key: cord-1044647-mzcnpvwl
authors: Ou, Michael T.; Boyarsky, Brian J.; Zeiser, Laura B.; Po-Yu Chiang, Teresa; Ruddy, Jake; Van Pilsum Rasmussen, Sarah E.; Martin, Jennifer; St. Clair Russell, Jennifer; Durand, Christine M.; Avery, Robin K.; Werbel, William A.; Cooper, Matthew; Massie, Allan B.; Segev, Dorry L.; Garonzik-Wang, Jacqueline M.
title: Kidney Transplant Recipient Attitudes Toward a SARS-CoV-2 Vaccine
date: 2021-06-10
journal: Transplant Direct
DOI: 10.1097/txd.0000000000001171
sha: ae4c34157e4010ad3166a8330bcf4f7577219cdc
doc_id: 1044647
cord_uid: mzcnpvwl

A widely accepted severe acute respiratory syndrome 2 (SARS-CoV-2) vaccine could protect vulnerable populations, but the willingness of solid organ transplant recipients (SOTRs) to accept a potential vaccine remains unknown. METHODS. We conducted a national survey of 1308 SOTRs and 1617 non-SOTRs between November 11 and December 2, 2020 through the network of the National Kidney Foundation. RESULTS. Respondents were largely White (73.2%), female (61.1%), and college graduates (56.2%). Among SOTRs, half (49.5%) were unsure or would be unwilling to receive a SARS-CoV-2 vaccine once available. Major concerns included potential side effects (85.2%), lack of rigor in the testing and development process (69.7%), and fear of incompatibility with organ transplants (75.4%). Even after the announcement of the high efficacy of the mRNA-1273 vaccine (Moderna Inc.) at the time of survey distribution, likeliness to receive a vaccine only slightly increased (53.5% before announcement versus 57.8% after the announcement). However, 86.8% of SOTRs would accept a vaccine if recommended by a transplant provider. CONCLUSIONS. SOTRs reported skepticism in receiving a potential SARS-CoV-2 vaccine, even after announcements of high vaccine efficacy. Reassuringly, transplant providers may be the defining influence in vaccine acceptance and will likely have a critical role to play in promoting vaccine adherence.

A widely-accepted severe acute respiratory syndrome 2 (SARS-CoV-2) vaccine could protect the community and vulnerable populations. However, the safety and efficacy of SARS-CoV-2 vaccines in solid organ transplant recipients (SOTRs) are currently unknown as clinical trials have excluded immunocompromised individuals. [1] [2] [3] [4] [5] Furthermore, although mRNA vaccine platforms offer greater flexibility in antigen manipulation and increased speed of development, 6 this relatively new platform has also not been tested in SOTRs. 1, 7 Coupled with the lack of long-term data, concerns over safety may impact the willingness of SOTRs to accept an SARS-CoV-2 vaccine once individually available.

Background. A widely accepted severe acute respiratory syndrome 2 (SARS-CoV-2) vaccine could protect vulnerable populations, but the willingness of solid organ transplant recipients (SOTRs) to accept a potential vaccine remains unknown. Methods. We conducted a national survey of 1308 SOTRs and 1617 non-SOTRs between November 11 and December 2, 2020 through the network of the National Kidney Foundation. Results. Respondents were largely White (73.2%), female (61.1%), and college graduates (56.2%). Among SOTRs, half (49.5%) were unsure or would be unwilling to receive a SARS-CoV-2 vaccine once available. Major concerns included potential side effects (85.2%), lack of rigor in the testing and development process (69.7%), and fear of incompatibility with organ transplants (75.4%). Even after the announcement of the high efficacy of the mRNA-1273 vaccine (Moderna Inc.) at the time of survey distribution, likeliness to receive a vaccine only slightly increased (53.5% before announcement versus 57.8% after the announcement). However, 86.8% of SOTRs would accept a vaccine if recommended by a transplant provider. Conclusions. SOTRs reported skepticism in receiving a potential SARS-CoV-2 vaccine, even after announcements of high vaccine efficacy. Reassuringly, transplant providers may be the defining influence in vaccine acceptance and will likely have a critical role to play in promoting vaccine adherence.

Although vaccines provide direct immunity to those vaccinated, they also provide indirect protection to unvaccinated individuals via herd immunity. One study estimated that at least two-thirds of the population need to be vaccinated before coronavirus disease 2019 (COVID-19) herd immunity develops, 8 yet projected global acceptance of SARS-CoV-2 vaccine dips to only half of the population in some countries, 9 and surveys of projected acceptance in the United States within non-SOTR populations vary widely. [10] [11] [12] [13] Despite this heterogeneity in vaccine acceptance patterns, physician recommendation may play an important role in vaccine acceptance, often being cited as the top reason for vaccination. [14] [15] [16] [17] For SOTRs, transplant provider recommendation may play a particularly critical role in vaccine acceptance, given the close relationship and trust SOTRs have with their transplant team. 18, 19 However, it is unknown whether SOTRs or their household contacts will widely accept a vaccine if a provider recommendation can overcome vaccine skepticism, or whether announcements of high efficacy in vaccine trials have changed vaccine perceptions.

To elicit the attitudes toward a potential SARS-CoV-2 vaccine in SOTRs across the United States, we conducted a national survey of SOTRs and non-SOTRs between November 11 and December 2, 2020. We gathered data in 2 major domains: (1) perceptions of a SARS-CoV-2 vaccine and (2) the impact of the pandemic on daily life and mental health. To assist future vaccine uptake efforts, we also identified potential barriers to vaccination. Understanding the perceptions of SOTRs will be a fundamental step in addressing vaccine concerns and promoting widespread acceptance in this vulnerable population.

We distributed the survey through the National Kidney Foundation's (NKF) network of 2806 SOTRs and 12 476 non-SOTRs (including family members, spouses, caregivers, and living donors) via email. A link to the survey was also posted twice to the NKF's social media platforms and was clicked a total of 364 times. For the purposes of calculating a response rate, we include the 364 social medial post views as unique survey invitations (and thus were included in our source population). Unfortunately, we were unable to determine if the social media post viewers were SOTRs or non-SOTRs. Thus, we report a range of response rates for each group, under the assumption that all or none were SOTRs. Thus, our response rate for SOTRs was 41.2%-46.6% and our response rate for non-SOTRs was 12.6%-13.0%. The overall response rate was 18.7%. The survey was conducted between November 11 and December 2, 2020, deemed an exempt research study by the institutional review board at Johns Hopkins School of Medicine (IRB00266679) and was hosted by Qualtrics (Provo, UT).

Questions were developed through an iterative process, based on a thorough review of the literature and discussion with 3 transplant surgeons, 3 transplant infectious diseases physicians, and a survey research expert. The input was also obtained from other members of the transplant team and the NKF. The survey and was piloted in a cohort of 11 transplant recipients, family members, and patients with kidney disease and found to function as intended.

The survey contained a total of 42 questions. Participant demographics including sex, race, ethnicity, education, household income, household size, marital status, employment status, and location were collected. Medical and transplant history was elicited, as well as test status, hospitalizations, and medical interventions related to COVID-19 infection. We studied 2 major domains: perceptions of a SARS-CoV-2 vaccine and the impact of the pandemic on daily life and mental health. The first domain included questions about willingness to obtain a potential SARS-CoV-2 vaccine, the recommendation to others, and perceptions about vaccine use in transplant recipients. Specific factors that influence vaccine hesitancy were also determined, based on open-ended themes previously identified in a survey of US adults. 11 The second domain focused on understanding the impact of the COVID-19 pandemic on daily routine, access to medical care, and life circumstances such as job and income stability. This domain also included the Coronavirus Anxiety Scale to identify probable cases of dysfunctional anxiety associated with the COVID-19 crisis (Table S1 , SDC, http://links.lww.com/TXD/A337). 20, 21 The survey took, on average, <10 min.

All statistical analyses were performed using Stata 16.1 for Windows (College Station, TX). We tested the association between vaccination attitudes and binary variables by Fisher's exact test, and continuous variables using the Wilcoxon ranksum test. We reported P values with an α of 0.05 for statistical significance.

We compared SOTRs to all non-SOTRs respondents. Among the non-SOTR respondents, we also compared those who lived in the same house to an SOTR (household contact) to those who did not (nonhousehold contacts). Although our survey was distributed after the announcement of high efficacy in the BNT162b1 vaccine (Pfizer Inc.), announcement of 94.5% efficacy in the mRNA-1273 vaccine (Moderna Inc.) occurred on November 16, 2020. We compared vaccine attitudes before and after this announcement by stratifying between those that answered before and after November 17, 2020. This date was used to account for the lag between news availability and awareness by the general public.

Among SOTRs who did not know that they were being excluded from vaccine clinical trials, we compared their likelihood of vaccination before and after learning this information. We used a 5-point Likert scale when asking about the likelihood of receiving a potential vaccine but collapsed responses into binary variables; those extremely likely or likely we included in one group whereas those who were unsure, unlikely, or extremely unlikely into another.

The Coronavirus Anxiety Scale, which has a 90% sensitivity and 85% specificity at a cutoff score of 9, was originally validated in a population with known COVID-19 anxiety. Repeat measurements found that a cutoff score of 5 may be more appropriate in populations in which the proportion of COVID-19 anxiety is unknown. 20 We included both for comprehensiveness. 

A total of 2925 people responded with approximately 44.7% being SOTRs. The majority of respondents were White (73.2%) and female (61.1%), with a wide distribution of age, geographic region, and household income (Table 1) . A large number had at least a college degree (56.2%) and were married (56.1%). Seventy-seven respondents (2.6%) had tested positive for COVID-19 and among those positive, 18 respondents (22.2%) had been hospitalized. The majority (98.9%) of SOTRs were kidney transplant recipients.

Compared to non-SOTRs, more SOTRs were male (37.9% versus 29.9%, P < 0.001), had at least a college degree (59.0% versus 54.0%, P = 0.01), were employed (41.9% versus 36.2%, P < 0.01), and believed they would get seriously ill from COVID-19 in the next 6 mo (14.6% versus 9.8%, P < 0.001). Less SOTRs intended to receive a vaccine compared to non-SOTRs (50.5% versus 60.7%, P < 0.001).

Six-hundred forty-seven (49.5%) SOTRs would be either unsure or unwilling to receive a SARS-CoV-2 vaccine once 

individually available (Table 2) . Females (55.4%, P < 0.001), Blacks (71.3%, P < 0.001), and those of lower household income (62.8%, P < 0.001) and lower educational attainment (56.7%, P < 0.001) were more likely to be unsure or unwilling to receive a potential vaccine. Among SOTRs who did not receive a flu vaccine in 2019, 71.9% were unsure or would be unlikely to receive a potential SARS-CoV-2 vaccine compared to 28.1% who would be likely (P < 0.001). Among SOTRs who believed they would get seriously ill from COVID-19 in the next 6 mo, 48.9% indicated uncertainty or refusal of a potential vaccine.

In respondents who indicated they would be uncertain or refuse an SARS-CoV-2 vaccine, side effects (85.2% SOTRs, 85.4% non-SOTRs), lack of rigor in testing and development (69.7% SOTRS, 69.5% non-SOTRS), and low efficacy (54.8% SOTRs, 56.0%) were cited as major concerns (Table 3) . Compared to non-SOTRs, SOTRs were more likely to want information regarding their health compatibility with a potential vaccine (75.4% versus 59.0%, P < 0.001) and a recommendation by their physician (80.0% versus 57.9%, P < 0.001). Fewer SOTRs believed that vaccines "don't work" (1.6% versus 3.7%, P = 0.02) and they had less concern about cost (23.6% versus 29.8%, P = 0.02), less mistrust of vaccines in general (7.7% versus 15.6%, P < 0.001), as well as less mistrust of pharmaceutical companies (29.4% versus 39.0%, P < 0.001).

Among respondents who would be likely to accept vaccination, we asked what barriers would decrease vaccine adherence. Compared to non-SOTRs, SOTRs were less likely to indicate cost (17.4% versus 22.8%, P < 0.01) and travel distance (10.1% versus 18.6%, P < 0.001) as reasons that would prevent them from receiving a vaccine. Roughly two-thirds (61.6%) of people responded to the survey after the major announcement about vaccine efficacy in mRNA-1273 vaccine (Moderna Inc.) and respondents were only slightly more likely to agree to receive a vaccine (57.8% after announcement versus 53.5% before announcement) (Table S2 , SDC, http://links.lww.com/TXD/A337). However, there were no significant differences in specific concerns about the vaccine itself. Although only half of SOTRs would be likely to receive a vaccine, 86.8% of SOTRs would receive a vaccine if recommended by a transplant surgeon or doctor, 71.9% if the recommendation came from a nonphysician transplant team member (ex. nurse, coordinator, physician assistant, etc), and 64.1% if from a primary care provider (P < 0.001) (Figure 1 ). Of the SOTRs, 75.1% did not know that SOTRs were being excluded from phase III trials, and among them, 21.9% would be likely to receive a vaccine compared to the 50.5% who would be likely before they were informed of this exclusion ( Figure 2 ).

Of non-SOTRs, 606 (37.5%) respondents lived with an SOTR. Only 57.6% of these household contacts intend to receive a vaccine, a similar number (61.3%) to non-SOTR respondents who did not live with a SOTR (Figure 3) . If recommended by a physician, 73.9% of household contacts would agree to receive a vaccine, whereas only 52.2% believed SOTRs should be vaccinated. Compared to non-SOTRs respondents who are not household contact, a larger proportion of household members believed that a vaccine would be safe for SOTRs (46% versus 35%) (Figure 4 ).

Compared to non-SOTRs, SOTRs were more likely to be practicing social distancing (92.3% versus 89.7%, P = 0.02) and self-quarantine (12.3% versus 7.6%, P < 0.001) ( Table 4 ). Non-SOTRs had more difficulty paying for basic necessities (43.4% versus 36.0%, P = 0.04), affording medical care (16.4% versus 10.8%, P = 0.02), and accessing a device for virtual healthcare (17.4% versus 9.8%, P < 0.01). However, severe anxiety related to the COVID-19 pandemic was low in both SOTRs and non-SOTRs (1.9% versus 2.1%, P = 0.8).

In this national survey of 1308 SOTRs, we found that only 51% intend to obtain a SARS-CoV-2 vaccine once available. We identified concerns about side effects, incompatibility with personal health conditions, lack of rigor in testing and development, and low efficacy as major barriers. Our study highlights the large amounts of skepticism toward a potential vaccine. These findings are striking in the face of available preliminary reports at the time of survey administration of high efficacy in phase III clinical trials, specifically 90% and 94.5% efficacy in the SARS-CoV-2 vaccines BNT162b1 and mRNA-1273, respectively. 2, 22 It seems that skepticism arising from the speed with which vaccines are being developed and tested may offset early acceptance. Reassuringly, willingness to be vaccinated was close to 90% among SOTRs if a recommendation came from a transplant provider, foreshadowing the critical role transplant providers may play. The average vaccine, taken from the preclinical phase, requires a development timeline of approximately 11 y. 23 Even after the Ebola outbreak of 2014, the accelerated development of the first Ebola vaccine took 5 y. 24 The COVID-19 pandemic has shifted the development paradigm from a linear sequence to a parallel sequence, with multiple stages being executed simultaneously. It has taken only 11 mo from the time Chinese authorities shared the genetic sequence of the novel coronavirus to the first injections of a vaccine to the public. 25 However, the emphasis on speed has provoked public anxiety. Our results confirm previous findings of quality control fears and concern for the fast pace of development and testing. 13, 26 Despite the reassurance of unwavering regulatory safeguards by the FDA, 27 it seems that months of mixed messages from various sources about COVID-19 may have eroded public trust. We found that the likelihood of accepting a potential vaccine did marginally increase after the efficacy announcement of the mRNA-1273 vaccine, but still far below conservatively projected herd immunity thresholds. Widespread vaccination among family members and household contacts of SOTRs may provide a level of protection even if herd immunity is not achieved. However, we found similar rates of intention to accept a vaccine between household contacts (57.6%) as compared to those who do not live with an SOTR (61.3%). This low rate of vaccine acceptance is alarming, especially given that only half (52.2%) of household contacts believe that SOTRs should receive a vaccine. The need for reassurance, education, and vaccine promotion will be all the more necessary in the upcoming days to weeks as vaccines become increasingly available to transplant recipients. Hesitancy to incur any vaccine-related risks was demonstrated by the significant need to understand organ transplant compatibility and to know physician recommendations before considering a potential SARS-CoV-2 vaccine. However, this may also be one of the greatest areas to promote vaccine acceptance. Although half of SOTRs were skeptical about a potential vaccine, 86.8% would be willing to receive a vaccine should that recommendation come from a transplant provider, whereas only 64% would be willing if it came from a primary care physician. These results highlight the incredible amount of trust between the SOTR and their transplant providers, a bond that can be the defining influence in vaccine acceptance. A recommendation by a trusted transplant provider can alleviate, or at least reduce, many fears SOTRs may have toward a new vaccine. Transplant providers will likely have a crucial role to play in protecting this population from infection by promoting vaccine adherence.

However, such promotion may be limited because of social distancing and pandemic-related restrictions. Therefore, additional alternative methods to promote vaccine adherence among transplant recipients should be considered. Recently, the Am J Transplant (AST) issued a statement recommending COVID-19 vaccination for most transplant recipients and candidates. 28 Further adoption statements by other transplant societies could act as a rapid, widespread, and unified message to the transplant community, quelling suspicion and fear. The rise of online clinical visits and virtual meetings can also be leveraged to reach large audiences, whereas virtual town halls and community dialogues can act as a gateway toward the dissemination of vaccine information and physician recommendations. Our study found that even a recommendation from a nonphysician member of the transplant team was able to convince 72% of kidney transplant recipients to receive a vaccine. Nurse or coordinator-led group education sessions, transplant program position statements to patients, and other institutional outreach may all serve as the foundation to widespread vaccine acceptance in transplant recipients.

Those who were hesitant to receive a vaccine were more likely to be Black, of lower household income, and lower educational attainment. These findings are consistent with other studies that have found that lower socioeconomic status was negatively associated with vaccination rates, [29] [30] [31] [32] and the existence of wide racial disparities in vaccination. [33] [34] [35] For example, one study of adult influenza vaccination demonstrated that African Americans had significantly lower odds of receiving an influenza vaccine compared to Whites (odds ratio = 0.55, 95% confidence interval, 0.42-0.72). These socioeconomic and racial disparities are of even higher concern given the increased rates of COVID-19 infection and mortality in disadvantaged populations, 36, 37 and among African American communities. 38, 39 Our findings further emphasize the importance of outreach to these vulnerable populations in which increased impact, coupled with lower vaccination rates, may further amplify health disparities. This study is the first national survey to investigate the attitudes of SOTRs toward a potential SARS-CoV-2 vaccine. Some of the strengths of this study include a wide geographical distribution of responses and large sample size. We were not only able to collect attitudes about a potential vaccine but also identify the specific factors influencing vaccine hesitancy. Furthermore, the timing of our survey administration was during the peak of vaccination interest as large pharmaceutical companies began publishing reports of efficacy. We were able to distinguish whether certain announcements changed vaccine attitudes, making these findings particularly pertinent. Our study provides a framework for transplant providers to target education and anticipatory guidance efforts for SOTRs regarding these novel vaccines and, ideally, reduce vaccine hesitancy.

However, there are some limitations. Study respondents were largely White and with college degrees. The generalizability of this study to other populations may be limited. However, we do believe that the significant hesitancy captured in this study is likely on the conservative side, given that vaccine uptake is less among non-White, socially disadvantaged groups as described above. Additionally, our overall response rate was low, which may lead to participation bias. However, our response rate was consistent with similar large-scale surveys and our SOTRspecific response rate was quite high. 11, 16 Furthermore, we recognize that survey distribution through the NKF's network may reflect engaged patients and families, and thus may not be generalizable to the entire population of kidney transplant recipients. This cross-sectional survey was also conducted in a rapidly changing landscape in which vaccine information is quickly evolving. Since the distribution of this survey, complete reports of the BNT162b1 vaccine (Pfizer Inc.) and mRNA-1273 vaccine (Moderna Inc.) have been published, emergency use authorizations have been granted, and millions of vaccines have already been distributed. The AST has also issued a statement recommending COVID-19 vaccination for most transplant recipients and candidates. 28 Although individual attitudes may have shifted, we believe that the importance of transplant providers in providing reassurance and guidance to their patients likely remains true. Lastly, there may be potential for nonresponse bias as this study was administered via email and social media platforms, a form of communication that may not be used by all.

In conclusion, this national survey of SOTRs demonstrated heterogeneity in vaccine attitudes amongst SOTRs. Concerns about side effects, incompatibility with conditions, and lack of rigor in testing and development were identified as major barriers towards vaccine acceptance. Additional data on safety in the SOTR population may be needed to further convince those with hesitancy to pursue vaccination. Nonetheless, advocacy by transplant providers may lead to maximal rates of vaccination among SOTRs. Future research is needed to better understand vaccine behaviors in SOTRs and may promote vaccine acceptance.

COVE Study Group. Efficacy and safety of the mRNA-1273 SARS-CoV-2 vaccine

C4591001 Clinical Trial Group. Safety and efficacy of the BNT162b2 mRNA COVID-19 vaccine

Safety and efficacy of the ChAdOx1 nCoV-19 vaccine (AZD1222) against SARS-CoV-2: an interim analysis of four randomised controlled trials in Brazil, South Africa, and the UK

Single dose administration, and the influence of the timing of the booster dose on immunogenicity and efficacy of ChAdOx1 NCoV-19 (AZD1222) vaccine. Social Science Research Network

Evaluation of the safety and immunogenicity of a SARS-CoV-2 rS nanoparticle vaccine with/without matrix-m adjuvant -full text view -clinicaltrials

The COVID-19 vaccine development landscape

Preclinical and clinical demonstration of immunogenicity by mRNA vaccines against H10N8 and H7N9 influenza viruses

Herd immunity: understanding COVID-19

A global survey of potential acceptance of a COVID-19 vaccine

A future vaccination campaign against COVID-19 at risk of vaccine hesitancy and politicisation

Attitudes toward a potential SARS-CoV-2 vaccine: a survey of U.S. adults

Determinants of COVID-19 vaccine acceptance in the

Influences on attitudes regarding potential COVID-19 vaccination in the United States. Vaccines (Basel)

Impact of a physician recommendation

Influenza among healthy young children: changes in parental attitudes and predictors of immunization during the 2003 to 2004 influenza season

Predictors of HPV vaccine uptake among women aged 19-26: importance of a physician's recommendation

Impact of a physician recommendation and parental immunization attitudes on receipt or intention to receive adolescent vaccines

Perceptions of experiences of graft rejection among organ transplant recipients striving to control the uncontrollable

Fear of graft rejection 1-5 years after lung transplantation -A nationwide cohort study

Replication analysis of the Coronavirus Anxiety Scale

Coronavirus Anxiety Scale: A brief mental health screener for COVID-19 related anxiety

Moderna's COVID-19 Vaccine Candidate Meets its Primary Efficacy Endpoint in the First Interim Analysis of the Phase 3 COVE Study. 2020. Available at investors.modernatx.com/news-releases/news-releasedetails/modernas-covid-19-vaccine-c andidate-meets-its-primaryefficacy

Risk in vaccine research and development quantified

WHO prequalifies Ebola vaccine, paving the way for its use in high-risk countries

Work on a COVID-19 Vaccine Candidate | Moderna

Vaccine hesitancy: the next challenge in the fight against COVID-19

Unwavering regulatory safeguards for COVID-19 vaccines

COVID-19: Vaccine FAQ Sheet

The association between influenza vaccination and socioeconomic status in high income countries varies by the measure used: a systematic review

Socioeconomic status, demographics, beliefs and A(H1N1) vaccine uptake in the United States

Predictors of flu vaccination among urban Hispanic children and adults

Relationship of income and health care coverage to receipt of recommended clinical preventive services by adults -United States

Racial disparities in human papillomavirus vaccination: does access matter?

Racial disparity in influenza vaccination: does managed care narrow the gap between African Americans and whites?

The role of attitudes in understanding disparities in adult influenza vaccination

Socio-economic status and COVID-19-related cases and fatalities

Socioeconomic inequalities in the spread of coronavirus-19 in the United States: a examination of the emergence of social inequalities

Racial and Ethnic Disparities in SARS-CoV-2 Pandemic: Analysis of a COVID-19 Observational Registry for a Diverse U.S. Metropolitan Population | medRxiv