Hepatitis A virus (HAV) is one of the leading causes of acute hepatitis. In the majority of European Union/European Economic Area (EU/EEA) countries, decreased in HAV circulation in the past decades has resulted in a significant proportion of individuals without immunity following natural infection and then susceptible to HAV infection.1 Likewise, the incidence of hepatitis A in Spain remains low and steady.2 However, periodic HAV outbreaks arise periodically, particularly affecting men who have sex with men (MSM), most of them living with HIV. In this respect, between 2016 and 2017 a large hepatitis A epidemic occurred across EU/EEA. Spain was one of the most struck countries, accounting for over 50% of HAV infections.3 In this subset, MSM were disproportionately affected and nearly half of the individuals with available HIV status data were living with HIV.3 Moreover, the majority of individuals who acquired HAV infection during this EU/EEA outbreak had not been previously vaccinated against HAV.3 In addition to that, health costs associated to HAV outbreaks are not negligible. Although HAV-related mortality is rare, morbidity due to HAV infection is significant, especially for the adult population.4 In this sense, between January and June 2017, only in Barcelona, 39% of the reported HAV infected individuals were admitted in hospital facilities.5 Besides, indirect costs linked to work absenteeism should not be underestimated.

In the vast majority of countries of the EU/EEA, universal HAV vaccination has not been adopted and is only currently recommended for high-risk groups. Thus, HAV immunization among MSM is commonly advised. However, as of February 2020, very few countries also recommend and cover HAV vaccination among people living with HIV (PLWH), such as Spain.6 Among PLWH with good immunological status, HAV vaccination with two standard doses achieves seroconversion rates above 90%.7,8 Consequently, lack of HAV immunity is the main cause of HAV outbreaks.9 Hence, current pockets of susceptible individuals along with environmental and behavioral risk factors may be determinant for new epidemics. However, HAV seroepidemiological data among PLWH are scarce and most of the studies which assessed HAV immunity prevalence are outdated and might not be reflecting the current situation.10–18 Besides, information on HAV vaccine coverage for PLWH is lacking and HAV vaccination programs outcomes remain unknown in real-life interepidemic conditions.

Therefore, the aims of this study were, firstly, to assess HAV serologic status among PLWH in Seville, Southern Spain, and, secondly, to evaluate the impact of a vaccination-based intervention among HAV-seronegative PLWH.

In our setting, a considerable proportion of PLWH are still susceptible to HAV infection, mainly those who acquired HIV infection through sexual transmission. A strategy based on the active investigation of HAV non-immune cases and subsequent systematic referral for vaccination results in only modest increases in the proportion of individuals immune against HAV infection, which is largely due to failures in adherence to the vaccination program.

The current study reveals that a substantial number of patients, particularly MSM, are at risk of acquiring HAV infection in future hepatitis A outbreaks, which will likely emerge, as they are historically cyclical.4 In addition, in the setting of acute symptomatic HAV infection, it has been reported that HAV viral load and duration of viremia are higher among PLWH than in non-HIV infected individuals.21 These two conditions could promote the maintenance and spreading of HAV outbreaks. Besides, health resources might be wasted, as patients who are screened do not initiate vaccination or even do not complete vaccination due to losses to follow-up.

Characterizing the epidemiology of HAV infection among PLWH, particularly HAV susceptibility trends, is essential to design effective vaccination programs. As a matter of fact, in the past decades, the prevalence of individuals susceptible to HAV infection has increased as HAV circulation has declined in middle and high-income countries along with insufficient vaccination coverage.1 However, in the present study, the proportion of PLWH immune to HAV was substantially greater than those estimated in most of these settings among general population1,22 and PLWH.13,22 In spite of this, considerable non-immunization rates were observed, ranging from 11% to 26%, depending on the HIV risk factor considered. Critical immunity threshold for preventing hepatitis A outbreaks has been estimated to be ≥70% among MSM.23 However, the threshold of 70% PLWH with immunity might be insufficient in case of an outbreak emergence, as data from the recent HAV outbreak in Lyon, France, has shown.24 Thus, even if the susceptibility prevalence is lower than in other populations, specific groups could be more vulnerable to HAV infection due to high-risk behaviors. Accordingly, in a seroincidence study carried out in our area, we found that, even if an elevated proportion of individuals were immune, incident HAV cases peaked in the last two major outbreaks occurred in 2009–2010 and 2017–2018.9 In the present study, the prevalence of HAV immunity was higher among injecting drug users, as reported in other studies.13,14,25 This is probably driven by a greater exposure to HAV related to parenteral drug use and poorer hygienic-sanitary living conditions. It is remarkable that, despite the implementation of HAV vaccination for MSM and PLWH in the recent years, the rates of immunization in our area were similar to those found in 2008–2009,11 suggesting that immunization strategies have not been effective. In this study, the intervention carried out succeeded at identifying a maximum number of HAV-seronegative individual. However, no significant increase of the overall immunization rate was achieved, largely due to failures in adherence to the vaccination circuit.

The present study results highlight the need of improving HAV vaccination coverage in at-risk populations. Identifying perceived barriers and facilitators of HAV vaccination among PLWH should be imperative when designing an effective immunization-based intervention, particularly in pandemic conditions. In the present work, the causes of the absence of HAV immunity were multifactorial. Thus, the poor results of the immunization program could be influenced by the fact that vaccination and post-vaccination controls require additional medical visits at different units, which may be enhancing missed opportunities for hepatitis A immunization. Secondly, lack of knowledge about HAV might lead PLWH to underestimate the risk and severity of HAV infection and therefore consider vaccination not important. In the European MSM Internet Survey published in 2017, only 45% of the participants were aware of hepatitis A or B disease, the existence of a vaccine and its specific recommendation.26 More recently, this issue has once again arisen in a French study.27 Thus, interventions targeting PLWH to improve health education are needed. Finally, we cannot rule out that COVID-19 pandemic has negatively impact on immunization provision. Reduction of face-to-face medical visits, including routine immunizations, along with national lockdowns and patients concern due to COVID-19 fear have probably strengthened immunization disruption, as recent investigations have shown.28 Consequently, if maintained overtime, this situation may create pockets of susceptible individuals. Hence, identification of HAV seronegative individuals through active recruitment and the use of recalls must be a priority. Besides, to increase adherence to vaccination circuit new strategies are warranted, such as increasing the number of consultations and making schedules more flexible, while strengthening vaccination in a single act, which would acquire an additional value in times of health system overload.

This study may have some limitations. Firstly, it is a local study that may not reflect the situation in the rest of the country. However, in a large proportion of Spanish facilities, HIV and vaccination consultations are not unified. In any case, multicenter studies would be needed to confirm these findings. Secondly, part of the study was carried out in the context of the SARS-CoV-2 pandemic. This situation could have led to greater delays in the appointment at the unit responsible for vaccination or even contributed to lower attendance at the visits scheduled by this unit. However, this fact would be in line with our results, reinforcing the need for strategies that promote adherence to these consultations. Besides, as far as we know, information about the causes of HAV non-immunization among PLWH and vaccinations programs outcomes beyond outbreaks were missing. Therefore, new insights in this regard are provided herein and this is a strength of the present study.

In summary, in our setting, a significant proportion of PLWH are not immune to HAV infection and are therefore at risk of acquiring this infection in future epidemic outbreaks, especially MSM. A program based on referral to the vaccine delivery unit yields poor results, mainly due to program adherence failures. This situation could be influenced by the long waiting time to the first assessment, which might have been extended in the context of SARS-CoV-2 pandemic. Thus, a simplified follow-up strategy, with unified HIV controls and vaccination implementation, could be crucial to improve HAV immunization rates among this high-risk population.

Juan Macias (J.M.) and Anaïs Corma-Gómez (A.C.G.) had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.

Study concept and design: Juan A. Pineda (J.A.P.) and A.C.G.

Acquisition, analysis, or interpretation of data: J.M., J.A.P., A.C.G., Luis M. Real (L.M.R.), Alejandro González-Serna (A.G.S.), Noemi Oliver (N.O.), Jesús Ortega (J.O.), Pilar RINCON (P.R.), Elena Rodríguez-Pineda (E.R.P.), Marta Trigo-Rodríguez (M.T.R.).

Statistical analysis: J.A.P., J.M. and A.C.G.

Drafting of the manuscript: J.M. and A.C.G.

Critical revision of the manuscript for important intellectual content: A.C.G., J.A.P., J.M., L.M.R., M.F.F., A.S., A.G.S., N.O., J.O., P.R., E.R.P., M.T.R.

Obtained funding: J.M., A.C.G and J.A.P.

Study supervision: J.A.P. and J.M.

This work was supported in part by the Instituto de Salud Carlos III (Project “PI16/01443”) integrated in the national I+D+i 2013-2016 and co-funded by the European Union (ERDF/ESF, “Investing in your future”), by the Spanish Network for AIDS investigation (RIS) (www.red.es/redes/inicio) (RD16/0025/0040), as a part of the Nacional I+D+I, ISCIII Subdirección General de Evaluación and the European Fund for Development of Regions (FEDER). JAP has received a research extensión grant from the Programa de Intensificación de la Actividad de Investigación del Servicio Nacional de Salud Carlos III (I3SNS). ACG has received a Río Hortega grant from the Instituto de Salud Carlos III (grant number CM19/00251).

ACG has received lecture fees from Gilead and Abbvie. JM has been an investigator in clinical trials supported by Bristol-Myers Squibb, Gilead and Merck Sharp & Dome. He has received lectures fees from Gilead, Bristol-Myers Squibb, and Merck Sharp & Dome, and consulting fees from Bristol Myers-Squibb, Gilead, and Merck Sharp & Dome. JAP reports having received consulting fees from Bristol-Myers Squibb, Abbvie, Gilead, Merck Sharp & Dome, and Janssen Cilag. He has received research support from Bristol-Myers Squibb, Abbvie and Gilead and has received lecture fees from Abbvie, Bristol-Myers Squibb, Janssen Cilag, and Gilead. The remaining authors report no conflict of interest.