort to date. Specifically, this report describes a baseline (retrospective) assessment of TCD implementation rates among the consortium. The report also describes site characteristics in relation to TCD implementation and characteristics of completed TCDs. In addition, we examined age at first abnormal TCD to determine whether a specific age cohort of children could be identified as the focus of the Part 3 implementation trial.

Materials and Methods

Study Design Overview

This retrospective medical record review study was designed to identify current stroke screening practices including rates of TCD implementation in a nationally representative, diverse cohort of children with SCA. Parts 1 and 2 are registered in ClinicalTrials.gov under NCT03621826.

Consortium Selection

Potential site investigators from Pediatric Hematology/Oncology departments were recruited to represent tertiary academic medical centers and community-based SCD centers of varying sizes, locations, and experience in clinical research. Thirty-five sites were approached for the study. Five sites felt they did not have the resources to complete the study. Two sites who had previously undertaken quality improvement projects did not want to be included as they had recently made changes to their screening process. Twenty-eight sites agreed to participate.

Patient Identification

Each consortium institution (CI) identified patients in several steps. Initially, sites were instructed to use their local SCD databases and perform a broad electronic medical record search for patients with SCA ICD-9/10 codes, born between 1996–2014. Patient cohorts were then assessed for the following inclusion criteria: 1.) SCA diagnosis (HbSS, HbSB0, HbSOarab, HbSD) by HPLC newborn screening or hemoglobin electrophoresis; 2.) documented outpatient visit at CI between study years 2012–2016, assuring patients were followed by that institution; and 3.) at least two episodes of care (inpatient or outpatient) between 2012–2016. The final cohort included children with SCA, aged 2–16 years who should have undergone TCD screening, including patients who might have missed appointments or were “lost to follow-up.” Patients were considered to “belong” to an institution if they were seen for acute or outpatient care at least twice during a study year. In rare cases, patients seen for two or more acute visits could be excluded if pinpointed by the principal investigator (for example if a patient was identified as “visiting” from another state, they were not included in the analysis). For institutions with large patient populations (>300), patients were listed in alphabetical order and then entered into the database alphabetically. This systematic method of entry was undertaken to prevent bias, in case larger institutions did not complete the extensive data collection (as opposed to the most frequently seen or compliant patients being entered first). Only 4 sites were unable to enter all identified patients into the database and used the above protocol. One site was unable to enter more than 10% of their patient population and was excluded from TCD implementation analysis.

Data Collection

Institutional Review Board and Data Use Agreements

Institutional Review Board approval was obtained at each CI using a common protocol. Data use agreements between the sponsoring institution and each CI were also obtained. All data were de-identified at time of entry; thus, consent was not required from individual patients.

Electronic Database Description

DISPLACE Part 1 patients were enrolled into the custom-designed electronic database, WebDCU from 2017 – 2018. WebDCU was created by The Data Coordination Unit (DCU) at the Medical University of South Carolina. WebDCU is a comprehensive clinical trial management system established in 2005. The database provides regulatory document tracking, central adjudication, query generation, and electronic case report form (CRF) data capture. Secure data entry occurred at CI via an online, user-friendly data-entry interface. The DCU provided training and technical support to all users, including study team members and coordinators.

Overview of Data Collection Procedures

Once eligibility was confirmed by CI, each patient was registered in the database; all data were obtained through intensive chart review of the patient’s medical record by trained coordinators or site PIs. The initial patient CRF included demographics, SCD genotype, and history of abnormal TCD or MRI results prior to study years (i.e., before 2012). Demographic information included gender, birth date, ethnicity, insurance type (last recorded), and race. After the initial CRF, annual data were entered for each of the study years (2012–2016). The annual CRFs included: SCD-related complications, baseline laboratory values, vital signs and anthropometric values, TCD results, MRI results, echocardiogram results, medications, and previous or concurrent treatment with hydroxyurea (HU) or CRCT. For patients started on CRCT during the years of 2012–2016, the TCD/patient rates were included prior to start of CRCT but excluded once the patient started CRCT.

TCD Data Collection Methods

The TCD CRF captured: 1.) if TCD was completed for that year, 2.) TCD results (as classified by the CI), and 3.) follow up actions after TCD or 4.) reasons TCD was not completed. Per NHLBI guidelines, expectations were that each patient, ages 2–16 would have an annual TCD. For patients with more than one TCD in a study year, all TCDs were documented. For patients >2 years of age at study entry (2012), additional data were captured to include any TCD performed prior to first study year. TCD data were not required once patients reached 16 years of age. The TCD CRF was completed per patient even if the TCD had not been done. If a TCD was not completed for a study year, data were collected regarding causation of the missed exam (appointment not scheduled, appointment scheduled but not attended, etc.). However, due to the retrospective nature of these data, sites could not always locate these answers. Thus, barriers to TCD were obtained through additional qualitative and quantitative analyses during Part 2 of the study (please see Discussion).

The TCD CRF also included where the study was performed (radiology, SCD clinic, etc.), TCD type (dedicated Doppler, TCD imaging aka TCDi, or unknown), and results as classified by the CI (low, normal, conditional, abnormal, or inadequate). For those with results other than normal, the CRF captured when/if the TCD was repeated. If not repeated, additional data were captured regarding why it was not repeated (provider choice, patient lost to follow up, technical issues, appointment cancellation or no-show, refusal, or unknown). Data collected on patients with abnormal TCD included treatment recommendations (repeat TCD, initiation of HU, CRCT, hematopoietic stem cell transplant or unknown).

Definition of Optimal TCD Implementation and Results Classification

Guideline-based implementation was defined as annual TCD for all patients ages 2–16 with SCA who were not receiving CRCT. Each individual should have had at least one TCD/calendar year to be considered “on time”. This minimum TCD schedule could include more than one assessment/year if the result fell in the conditional or abnormal range (and TCD was repeated). TCD results were classified as normal, conditional, abnormal, or inadequate as per the CI’s report. TCD images were not centrally reviewed; assumptions were made that TCDs were performed and results were read according to standard of care. (Consortium practices and TCD results classification were collected and published separately.15) This consideration is important because 12 sites (42.9%) were using TCDi to classify results.

Variables

The primary outcome of this study was to calculate the current, real-world TCD screening rate at each institution (calculated as patient/year/site over all study years). Implementation rates were calculated as the ratio of number of eligible years at least one TCD was completed to number of eligible years TCDs should have been completed. A TCD eligible year was defined as any study year during which a patient was 2–16 years of age and not on CRCT. Implementation rates were calculated on a per site basis in order to identify the lowest performing sites for the subsequent implementation study (Part 3). Secondary outcomes included CI assessments, TCD results, and per patient results.

Site characteristics included institution size based on estimated number of total patients with SCD being treated prior to data capture and previous participation in the STOP I/II trials. For institutional size, the 27 CI included in the implementation analyses were classified as small (<200 total patients; n = 7), medium (201–400 total patients; n = 12), or large (>400 total patients; n = 8) based on sites’ estimated numbers of patients followed (not based on number of patients with SCA entered into the database). Analyses were conducted for sites overall and by comparing the top 3 and bottom 3 sites in terms of TCD implementation rates.

Information about current TCD results per patient and in aggregate included current rates of abnormal and conditional TCD; age of child at first abnormal TCD; TCD type (dedicated Doppler versus TCDi); and location of and timing of TCD (same day as clinic visit or separate day).

Statistical Methods

Data cleaning was performed to ensure reported numerical outcomes (e.g., vital signs, laboratory values) were in physiologic ranges and consistent with patient age, removing duplicate patients, and adjudicating abnormal TCD results with each site. Records with insufficient data relevant to study outcomes were removed (e.g., vital signs but no other data) and TCD CRFs were deleted if the test date was unknown. TCD data were analyzed for 27 CI; analyses not involving TCD implementation included all 28 sites.

Analyses were carried out in two distinct ways: 1.) demographic, screening, treatment, and clinical characteristics were determined by patient, and 2.) information on TCD results and characteristics was analyzed by TCD. For example, for individual patient outcomes (i.e., did a patient receive a TCD/year), analyses were done per patient. For TCD implementation outcomes (i.e., if a TCD was abnormal), analyses were performed per TCD, as patients could have multiple TCDs per year. Similarly, data for pre-study year periods (pre-2012) are highly relevant in the per patient analysis, but not for the implementation analysis. Institution size and number of patients in relation to TCD implementation rates were assessed using Kruskal-Wallis and Pearson correlation, respectively. Patients who died during study years were excluded from analyses (n=24). All statistical analyses were conducted using SAS Software Version 9.4 (Copyright © 2016 by SAS Institute Inc., Cary, NC, USA).

Results

Demographics

The final consortium comprised 28 institutions across the United States with various sizes and locations. There were 5247 patients entered into WebDCU making this the largest cohort of children with SCA ever investigated. Patient demographics for the 5116 patients eligible for at least 1 TCD during study years are reported in Table 1. The majority of children were African American or Black, non-Hispanic and received Medicaid insurance. Not all questions were answered for each patient.

Table 1:

Subject Demographics

Characteristic N n %
BASELINE CHARACTERISTICS 5116
Agea mean (sd), median, IQR
 First recorded TCD in study years 5.9 (4.1) 5.0 (2–9)
 End of Study (31Dec2016) 10.5 (5.3) 10.0 (6–15)
Sex a 5116
 Male 2575 50.3
 Female 2541 49.7
Ethnicity a 5116
 Hispanic or Latino 124 2.4
 Not Hispanic/Latino 4661 91.1
 Unknown 331 6.5
Race*,a 5116
 Native American 13 0.3
 Asian 8 0.2
 African-American or Black 4850 94.8
 Pacific Islander 8 0.2
 White 64 1.3
 Unknown 188 3.7
Insurance b 3972
 Medicaid 2505 63.1
 CHIP 43 1.1
 Tricare 62 1.6
 Private 782 19.7
 Local 88 2.2
 None 52 1.3
 Unknown 545 13.7
Genotype a,c 5106
 Hb SS or sickle cell anemia 4782 93.7
 Hb s beta thalassemia 273 5.4
 Hb S + Hb FHd 37 0.7
 Hb SE 4 0.1
 Hb SD 5 0.1
 Hb SO 5 0.1
TREATMENT
Hydroxyurea a 5116 3009 58.8
Open in a new tab
*

Not mutually exclusive

a

Rates per subject (Subjects are only represented once but Hydroxyurea use could be at any time from 2012–2016)

b

Baseline rates per subject (Subjects are only represented once)

c

Missing 10

d

Included at the discretion of the local CI (not genetically defined)

Primary Outcomes: TCD implementation

The primary goal of DISPLACE Part 1 was to assess current TCD screening implementation at CIs. This intensive evaluation was necessary as only the lowest performing 16 sites would participate in the subsequent implementation trial (Part 3). The final dataset included 5247 children ages 2–16 years. Of these, 5116 were eligible for TCD implementation assessment (for at least one study year). Patients were deemed ineligible if they had started CRCT or received stem cell transplant prior to 2012 (n=22). Patients from the site with <10% of total patients entered were removed from TCD implementation assessment due to potential bias (n=33). Twenty-four patients who died during the study window were excluded.

TCD implementation was measured for study years 2012–2016. TCD screening rates were collected per patient/year/institution and the mean and median were calculated for better representation of overall screening rates. Overall TCD screening rates varied widely among institutions ranging from 30.9–74.7% (mean 49.9%, median 48.6%; Table 2). No trends in TCD rates were observed across the study years. During this time, 3655 patients registered in the database had at least one TCD during the study period (71.4%) and 1461 (28.6%) did not have a single TCD. Among patients who were eligible for at least four study years and should have had at least four TCDs, 601 patients (18.0%) did not have a single TCD (Table 3).

Table 2:

TCD Implementation Rates Across the 27 DISPLACE Consortium Institutions by Institution Size

Year
Overall 2012 2013 2014 2015 2016
Site N n (%) N n (%) N n (%) N n (%) N n (%) N n (%)
Small
1 173 104 (60.1%) 29 15 (51.7%) 32 15 (46.9%) 36 21 (58.3%) 38 28 (73.7%) 38 25 (65.8%)
2 197 126 (64.0%) 40 19 (47.5%) 36 26 (72.2%) 39 23 (59.0%) 43 30 (69.8%) 39 28 (71.8%)
3 304 94 (30.9%) 60 12 (20.0%) 59 19 (32.2%) 58 25 (43.1%) 62 22 (35.5%) 65 16 (24.6%)
4 478 272 (56.9%) 93 47 (50.5%) 98 57 (58.2%) 98 48 (49.0%) 95 66 (69.5%) 94 54 (57.4%)
5 531 177 (33.3%) 90 35 (38.9%) 97 32 (33.0%) 104 39 (37.5%) 112 26 (23.2%) 128 45 (35.2%)
6 584 268 (45.9%) 108 27 (25.0%) 119 49 (41.2%) 117 58 (49.6%) 115 65 (56.5%) 125 69 (55.2%)
7 919 371 (40.4%) 186 50 (26.9%) 183 73 (39.9%) 184 81 (44.0%) 179 78 (43.6%) 187 89 (47.6%)
Medium
8 244 132 (54.1%) 48 23 (47.9%) 42 26 (61.9%) 45 23 (51.1%) 51 31 (60.8%) 58 29 (50.0%)
9 312 213 (68.3%) 60 42 (70.0%) 59 42 (71.2%) 61 40 (65.6%) 67 39 (58.2%) 65 50 (76.9%)
10 324 175 (54.0%) 63 32 (50.8%) 62 33 (53.2%) 63 37 (58.7%) 69 36 (52.2%) 67 37 (55.2%)
11 475 197 (41.5%) 77 24 (31.2%) 93 35 (37.6%) 98 41 (41.8%) 101 50 (49.5%) 106 47 (44.3%)
12 506 267 (52.8%) 98 54 (55.1%) 95 50 (52.6%) 103 47 (45.6%) 107 57 (53.3%) 103 59 (57.3%)
13 592 260 (43.9%) 123 48 (39.0%) 123 54 (43.9%) 123 51 (41.5%) 115 52 (45.2%) 108 55 (50.9%)
14 650 360 (55.4%) 129 74 (57.4%) 132 72 (54.5%) 131 64 (48.9%) 124 74 (59.7%) 134 76 (56.7%)
15 658 284 (43.2%) 123 52 (42.3%) 130 63 (48.5%) 131 60 (45.8%) 136 60 (44.1%) 138 49 (35.5%)
16 707 442 (62.5%) 141 82 (58.2%) 149 79 (53.0%) 146 111 (76.0%) 136 93 (68.4%) 135 77 (57.0%)
17 752 428 (56.9%) 150 80 (53.3%) 148 79 (53.4%) 151 85 (56.3%) 152 94 (61.8%) 151 90 (59.6%)
18 769 267 (34.7%) 155 41 (26.5%) 151 55 (36.4%) 154 60 (39.0%) 155 50 (32.3%) 154 61 (39.6%)
19 785 353 (45.0%) 164 79 (48.2%) 160 70 (43.8%) 159 81 (50.9%) 149 70 (47.0%) 153 53 (34.6%)
Large
20 615 199 (32.4%) 124 26 (21.0%) 137 26 (19.0%) 122 44 (36.1%) 120 54 (45.0%) 112 49 (43.8%)
21 644 360 (55.9%) 93 46 (49.5%) 117 64 (54.7%) 128 68 (53.1%) 151 77 (51.0%) 155 105 (67.7%)
22 738 551 (74.7%) 141 98 (69.5%) 147 105 (71.4%) 151 113 (74.8%) 149 111 (74.5%) 150 124 (82.7%)
23 1040 651 (62.6%) 217 101 (46.5%) 211 119 (56.4%) 207 138 (66.7%) 210 143 (68.1%) 195 150 (76.9%)
24 1128 529 (46.9%) 237 106 (44.7%) 238 100 (42.0%) 221 99 (44.8%) 221 117 (52.9%) 211 107 (50.7%)
25 1369 622 (45.4%) 270 93 (34.4%) 275 101 (36.7%) 285 102 (35.8%) 270 180 (66.7%) 269 146 (54.3%)
26 2016 768 (38.1%) 391 136 (34.8%) 401 140 (34.9%) 405 155 (38.3%) 408 175 (42.9%) 411 162 (39.4%)
27 2205 1072 (48.6%) 426 191 (44.8%) 439 210 (47.8%) 449 228 (50.8%) 453 206 (45.5%) 438 237 (54.1%)
Open in a new tab

N=total number of TCDs needed per eligible patient per year eligible

Table 3:

TCD Implementation Based on Years of Eligibility with Rates of Abnormal and Conditional Results

2012–2016
Eligible 1+ yearb (n=5116) Eligible 4+ yearsc (n=3354)
Unique Patients who DID NOT HAVE A TCD 1461 (28.6%) 601 (17.9%)
Unique patients who only had ONE TCD 917 (17.9%) 456 (13.6%)
Unique Patients who had a TCD total 3655 (71.4%) 2753 (82.1%)
Unique Patients with abnormal TCDa 102 (2.8%) 80 (2.9%)
Unique Patients with conditional TCDa 495 (13.5%) 406 (14.8%)
Open in a new tab
a

Denominator = Unique patients who had a TCD total

b

Of the 5,116 patients eligible to receive a TCD for at least 1 year during the study years

c

Of the 3,354 patients eligible to receive a TCD for at least 4 (of the 5) years during the study years

Secondary Outcomes

Site Characteristics

Screening variation both within site (from year to year) and between sites was high. Institution size and number of patients were not statistically significantly related to TCD implementation rates (Chi-square=0.22, p=0.895 obtained from Kruskal-Wallis Test for non-parametric distributions; r=−.20, p=0.313 from Pearson correlation, respectively). No difference in implementation of TCD by participation in STOP I and/or II trials was noted (all sites: 48.4%; STOP I/II sites: 46.4%; non-STOP sites: 51.2%). A comparison of the 3 sites with the highest implementation rates and the 3 sites with the lowest implementation rates by size and participation in STOP trials indicated no trends by size. Specifically, the lowest three sites included two small sites and one large site as well as one site that participated in STOP I and/or II. The highest three sites included one small, one medium, and one large site and no sites that participated in STOP I and/or II.

TCD Characteristics

Assessment of TCD results included patients studied from 2012–2016 who had at least one TCD and were not on CRCT. There were 104 (2.8%) patients with abnormal TCD and 495 (13.5%) patients with a conditional TCD during this time period (Table 3). Mean age at time of first abnormal TCD during study years was 6.3 years (median 6, interquartile range of 4–8 years). Of note, the oldest patient to develop a new, abnormal TCD was 16 years old. More TCDs were conducted using dedicated Doppler (66.2%) compared to TCDi (32.8%). There was no difference in abnormal results seen with TCD vs. TCDi. Nearly all TCDs were conducted at the study hospital (96.9%) and the majority were conducted at the same time as a clinic appointment (67.3%).

Discussion

The STOP study dramatically changed stroke prevention practices for children with SCA, offering a preventive strategy to a devastating complication.2 Results from DISPLACE Part 1 highlight real-world stroke screening practices and TCD results in the modern era in the largest SCA cohort to date. This real-world assessment of TCD implementation overcomes limitations in prior studies conducted with administrative datasets and illustrates the need for a clinical longitudinal registry for more accurate monitoring of clinical care and patient outcomes. Unfortunately, findings demonstrate wide variability in TCD screening implementation not due to geographic location, institution size, number of patients, or prior participation in the STOP trials.

Barriers and facilitators to TCD implementation occur at multiple levels (patient level, provider level, and system level). We previously reported data from qualitative interviews performed during Part 2 of DISPLACE that reveal predominant barriers and facilitators that likely explain the variability observed in TCD rates. These results showed that predominant barriers included patient/caregiver logistical difficulties and competing life demands and gaps in scheduling, communication, and coordination. Predominant facilitators included coordination, scheduling, and reminders (especially when there was a single identified coordinator) and education and information (patient/caregiver knowledge of TCD).16 These results suggest that a combination of patient-, provider-, and systems-level issues are involved in TCD implementation, consistent with previous, single center studies,1012, 1724 and suggest that targeted multi-level interventions are likely needed to improve TCD screening rates.

Overall, the abnormal TCD rate is considerably lower in this large, real-world sample of children with SCA compared to the STOP study.1 STOP was a prospective study to assess CRCT for patients with abnormal TCD. Thus, the findings in this retrospective, real-world study cannot be directly compared to those in STOP. However, the incidence of abnormal TCD in this cohort is lower than seen during the STOP study. This difference is likely multifactorial and may be due to improvements in overall SCD management, including use of HU.25 During the STOP study, the majority of HU use was in adults.26 Further, because the STOP screening protocol has been implemented in care for >10 years, many who had abnormal TCD are no longer in the screening pool as they are now on CRCT. Despite improvements in care, many children continue to have abnormal TCD and remain at high risk of ischemic stroke.

The average age at abnormal TCD was only slightly higher in DISPLACE compared to the STOP study although direct statistical comparisons could not be made.1 The mean age at the time of first abnormal TCD during study years was 6.3 years (range 2–16). The majority of abnormal TCDs (75%) were before or at 7 years of age. However, 25% of abnormal TCD occurred in older patients (>9 years) in this cohort. Additional characterization of those with abnormal TCD and findings relative to use of HU will be presented in a separate paper. It is important to characterize which older children (>9 years) remain at high risk of developing abnormal TCD and whether a clinically defined group could stop screening before 16 years of age. We used these data to guide the enrollment age group for the Part 3 implementation trial. To reduce the number of patients enrolled at each site, we chose to focus data collection on ages 2–8, as these children would be the most likely to have an abnormal TCD during the trial.

In the STOP study, only dedicated Doppler was used. However, in DISPLACE, almost half of sites used TCDi.15 Previous studies have compared results using dedicated Doppler versus TCDi in SCA and recent guidelines from ASH have formally recommended the use of lower velocities for identifying abnormal results when using TCDi (compared to dedicated Doppler).2731 More specifically, these guidelines recommend using the STOP criterion of ≥200 time average mean of the maximum (TAMM) velocity for dedicated Doppler versus ≥185 TAMM time for TCDi. Our previous paper on practice patterns for TCD screening in the consortium suggested variation in how TCDi studies were categorized as there were no clear guidelines during the time of data collection15; however, there was no clinically significant difference in the number of abnormal TCD results between methods. Nonetheless, it is possible that the rate of abnormal TCDs was affected by variation in practices.

Limitations

DISPLACE is a real-world evaluation of current practice in 28 centers in the US. There was potential bias in the site selection. First, most CI were academic centers; however, the majority of children with SCD receive care in the US at academic institutions.32 Thus, screening rates were likely representative of typical care. Second, 7 of the original 35 sites approached chose not to participate in the study. Two of these sites had already conducted single center quality improvement projects and had new screening processes in place. Five others did not have sufficient research staff. While the two sites who had previously undertaken projects to improve screening rates now have better rates, these were not likely representative screening rates. The sites that did not participate might have had lower screening rates as their ability to participate and track these outcomes was limited. TCDs were conducted according to institutional practice and not per a single study protocol, and only abnormal TCD were adjudicated by the PI and confirmed to meet the “STOP protocol” definition. Thus, data reported are based on institutional judgement, which may be regarded as a limitation but is consistent with real-world practice. All data were collected by intensive chart review, but testing was not performed prospectively for this study. Thus, it is possible that TCD classifications in DISPLACE would not be consistent with STOP protocol definitions.

Conclusion

TCD screening was one of the most strongly recommended practices by the NHLBI SCD guidelines.6 Despite being the most common inherited blood disorder in the US, SCD is still affected by multiple health disparities, including a lack of funding, well-defined quality metrics and assessments, and novel drug development that exists in other life-limiting conditions, such as cystic fibrosis.33 Further, there are limited treatment guidelines or oversight for individuals with SCD compared to other conditions.34, 35

Current TCD implementation is lacking. Findings in DISPLACE likely reflect other areas of profound gaps between guidelines and practice. DISPLACE seeks to optimize implementation of stroke risk screening in SCD as one means for improving care. New SCD guidelines have recently been published by ASH,7, 36, 37 and new therapies have been approved. Lessons learned from the DISPLACE implementation study are expected to provide new strategies to improve quality of care and reduce health outcome inequities for this at-risk population.

Acknowledgements

Collaborators: Site Principal Investigators on the study are Rachelle Nuss, MD, Children’s Hospital Colorado; Carla Roberts, MD, Prisma Health Richland; Lewis Hsu, MD, PhD University of Illinois at Chicago; Melissa McNaull, MD, University of Mississippi; Felicia Wilson, MD, University of South Alabama; Suzanne Saccente, MD, Arkansas Children’s Research Institute; Vandy Black, MD, University of Florida; Monica Hulbert, MD, St. Louis Children’s Hospital; Beng Fuh, MD, Eastern Carolina University; Leili Dolatshahi, MD, SSM Cardinal Glennon Children’s Hospital; Zora Rogers, MD, University of Texas Southwestern; Melissa Frei-Jones, MD, University of Texas Kids San Antonio; Robert Liem, MD, Lurie Children’s Hospital of Chicago; Sohail Rana, MD, Howard University; Margaret Lee, MD, Columbia University; Lynne Neumayr, MD, UCSF Benioff Children’s Hospital Oakland; Daniel McMahon, MD, Levine Children’s Hospital; Richard Drachtman, MD, Rutgers University; Ofelia Alvarez, MD, University of Miami; Emily Meier, MD, Indiana Hemophilia and Thrombosis Center; Robin Miller, MD, Nemours Center for Cancer & Blood Disorders; Charles Quinn, MD, Cincinnati Children’s Hospital; Emmanuel Volanakis, MD, Vanderbilt University Children’s Hospital; Hector Rodriguez-Cortes, MD, Broward Health Medical Center

Additional contributions: We acknowledge Sarah Moderhack, BS, at the University of Alabama Birmingham and Joannie Hayes, BS, at the Medical University of South Carolina for their substantial assistance with the coordination and management of the study. Financial compensation was provided to Ms. Moderhack and Ms. Hayes via employment contract for grant effort.

Funding for this Work: This study was supported by the National Institutes of Health, National Heart Lung and Blood Institute (NHLBI) award R01HL133896. Dr. Phillips was additionally supported by a K23 award from the National Institutes of Nursing Research (NINR) award K23NR017899.

Conflicts of Interest and Sources of Funding: Dr. Kanter reports receiving grants (R01HL133896, U01HL133990) from the National Institutes of Health (NIH), the Health Resources and Services Administration and the Centers for Disease Control. She has served as a Principal Investigator on studies funded by Novartis Pharmaceuticals Corporation, Ironwood Therapeutics, Inc., Imara, Inc, Baxalta US, Inc., Bluebird Bio, Inc. She has received honoraria from Novartis Pharmaceuticals Corporation, MEDSCAPE, MD Magazine, Terumo and Bluebird Bio, Inc and travel support for Global Blood Therapeutics. Dr. Phillips reports receiving a grant (K23NR017899) from NIH. Dr. Melvin reports receiving grants (R01HL133896, U01HL133990) from the NIH. Dr. Adams reports receiving a grant (R01HL133896) from the NIH and the American Heart Association and consulting honoraria from Global Blood Therapeutics. No other conflicts were declared.

References

  • 1.Adams RJ, McKie VC, Hsu L, et al. Prevention of a first stroke by transfusions in children with sickle cell anemia and abnormal results on transcranial Doppler ultrasonography. N Engl J Med. 1998;339(1):5–11. [DOI] [PubMed] [Google Scholar]
  • 2.Adams RJ. Big strokes in small persons. Arch Neurol. 2007;64(11):1567–1574. [DOI] [PubMed] [Google Scholar]
  • 3.Lee MT, Piomelli S, Granger S, et al. Stroke prevention trial in sickle cell anemia (STOP): Extended follow-up and final results. Blood. 2006;108(3):847–852. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 4.Ohene-Frempong K, Weiner SJ, Sleeper LA, et al. Cerebrovascular accidents in sickle cell disease: Rates and risk factors. Blood. 1998;91(1):288 – 294. [PubMed] [Google Scholar]
  • 5.Section on Hematology/Oncology Committee on Genetics, American Academy of Pediatrics. Health supervision for children with sickle cell disease. Pediatrics. 2002;109(3):526–535. [DOI] [PubMed] [Google Scholar]
  • 6.Yawn BP, Buchanan GR, Afenyi-Annan AN, et al. Management of sickle cell disease: Summary of the 2014 evidence-based report by expert panel members. JAMA. 2014;312(10):1033–1048. [DOI] [PubMed] [Google Scholar]
  • 7.DeBaun MR, Jordan LC, King AA, et al. American Society of Hematology 2020 guidelines for sickle cell disease: Prevention, diagnosis, and treatment of cerebrovascular disease in children and adults. Blood Adv. 2020;4(8):1554–1588. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 8.Kwiatkowski JL, Voeks JH, Kanter J, et al. Ischemic stroke in children and young adults with sickle cell disease in the post-STOP era. Am J Hematol. 2019;94(12):1335–1343. [DOI] [PubMed] [Google Scholar]
  • 9.Crosby LE, Joffe NE, Davis B, et al. Implementation of a process for initial transcranial Doppler ultrasonography in children with sickle cell anemia. Am J Prev Med. 2016;51(1 Suppl 1):S10–16. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 10.Reeves SL, Fullerton HJ, Cohn LM, et al. Missed opportunities for transcranial Doppler screening among children with sickle cell disease. Clin Pediatr (Phila). 2016;55(12):1093–1099. [DOI] [PubMed] [Google Scholar]
  • 11.Weisman JK, Diamond CE, Kappa S, et al. Transcranial Doppler screening adherence among children with sickle cell anemia seen in the emergency department. J Pediatr. 2020;217:172–176. [DOI] [PubMed] [Google Scholar]
  • 12.Reeves SL, Madden B, Freed GL, et al. Transcranial Doppler screening among children and adolescents with sickle cell anemia. JAMA Pediatr. 2016;170(6):550–556. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13.McCarville MB, Goodin GS, Fortner G, et al. Evaluation of a comprehensive transcranial Doppler screening program for children with sickle cell anemia. Pediatr Blood Cancer. 2008;50(4):818–821. [DOI] [PubMed] [Google Scholar]
  • 14.Muntz DS, Bundy DG, Strouse JJ. Personalized reminders increase screening for stroke risk in children with sickle cell anemia. South Med J. 2016;109(9):506–510. [DOI] [PubMed] [Google Scholar]
  • 15.Schlenz AM, Phillips S, Mueller M, et al. Practice patterns for stroke prevention using transcranial Doppler in sickle cell anemia: DISPLACE consortium. Pediatr Blood Cancer. 2020:e28172. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 16.Phillips S, Schlenz AM, Mueller M, et al. Barriers and facilitators to transcranial Doppler screening for stroke prevention in children with sickle cell anemia: Results from the DISPLACE consortium. Blood. 2019;134(Supplement_1):3393–3393. [Google Scholar]
  • 17.Armstrong-Wells J, Grimes B, Sidney S, et al. Utilization of TCD screening for primary stroke prevention in children with sickle cell disease. Neurology. 2009;72(15):1316–1321. [DOI] [PubMed] [Google Scholar]
  • 18.Bollinger LM, Nire KG, Rhodes MM, et al. Caregivers’ perspectives on barriers to transcranial Doppler screening in children with sickle-cell disease. Pediatr Blood Cancer. 2011;56(1):99–102. [DOI] [PubMed] [Google Scholar]
  • 19.Cabana MD, Kanter J, Marsh AM, et al. Barriers to pediatric sickle cell disease guideline recommendations. Glob Pediatr Health. 2019;6:2333794X19847026. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 20.Eckrich MJ, Wang WC, Yang E, et al. Adherence to transcranial Doppler screening guidelines among children with sickle cell disease. Pediatr Blood Cancer. 2013;60(2):270–274. [DOI] [PubMed] [Google Scholar]
  • 21.Hamm J, Hilliard L, Howard T, et al. Maintaining high level of care at satellite sickle cell clinics. J Health Care Poor Underserved. 2016;27(1):280–292. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 22.Meier ER, Janson IA, Hampton K, et al. Adherence to quality of care indicators and location of sickle cell care within indiana. J Community Health. 2020;45(1):81–87. [DOI] [PubMed] [Google Scholar]
  • 23.Raphael JL, Shetty PB, Liu H, et al. A critical assessment of transcranial Doppler screening rates in a large pediatric sickle cell center: Opportunities to improve healthcare quality. Pediatr Blood Cancer. 2008;51(5):647–651. [DOI] [PubMed] [Google Scholar]
  • 24.Reeves SL, Fullerton HJ, Dombkowski KJ, et al. Physician attitude, awareness, and knowledge regarding guidelines for transcranial Doppler screening in sickle cell disease. Clin Pediatr (Phila). 2015;54(4):336–345. [DOI] [PubMed] [Google Scholar]
  • 25.Ghafuri DL, Chaturvedi S, Rodeghier M, et al. Secondary benefit of maintaining normal transcranial Doppler velocities when using hydroxyurea for prevention of severe sickle cell anemia. Pediatr Blood Cancer. 2017;64(7). [DOI] [PubMed] [Google Scholar]
  • 26.Heeney MM, Ware RE. Hydroxyurea for children with sickle cell disease. Hematol Oncol Clin North Am. 2010;24(1):199–214. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 27.McCarville MB, Li C, Xiong X, et al. Comparison of transcranial Doppler sonography with and without imaging in the evaluation of chldren with sickle cell anemia. Amer J Radiol. 2004;183:1117 – 1122. [DOI] [PubMed] [Google Scholar]
  • 28.Jones AM, Seibert JJ, Nichols FT, et al. Comparison of transcranial color Doppler imaging (TCDi) and transcranial Doppler (TCD) in children with sickle-cell anemia. Pediatr Radiol. 2001;31:461 – 469. [DOI] [PubMed] [Google Scholar]
  • 29.Krejza J, Rudzinski W, Pawlak MA, et al. Angle-corrected imaging transcranial Doppler sonography versus imaging and nonimaging transcranial Doppler sonography in children with sickle cell disease. Amer J Neuroradiol. 2007;28:1613 – 1618. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 30.Bulas DI, Jones A, Seibert JJ, et al. Transcranial Doppler (TCD) screening for stroke prevention in sickle cell anemia: Pitfalls in technique variation. Pediatr Radiol. 2000;30(11):733–738. [DOI] [PubMed] [Google Scholar]
  • 31.Neish AS, Blews DE, Simms CA, et al. Screening for stroke in sickle cell anemia: Comparison of transcranial Doppler imaging and nonimaging us techniques. Radiology. 2002;222(3):709–714. [DOI] [PubMed] [Google Scholar]
  • 32.Brousseau DC, Muslu CS, Visotcky A, et al. Teaching versus nonteaching hospitals: Where children with sickle cell disease receive their emergency department care. J Pediatr Hematol Oncol. 2020;42(6):412–413. [DOI] [PubMed] [Google Scholar]
  • 33.Farooq F, Mogayzel PJ, Lanzkron S, et al. Comparison of US federal and foundation funding of research for sickle cell disease and cystic fibrosis and factors associated with research productivity. JAMA Netw Open. 2020;3(3):e201737. [DOI] [PubMed] [Google Scholar]
  • 34.Lee L, Smith-Whitley K, Banks S, et al. Reducing health care disparities in sickle cell disease: A review. Public Health Rep. 2019;134(6):599–607. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 35.Smith LA, Oyeku SO, Homer C, et al. Sickle cell disease: A question of equity and quality. Pediatrics. 2006;117(5):1763–1770. [DOI] [PubMed] [Google Scholar]
  • 36.Murad MH, Liem RI, Lang ES, et al. 2019 sickle cell disease guidelines by the American Society of Hematology: Methodology, challenges, and innovations. Blood Adv. 2019;3(23):3945–3950. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 37.Liem RI, Lanzkron S, T DC, et al. American Society of Hematology 2019 guidelines for sickle cell disease: Cardiopulmonary and kidney disease. Blood Adv. 2019;3(23):3867–3897. [DOI] [PMC free article] [PubMed] [Google Scholar]

RESOURCES