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Disparities in resource utilisation by families of children with cardiac conditions

Published online by Cambridge University Press:  07 July 2023

Francisca L. Chou Open the ORCID record for Francisca L. Chou [Opens in a new window] ,
Denis J. Donovan ,
Rachel J. Weller ,
Michael A. Fremed Open the ORCID record for Michael A. Fremed [Opens in a new window] ,
Julie S. Glickstein  and
Usha S. Krishnan
Francisca L. Chou
Affiliation:
Columbia University Vagelos College of Physicians and Surgeons, New York, NY, USA
Denis J. Donovan
Affiliation:
Department of Pediatrics, Division of Pediatric Cardiology, Columbia University Irving Medical Center, New York, NY, USA
Rachel J. Weller
Affiliation:
Department of Pediatrics, Division of Pediatric Cardiology, Columbia University Irving Medical Center, New York, NY, USA
Michael A. Fremed
Affiliation:
Department of Pediatrics, Division of Pediatric Cardiology, Columbia University Irving Medical Center, New York, NY, USA
Julie S. Glickstein
Affiliation:
Columbia University Vagelos College of Physicians and Surgeons, New York, NY, USA Department of Pediatrics, Division of Pediatric Cardiology, Columbia University Irving Medical Center, New York, NY, USA
Usha S. Krishnan*
Affiliation:
Columbia University Vagelos College of Physicians and Surgeons, New York, NY, USA Department of Pediatrics, Division of Pediatric Cardiology, Columbia University Irving Medical Center, New York, NY, USA
*
Corresponding author: U. S. Krishnan; Email: [email protected]
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Abstract

Objectives:

There are limited data documenting sources of medical information that families use to learn about paediatric cardiac conditions. Our study aims to characterise these resources and to identify any disparities in resource utilisation. We hypothesise there are significant variations in the resources utilised by families from different educational and socio-economic backgrounds.

Methods:

A survey evaluating what resources families use (websites, healthcare professionals, social media, etc.) to better understand paediatric cardiac conditions was administered to caretakers and paediatric patients at Morgan Stanley Children’s Hospital. Patients with a prior diagnosis of CHD, cardiac arrhythmia, and/or heart failure were included. Caretakers’ levels of education (fewer than 16 years vs. 16 years or more) and patients’ medical insurance types (public vs. private) were compared with regard to the utilisation of resources.

Results:

Surveys completed by 137 (91%) caretakers and 27 (90%) patients were analysed. Websites were utilised by 72% of caretakers and 56% of patients. Both private insurance and higher education were associated with greater reported utilisation of websites, healthcare professionals, and personal networks (by insurance p = 0.009, p = 0.001, p = 0.006; by education p = 0.022, p < 0.001, p = 0.018). They were also more likely to report use of electronic devices (such as a computer) compared to those with public medical insurance and fewer than 16 years of education (p < 0.001, p < 0.001, respectively).

Conclusion:

Both levels of education and insurance status are associated with the utilisation of informative resources and digital devices by families seeking to learn more about cardiac conditions in children.

Keywords

Social determinants of healthdigital dividehealth equitysocial justiceCHD
Type
Original Article
Information
Cardiology in the Young , Volume 34 , Issue 2 , February 2024 , pp. 325 - 333
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

With a rising global prevalence and median incidence of approximately 8 per 1,000 live births, CHD continues to impact millions of children and their families worldwide. Reference Liu, Chen and Zühlke1,Reference Bernier, Stefanescu, Samoukovic and Tchervenkov2 Counseling families of patients diagnosed with CHD involves in-depth explanations of potentially complex anatomical structures and often requires cardiologists to provide additional digital and non-digital resources such as diagrams, medical websites, and printed information. Reference Kovacevic, Simmelbauer and Starystach3,Reference Kovacevic, Bär and Starystach4 A comprehensive understanding of the diagnosis is paramount to a parent’s decisions related to the management of their child’s CHD. Reference Hilton-Kamm, Sklansky and Chang5 Prior studies have reported that internet-based CHD-specific health information accessed online influences parents’ decisions about their children’s healthcare. Reference Kasparian, Lieu, Winlaw, Cole, Kirk and Sholler6 Despite widespread Internet use, online health literacy remains low with many parents reporting a lack of familiarity with the types of resources available online, inability to assess the quality of those resources, and distrust in the information they find. Reference Kasparian, Lieu, Winlaw, Cole, Kirk and Sholler6,Reference Ikemba, Kozinetz and Feltes7 Furthermore, many families prefer to receive more CHD education from their child’s cardiologist than what is generally provided. Reference Arya, Glickstein, Levasseur and Williams8 As information available through digital platforms continues to expand, the impact of health literacy – particularly as it pertains to information seeking – on health outcomes is a topic of growing importance. Reference Knapp, Madden, Wang, Sloyer and Shenkman9,Reference Chesser, Burke, Reyes and Rohrberg10

Prior studies have reported that the Internet, paediatric cardiologists, and general paediatricians are some of the most common sources of health information for parents of children diagnosed with CHD. Reference Kasparian, Lieu, Winlaw, Cole, Kirk and Sholler6,Reference Massin, Montesanti and Gerard11 However, little is known about the specific types of digital and non-digital resources families utilise to bolster their understanding of their child’s CHD. Furthermore, whether any differences exist in the types of health information families use has been largely underexplored.

In this study, we address this gap by characterising the types of informative resources utilised by families of paediatric patients following up for care at the Congenital Heart Center at Columbia University Medical Center/Morgan Stanley Children’s Hospital of New York. We assessed if any significant differences exist in the use of resources between families of varying socio-economic strata defined by health insurance type and the education levels of caregivers. The findings from this work add to the existing body of knowledge dedicated to understanding the impact of social determinants, particularly health literacy, on paediatric health disparities and inequities.

Materials and methods

A cross-sectional survey-based study was conducted from October, 2021 to December, 2021 to assess both digital and non-digital sources of medical information used by families to better understand cardiac conditions in children. Surveys were reviewed by co-authors prior to the start of the study to optimise the readability and appropriateness of the survey for patients and their caretakers at the study centre. Caretaker and patient surveys were also assessed using the readability statistics tool within Microsoft Word. The Flesch-Kincaid Grade Level of the caretaker survey and paediatric survey was 5.5 and 5.4, respectively. Eligible study participants were identified on the day of the paediatric patient’s follow-up visit at the congenital heart center. Caretakers of patients who were previously diagnosed with CHD, cardiac arrhythmia, and/or heart failure were included in the study. Caretakers who do not speak English or Spanish and caretakers of patients with heart transplants were excluded. Patients 12 years of age and older with capacity to provide assent and complete the study survey were approached at the same time as their caretakers (Supplementary S9S10). The primary exposure for the study was caretaker socio-economic status as estimated by the patient’s medical insurance type. The secondary exposure for the study was caretakers’ levels of education. Insurance coverage was stratified into two groups: public insurance plans, specifically CHIP or Medicaid plans, and private insurance plans, such as employer-sponsored plans or those from the marketplace. Caretaker level of education was stratified into two groups: those with fewer than 16 years of education (less than high school, high school graduate, some college, or 2-year degree) and those with 16 or more years of education.

Surveys were administered via a study iPad containing the Qualtrics survey link or via participants’ own devices since a QR code for the survey was also provided. A member of the research team was available to answer participants’ questions while taking the survey. Study participants had the option of completing the study survey in either English or Spanish (Supplementary S5S8). Participants also had the option to have the study survey read aloud if they otherwise could not use the research iPad or were limited by low visual acuity. The survey included demographic questions on age, education level, gross annual household income, language(s) spoken at home, and the patient’s health insurance type. Clinical questions included the cardiac diagnosis, time since diagnosis, number of previous hospitalisations, and number of previous surgeries. The study survey also assessed access to the Internet and digital devices such as laptops and smartphones. Participants were then asked to indicate which types of digital and non-digital sources of medical information they may have used to learn about paediatric cardiac conditions. The first of these questions asked participants to select which general resources – websites, healthcare professionals, social media/online groups, personal contacts, printed sources, and/or video platforms – they may have used at least once to learn about the heart. The study survey then assessed more specifically the types of websites (i.e., commercial sites, government sites, etc.), healthcare professionals (i.e., general paediatricians, paediatric cardiologists, nurse practitioners etc.), social media/online groups (i.e. Facebook, Reddit, etc.), personal contacts (i.e. family, friends, etc.), printed sources (i.e. textbooks, pamphlets, etc.), and video platforms (i.e. YouTube, TikTok, etc.) participants may have used to learn more about their diagnosis and which they utilised the most. Final survey questions assessed participant satisfaction with the number of resources received, how often participants had access to information in their native language and participants’ perceptions on how often the information they obtained agreed with doctors’ recommendations. Answer choices were structured as five-point Likert scales with one representing “always” or “extremely satisfied” and five representing “never” or “extremely dissatisfied.”

Statistics

Statistical analyses on completed study surveys were conducted using Stata Statistical Software: Release 17 (College Station, TX: Stata Press. StataCorp. 2019). Pearson’’s chi-square test and Fisher’’s exact test were used to assess for potential associations between insurance status and caretaker education level with the utilization of resources to learn about paediatric cardiac conditions. The study protocol was approved by the Institutional Review Board at Columbia University (protocol AAAT7433).

Results

Demographics

Surveys were administered to a total of 151 caretakers and 30 patients and were completed by 137/151 (91%) caretakers and 27/30 (90%) patients for an overall response rate of 91%. The median caretaker age range was 31–45 years of age. Among caretakers, 58/135 (43%) reported their race as White and 107/137 (78%) reported their gender as female. Of those who completed the survey questions on insurance and education, 83/135 (61%) of patients were covered by public medical insurance plans and 52/135 (39%) had private medical insurance plans. Sixty-three of 128 (49%) caretakers reported having completed at least 16 years of schooling or through a 4-year degree, and 65/128 (51%) reported fewer than 16 years of education or less than a 4-year degree. Seventy-nine of 136 (58%) caretakers reported speaking only English at home; 110/137 (80%) had access to a device (such as a laptop), 131/137 (96%) had Internet at home, and 126/136 (93%) used a smartphone. The median patient age range was 15–17 years of age. Among patients, 11/26 (42%) reported their race as White and 14/27 (52%) reported their gender as male. Additionally, 17/27 (63%) of patient responders reported speaking only English at home; 26/27 (96%) had access to a device (such as a laptop), 27/27 (100%) had internet at home, and 27/27 (100%) used a smartphone (Table 1).

Table 1. Caretaker demographic data by patient insurance type and caretaker education levela; paediatric patient demographic dataa

VSD = ventricular septal defect, ASD = atrial septal defect, AV canal defect=atrioventricular canal defect, TGA = transposition of the great arteries, CHD = congenital heart defect.

a Values represent number (%) of respondents unless otherwise indicated.

General resource utilisation by caretakers and paediatric patients

Websites and healthcare professionals, such as general paediatricians, paediatric cardiologists, and advanced practice providers, were the most popular resources caretakers reported using at least once to learn about paediatric cardiac conditions (websites 98/137 [72%], healthcare professionals 106/137 [77%], Table 2, Fig. 1). For caretakers who specifically indicated which types of websites they utilised, 58/74 (78%) reported using commercial websites such as WebMD. For caretakers who specifically indicated which healthcare professionals they consulted, 55/98 (56%) reported consulting someone other than the paediatric cardiologist to learn about the heart. Furthermore, 66/130 (51%) of the caretakers reported that their primary resource for learning about paediatric cardiac conditions was healthcare professionals, such as paediatric cardiologists, general paediatricians, or advanced practice providers (Supplementary Table S1). Patients also frequently reported consulting healthcare professionals (18/27 [67%]), and more than half reported using websites to obtain health information (15/27 [56%]). For patients who specifically indicated which healthcare professionals they consulted, 11/18 (61%) reported consulting someone other than their cardiologist to learn about the heart. The two most popular types of websites accessed by patients were commercial websites (7/11 [64%]) and hospital websites (5/11 [45%], Table 2, Fig. 1).

Figure 1. Caretakers’ utilizations of websites, healthcare professionals, social media, personal contacts, printed sources, and videos to learn about paediatric cardiac conditions differed between groups stratified by education level and patients’ insurance types.

Table 2. Resources utilization by patient insurance type and caretaker education level a

a Values represent number (%) of respondents unless otherwise indicated.

* Fischer’s Exact test p value.

Resource utilization by paediatric patient insurance type

The frequency of caretakers who reported using websites, healthcare professionals, and someone from their personal network was significantly different between groups stratified by the patient’s medical insurance type. Caretakers of patients covered by private medical insurance more frequently reported using websites (44/52 [85%] versus 53/83 [64%], p = 0.009), consulting healthcare professionals (48/52 [92%] versus 56/83 [67%], p = 0.008), and utilising someone from their personal network (19/52 [36.54] versus 13/83 [16%], p = 0.006) to learn about their child’s cardiac condition compared to caretakers of patients covered by public medical insurance (Table 2, Fig. 1). Although there were no significant differences in the proportion of caretakers who used commercial websites, government websites, hospital websites, and peer-reviewed medical journal websites, a larger proportion of caretakers with private medical insurance plans reported using websites of national organisations (such as healthychildren.org) compared to caretakers of patients covered by public medical insurance plans (13/38 [34%] versus 3/35 [8%], p = 0.008). Within the patient group, those covered by private insurance more frequently reported consulting their general paediatrician compared to those covered by public insurance (5/5 [100%] versus 2/10 [20%], p = 0.007).

Caretaker resource utilization by education level

Caretakers with higher education more frequently reported using websites (52/63 [83%] versus 42/65 [65%], p = 0.022), consulting healthcare professionals (58/63 [92%] versus 43/65 [66%], p < 0.001), utilising someone from their personal network (21/63 [33%] versus 10/65 [15%], p = 0.018)), and using printed sources (13/63 [21% versus 4/65 [6%], p = 0.016) to learn about their child’s cardiac condition compared to caretakers with fewer than 16 years of education (Table 2, Fig. 1). There were no significant differences in the use of social media/online groups and video platforms among caretakers stratified by their level of education. Compared to caretakers with fewer than 16 years of education, a significantly higher percentage of caretakers with higher education indicated that the primary resource they used to learn about their child’s cardiac diagnosis was healthcare professionals (38/62 [61%] versus 24/62 [39%], p = 0.015).

Access to devices and home internet by patient insurance status and caretaker education level

When comparing caretakers by insurance type, there were no significant differences in the proportion of caretakers with smartphones and Internet at home. A greater proportion of caretakers of patients covered by private medical insurance and those who completed higher education reported having access to a device, such as a desktop computer, laptop or tablet, when compared to caretakers of patients covered by public medical insurance (51/52 [98%] versus 58/83 [70%], p < 0.001) and those who completed fewer than 16 years of education (62/63 [98%] versus 43/65 [66%], p < 0.001), respectively (Fig. 2, Supplementary Table S2). Additionally, a significantly larger proportion of caretakers with higher education said that they use a smartphone compared to caretakers with fewer than 16 years of education (62/63 [100%] versus 57/65 [88%], p = 0.006). There were no significant differences in the proportion of caretakers who reported having Internet at home when stratified by educational attainment.

Figure 2. Caretakers differed significantly in their utilisation of devices such as smartphones and laptops when stratified by education level and patients’ insurance types. There were no significant differences in access to the Internet between groups.

Caretaker satisfaction with resources

Mean caretaker satisfaction with the amount of information received about their child’s cardiac condition (1 representing “extremely satisfied” and 5 representing “extremely dissatisfied”) was 1.37 ± 0.63. Mean patient satisfaction with the amount of information they received on their cardiac diagnosis was 1.44 ± 0.58 (Supplementary Table S3-S4). There were no significant differences in satisfaction with the amount of information received when caretakers were stratified by patients’ insurance types. When asked “how often did the information you obtained agree with your doctors’ recommendations?” (one representing “always” and five representing “never”) caretakers averaged a score of 1.60 ± 0.75 and patients averaged a score of 1.56 ± 0.89. There were no significant differences when comparing mean scores for this question by caretakers’ levels of education and by responders’ medical insurance types. Additionally, when asked how often participants had access to information in their native language (one representing “always” and five representing “never”), caretakers averaged a score of 1.58 ± 1.12, and patients averaged a score of 1.70 ± 1.20. There was no significant difference in mean scores with regard to access to information in participants’ native languages between caretakers who exclusively speak English at home and caretakers who speak at least one language other than English (such as Spanish or Arabic) at home.

Discussion

Disparities in health outcomes related to CHD continue to disproportionately affect vulnerable groups. Specifically, the incidence of CHD and risk of mortality in infants with CHD have been reported to be higher in ethnic minority groups living in areas of disadvantage characterised by factors such as poverty and low educational attainment. Reference Knowles, Ridout and Crowe12Reference Kucik, Nembhard and Donohue14 Recent studies have identified the importance of understanding how socio-economic factors relate to disparities in mortality and complications in children with CHD. Reference Anderson, Fieldston, Newburger, Bacha and Glied15Reference Richardson, Itua, Duong, Lewars and Tiesenga18 Health literacy is a modifiable factor that mediates the relationship between social determinants and health disparities. Reference Stormacq, Van den Broucke and Wosinski19,20 However, there are limited data on how families learn about paediatric cardiac conditions and whether any differences in information seeking exist.

The results of this survey-based study demonstrated that websites and healthcare professionals (such as paediatric cardiologists, general paediatricians, and advanced care providers) are two of the most popular resources both caretakers and patients use to learn about paediatric cardiac conditions. Differences in the utilisation of resources to learn about the heart were identified when caretakers were stratified based on their levels of education and the type of medical insurance covering their children. There were fewer differences in the utilisation of social media, video platforms, and paediatric cardiologists as sources of information between groups. Since paediatric cardiologists were consulted most frequently among these resources (social media, video platforms, and health professionals), paediatric cardiologists should feel empowered to provide resources whenever possible to maximise patient and caretaker comprehension of paediatric cardiac conditions.

Notably, the level of education completed by caretakers participating in the study correlates with the utilisation of informative resources to learn more about paediatric cardiac conditions. Prior studies have reported that the average readability of online sources with material pertaining to cardiac conditions is above 6th-grade reading level. Reference Arslan, Sami Tutar, Kozanhan and Bagci21 Not only does this potentially exclude caretakers with lower levels of education from engaging with these resources but it may also affect caretaker comprehension of online medical information thereby influencing caretakers’ health-related decisions, compliance to therapies, and consequently paediatric patients’ health outcomes.

Finally, grouping caretakers by their level of education revealed disparities in the utilisation of devices such as smartphones, laptops, desktop computers, and tablets. A lack of access to technology and low literacy with digital devices are barriers that exacerbate the “digital divide,” or disparities in the utilisation of technology and technical knowledge. Reference Alkureishi, Choo and Rahman22 These disparities may contribute to differences in the accessibility and availability of resources families utilise to learn about the heart. Reference Kubb and Foran23 Despite no significant difference in how satisfied caretakers were with the amount of information they received, the digital divide that exists among caretakers of children with cardiac conditions highlights a potential need among low-income families for additional tools that serve to increase caretaker knowledge of the heart and caretaker engagement with information on paediatric cardiac conditions. Reference Etnel, van Dijk and Kluin24

The study has several limitations. Given the small sample size of 27 paediatric patients, comparing patients’ responses by insurance and caregiver education would likely have been insufficiently powered to detect significant differences. Additionally, while the survey was reviewed with several paediatric cardiologists at our institution, it was not piloted with a group of potential participants prior to implementation. Piloting the survey would have helped the research team identify survey questions that may be confusing or unclear to participants. Though study participants may have encountered ambiguities in the survey, a member of the research team was always available to help address any questions or concerns. The study was furthermore subject to biases. All eligible patients and caretakers were approached about the study when reasonably possible; however, completion of the study survey was potentially subject to selection bias since only those who consented and assented to participate in the study were provided with the study survey. Variations between participants with regard to cardiac history (such as the severity of the diagnosis, number of hospitalisations, and prior surgeries) raise the potential for recall bias, which may impact study results. Data on the total number of patients and caretakers who were eligible for participation or were approached about the study but did not start the survey was not collected; the 151 caretakers who took the survey is a subset of the total number of eligible participants. Finally, a significant limitation of this study is that all patients and caretakers included in the study were from a single centre. The processes through which medical information is provided to patients are often highly institution-specific; thus, this study is limited in its generalizability to other institutions.

In addition to bridging the digital divide and identifying new, widespread sources of information both within social media and video platforms, greater access does not guarantee the equitable distribution of reliable information, therefore, patients and their families may require more guidance on how to identify trustworthy sources. Reference Baumann, Jaks, Robin, Juvalta and Dratva25,Reference Treadgold, Teasdale, Muller, Roberts, Coulson and Santer26 Further studies on how health literacy impacts health outcomes in children with CHD are needed to identify and target modifiable differences that may be leading to health disparities. Making sources of medical information low-cost, easily accessible (especially for families without stable resources such as devices, home internet, transportation, etc.), and available in different languages may be helpful for those with low health literacy. It is essential going forward that we identify issues surrounding access to sources of medical information and remove the barriers to access beleaguering populations affected by disinvestment. Additionally, there are limited data documenting how differences in the utilisation of informative resources affect health behaviour, decision-making, and health outcomes for children with CHD. Understanding whether variations in access to various digital and non-digital sources of medical information contribute to disparities in health outcomes is paramount in further identifying, which social determinants of health negatively impact children diagnosed with CHD.

Conclusion

Families of children with cardiac conditions vary significantly in the types of digital and non-digital resources they utilise and have access to for medical information. The use of websites, healthcare professionals, and personal contacts as sources of paediatric cardiac information varies significantly among caretakers when stratified by markers of socio-economic advantage and disadvantage such as caretakers’ levels of education and types of medical insurance coverage. Identifying differences in information seeking may improve our understanding of how inequitable systems fail to support families with low health literacy and further reinforce health disparities for children with CHD.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1047951123001634.

Acknowledgements

We wish to thank and acknowledge Dr Leonardo Liberman, Dr Amee M. Shah, Dr Thomas J. Starc, Dr Anne M. Ferris, Dr Adam Butensky, Dr Ezinne Emeruwa, Dr Jennifer Smerling, Dr Rebecca Epstein, Dr Alexandra Linder, Dr William Patten, Dr Ryan Closson, and Dr Kinjal Desai for allowing our team to recruit their clinical patients for this study.

Financial support

All phases of this study were supported by Scholarly Project Funding from Columbia University Vagelos College of Physicians and Surgeons & the Friedman Award.

Competing interests

None.

Ethical standard

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national guidelines on human experimentation (the Belmont Report and the Federal Policy for the Protection of Human Subjects or “Common Rule”) and with the Helsinki Declaration of 1975, as revised in 2008, and has been approved by the Institutional Review Board at Columbia University.

References

Liu, Y, Chen, S, Zühlke, L, et al. Global birth prevalence of congenital heart defects 1970-2017: updated systematic review and meta-analysis of 260 studies. Int J Epidemiol 2019; 48: 455463.CrossRefGoogle ScholarPubMed
Bernier, PL, Stefanescu, A, Samoukovic, G, Tchervenkov, CI. The challenge of congenital heart disease worldwide: epidemiologic and demographic facts. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu 2010; 13: 2634.CrossRefGoogle ScholarPubMed
Kovacevic, A, Simmelbauer, A, Starystach, S, et al. Counseling for prenatal congenital heart disease—Recommendations based on empirical assessment of counseling success. Frontiers in Pediatrics 2020; 8. DOI: 10.3389/fped.2020.00026.CrossRefGoogle ScholarPubMed
Kovacevic, A, Bär, S, Starystach, S, et al. Objective assessment of counselling for fetal heart defects: an interdisciplinary multicenter study. J Clin Med 2020; 9: 467.CrossRefGoogle ScholarPubMed
Hilton-Kamm, D, Sklansky, M, Chang, RK. How not to tell parents about their child’s new diagnosis of congenital heart disease: an internet survey of 841 parents. Pediatr Cardiol 2014; 35: 239252.CrossRefGoogle ScholarPubMed
Kasparian, NA, Lieu, N, Winlaw, DS, Cole, A, Kirk, E, Sholler, GF. EHealth literacy and preferences for eHealth resources in parents of children with complex CHD. Cardiol Young 2017; 27: 722730.CrossRefGoogle ScholarPubMed
Ikemba, CM, Kozinetz, CA, Feltes, TF, et al. Internet use in families with children requiring cardiac surgery for congenital heart disease. Pediatrics 2002; 109: 419422.CrossRefGoogle ScholarPubMed
Arya, B, Glickstein, JS, Levasseur, SM, Williams, IA. Parents of children with congenital heart disease prefer more information than cardiologists provide. Congenit Heart Dis 2013; 8: 7885.CrossRefGoogle ScholarPubMed
Knapp, C, Madden, V, Wang, H, Sloyer, P, Shenkman, E. Internet use and eHealth literacy of low-income parents whose children have special health care needs. J Med Internet Res 2011; 13: e75.CrossRefGoogle ScholarPubMed
Chesser, A, Burke, A, Reyes, J, Rohrberg, T. Navigating the digital divide: a systematic review of eHealth literacy in underserved populations in the United States. Inform Health Soc Care 2016; 41: 119.CrossRefGoogle ScholarPubMed
Massin, MM, Montesanti, J, Gerard, P. Use of the internet by parents of children with congenital heart disease. Acta Cardiol 2006; 61: 406410.CrossRefGoogle ScholarPubMed
Knowles, RL, Ridout, D, Crowe, S, et al. Ethnic and socioeconomic variation in incidence of congenital heart defects. Arch Dis Child 2017; 102: 496502.CrossRefGoogle ScholarPubMed
Lopez, KN, Morris, SA, Sexson Tejtel, SK, Espaillat, A, Salemi, JL. US mortality attributable to congenital heart disease across the lifespan From 1999 Through 2017 Exposes persistent racial/Ethnic disparities. Circulation 2020; 142: 11321147.CrossRefGoogle ScholarPubMed
Kucik, JE, Nembhard, WN, Donohue, P, et al. Community socioeconomic disadvantage and the survival of infants with congenital heart defects. Am J Public Health 2014; 104: e150e157.CrossRefGoogle ScholarPubMed
Anderson, BR, Fieldston, ES, Newburger, JW, Bacha, EA, Glied, SA. Disparities in outcomes and resource use after hospitalization for cardiac surgery by neighborhood income. Pediatrics 2018; 141: e20172432.CrossRefGoogle ScholarPubMed
Peyvandi, S, Baer, RJ, Moon-Grady, AJ, et al. Socioeconomic mediators of racial and ethnic disparities in congenital heart disease outcomes: a population-based study in California. J Am Heart Assoc 2018; 7: e010342e010342.CrossRefGoogle ScholarPubMed
Tillman, AR, Colborn, KL, Scott, KA, et al. Associations between socioeconomic context and congenital heart disease related outcomes in adolescents and adults. Am J Cardiol 2021; 139: 105115.CrossRefGoogle ScholarPubMed
Richardson, CJ, Itua, P, Duong, T, Lewars, J, Tiesenga, F. Racial and socioeconomic disparities in congenital heart surgery: a research article. J Card Surg 2021; 36: 24542457.CrossRefGoogle ScholarPubMed
Stormacq, C, Van den Broucke, S, Wosinski, J. Does health literacy mediate the relationship between socioeconomic status and health disparities? Integrative review. Health Promot Int 2018; 34: e1e17.CrossRefGoogle Scholar
Office of Disease Prevention and Health Promotion, U.S. Department of Health and Human Services. Social determinants of health. Healthy People 2030, https://health.gov/healthypeople/priority-areas/social-determinants-health.Google Scholar
Arslan, D, Sami Tutar, M, Kozanhan, B, Bagci, Z. The quality, understandability, readability, and popularity of online educational materials for heart murmur. Cardiol Young 2020; 30: 328336.CrossRefGoogle ScholarPubMed
Alkureishi, MA, Choo, ZY, Rahman, A, et al. Digitally disconnected: qualitative study of patient perspectives on the digital divide and potential solutions. JMIR Hum Factors 2021; 8: e33364.CrossRefGoogle ScholarPubMed
Kubb, C, Foran, HM. Online health information seeking by parents for their children: systematic review and agenda for further research. J Med Internet Res 2020; 22: e19985.CrossRefGoogle ScholarPubMed
Etnel, JRG, van Dijk, APJ, Kluin, J, et al. Development of an online, evidence-based patient information portal for congenital heart disease: a pilot study. Front Cardiovasc Med 2017; 4: 25.CrossRefGoogle ScholarPubMed
Baumann, I, Jaks, R, Robin, D, Juvalta, S, Dratva, J. Parents’ health information seeking behaviour - does the child’s health status play a role? BMC Fam Pract 2020; 21: 266.CrossRefGoogle ScholarPubMed
Treadgold, BM, Teasdale, E, Muller, I, Roberts, A, Coulson, N, Santer, M. Parents and carers’ experiences of seeking health information and support online for long-term physical childhood conditions: a systematic review and thematic synthesis of qualitative research. BMJ Open 2020; 10: e042139.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Caretaker demographic data by patient insurance type and caretaker education levela; paediatric patient demographic dataa

Figure 1

Figure 1. Caretakers’ utilizations of websites, healthcare professionals, social media, personal contacts, printed sources, and videos to learn about paediatric cardiac conditions differed between groups stratified by education level and patients’ insurance types.

Figure 2

Table 2. Resources utilization by patient insurance type and caretaker education levela

Figure 3

Figure 2. Caretakers differed significantly in their utilisation of devices such as smartphones and laptops when stratified by education level and patients’ insurance types. There were no significant differences in access to the Internet between groups.

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