Using BCG to Protect Senior Citizens During the COVID-19 Pandemic

INTRODUCTION One of the most recognized consequences of aging is a decline in immune
function, so-called "immunosenescence". Vaccination is the most effective prophylactic
intervention for infectious diseases, but due to immunosenescence, the efficacy of vaccines
decreases with increasing age.

Due to immunosenescence, severe infections are more common in the elderly. Not least during
the COVID-19 pandemic, it has become clear that elderly people are particularly susceptible
to severe COVID-19. Strategies to strengthen senior citizens' immune system are urgently
warranted.

Bacillus Calmette-Guérin (BCG) was developed as a childhood vaccine against tuberculosis, but
our group has shown that it can protect against death from other infections, i.e. it has what
the investigators have called non-specific effects (NSEs). In clinical studies, BCG
vaccination was associated with decreased child mortality, mainly as a result of reduced
neonatal sepsis and respiratory infections. In a meta-analysis commissioned by the World
Health Organization (WHO), BCG was associated with a 42% (95%CI: 24-55%) reduction in child
mortality.

NSEs of BCG are not limited to children. An Indonesian trial with 34 subjects aged 60-75
years reported that compared with placebo, consecutive BCG vaccination for 3 months reduced
the incidence of acute upper respiratory tract infections by 80% (95% confidence interval
(CI)=22-95%). In a very recent clinical trial in Greece, BCG vs. placebo to senior citizens
at discharge from the hospital was associated with a significant decrease in time to first
infection (p: 0.035). The incidence of new infections was 42.3% (99% CIs 31.9 53.4%) in the
placebo group and 25.0% (95% CIs (16.4-36.16%) in the BCG group; most of the protection was
against respiratory tract infections (odds ratio 0.20; p: 0.001). No difference in the
frequency of adverse effects was found between groups. These data show that BCG vaccination
is safe and can protect the elderly against infections.

Immunological studies have now provided an explanation for the observed NSEs of BCG: BCG
induces epigenetic and metabolic reprogramming of innate immune cells such as myeloid cells
and Natural Killer cells, leading to an increased antimicrobial activity, a process termed
'trained immunity'.

In a pilot study the investigators recently investigated whether BCG could induce innate
immune training in seniors above 50 years of age in Guinea-Bissau. Two months after
vaccination, BCG recipients had increased release of the pro-inflammatory innate cytokines
interleukin (IL)-1β, IL-6 and TNF-α to non-specific stimuli. These effects were more
pronounced among those with a positive Quantiferon test at baseline. Thus, BCG vaccination
can induce a 'trained immunity' phenotype in older adults. including previously Mycobacterium
tuberculosis exposed individuals.

Currently, numerous clinical trials are investigating the effect of BCG as a prophylactic
treatment for health care workers of all ages. No results of these trials are available yet,
but ecological analyses have suggested that countries with a functioning BCG vaccination
program have lower COVID-19 mortality. Furthermore, in a very recent follow-up study of three
cohorts of healthy volunteers who either received BCG in the last five years or not, BCG
vaccination was safe and not associated with increased incidence of symptoms during the
COVID-19 outbreak in the Netherlands. In fact, BCG vaccination was associated with a decrease
in the incidence of sickness during the COVID-19 pandemic (adjusted odds ratio 0.58, P <
0.05).

The investigators hypothesize that BCG vaccination may strengthen the immune system of the
senior citizens and may (partially) protect against getting infected and/or experiencing
severe morbidity due to infections with SARS-CoV-2 and other infectious pathogens.

OBJECTIVES Primary objective: To reduce senior citizens' risk of acute infection during the
COVID-19 pandemic. Secondary objectives: To reduce senior citizens' risk of SARS-CoV-2
infection during the COVID-19 pandemic. To reduce senior citizens' risk of self-reported
respiratory illness during the COVID-19 pandemic.

HYPOTHESIS BCG vaccination of seniors will reduce the risk of acute infection by 25% over a
period of 12 months.

PROJECT GROUP Christine Stabell Benn (MD, DMSc), Peter Aaby (DMSc), Anne Marie Rosendahl
Madsen (MD, PhD student), Mette Bliddal (PhD), Sebastian Nielsen (MSc, statistician), and
Frederik Schaltz-Buchholzer (MD, PhD), all from University of Southern Denmark. Lene Annette
Norberg (MD, PhD) and Anne Grete Pilgaard from Municipality of Odense. Mihai Netea (MD,
DMSc), Radboud Medical Centre, Nijmegen, The Netherlands. Tyra Grove Krause (MD, PhD),
Statens Serum Institut.

METHODS Study design and follow-up A randomized placebo-controlled clinical trial.
Participants will be followed for 12 months post-randomization with respect to illness,
medical contacts, use of antibiotics, hospitalization and death. The follow-up will take
place both through self-reporting, and through the Danish National Registers. Information on
hospitalizations for infections and other medical conditions will be obtained through
Denmark's National Patient Register and information on use of antibiotics from the Danish
Prescription Register. Vaccination history will be acquired from the Danish Vaccination
Registry at Statens Serum Institut. Furthermore, data on testing for SARS-CoV-2 and results
will be obtained via the local department of clinical microbiology.

Since the Investigational Medicinal Product (IMP), the BCG vaccine, is used in this study on
another indication than the one it has been approved for, this is classified as a phase III
study.

Participants will be randomized 1:1 to receiving an intradermal BCG vaccine or placebo.
Participants who are randomized in the active arm will receive a BCG vaccine (BCG-Denmark, AJ
Vaccines, http://www.produktresume.dk/AppBuilder/login.html). The BCG vaccines will be
handled in full compliance with the requirements of the Summary of Product Characteristics
(SPC). Placebo will be 0.1 ml sterile 0.9 % NaCl, which has a similar color as the
resuspended BCG vaccine.

All participants will receive one injection at inclusion. No further treatment of study
participants will take place. BCG will be administered in the upper arm, intradermally, 0.1
ml of the suspended vaccine. Placebo will be administered in the upper arm, intradermally,
0.1 ml of sterile 0.9 % NaCl solution.

STUDY PROCEDURES The trial will be presented at information meetings and in relevant media,
local newspapers and homepages and newsletters of the activity houses.

Citizens wishing to participate will be given written information and will be booked for an
interview.

Day of inclusion (day 0) Study physicians, who are trained in good clinical practice and in
providing intradermal vaccines, will be responsible for the inclusion of study participants.
Informed consent will be obtained from all participants. Background information on
participants will be collected in an electronic case report form system (REDCap). A blood
sample of 5 ml will be drawn for subsequent testing for SARS-CoV-2 antibodies.

Randomization and blinding The study will be individually randomized, and placebo controlled.
Randomization will be done using the REDCap tool with stratification per sex and age groups
(65-74/75+ years of age) in randomly selected block sizes of 4 and 6.

The participant will be blinded to the treatment.

Day of inclusion till end of trial A short electronic questionnaire regarding health,
symptoms and potential side effects will be sent to the participants biweekly.

End of trial Participants are asked to fill in a final questionnaire. A blood sample of 5 ml
will be drawn for subsequent testing for SARS-CoV-2 antibodies.

The end of the trial is defined as whichever comes latest: The last participants last
registration in the online data collection, or 365 days. When the study is ended, all
participants receive an email with information about the intervention that they have received
(BCG/placebo).

STATISTICAL ANALYSIS The primary endpoint "acute infection" will be analyzed as a recurrent
time-to-event using an Andersen-Gill Cox proportional hazards regression model with time
since inclusion as underlying time scale. Analyses will be done stratified by the block
randomization variables sex and age group.

The secondary endpoint self-reported respiratory illness will be analyzed the same way as the
primary endpoint. The other secondary outcome verified SARS-CoV-2 infection will be analyzed
in a standard Cox proportional hazards model, but otherwise as described above.

When applicable (i.e. in the event that one or more participants have died during the
follow-up period) a competing events analysis will be performed in addition (Fine-Gray
model).

SAMPLE SIZE CALCULATION With an expected incidence of "acute infection" of 20% the trial can
show a 25% reduction in the risk of acute infection in the intervention group versus the
placebo group by including a total of 1890 individuals, 945 individuals in each group.