Good morning, and welcome to Moderna's conference call. At this time, all participants are in a listen only mode. Following the formal remarks, we will open the call up for your questions. Please be advised that the call is being recorded. At this time, I'd like to turn the call over to Lavina Talukdar, Head Investor Relations at Moderna. Please go ahead.
Thank you, operator. Good morning, everyone, and thank you for joining us on today's call to discuss phase I interim analyses from our first seasonal flu program, mRNA-1010. You can access the press release issued this morning as well as the slides that we will be reviewing by going to the investor section of our website. On today's call are Stéphane Bancel, our Chief Executive Officer, Stephen Hoge, our President, and Jacqueline Miller, Senior Vice President, Head of Infectious Diseases. Before we begin, please note that this conference call will include forward-looking statements made pursuant to the safe harbor provisions of the Private Securities Litigation Reform Act of 1995. Please see slide two of the accompanying presentation and our SEC filings for important risk factors that could cause our actual performance and results to differ materially from those expressed or implied in these forward-looking statements.
With that, I will turn it over to Stephen.
Thank you, Lavina. Good morning and good afternoon, everyone. We're excited this morning to share an update on our quadrivalent influenza vaccine, mRNA-1010. I'd like to start with a little bit of an overview of the influenza epidemiology and current market landscape, and then a reprise of our vaccine strategy for the influenza market. I'll then turn it over to Jacqueline, who will walk you through some of the interim analysis from our quadrivalent mRNA-1010 program before Stéphane closes with some of his closing remarks. On slide four, just briefly to remind you, the seasonal influenza market is driven by epidemics that occur every year, which vary substantially in severity and generally cause a respiratory syndrome with the symptoms and complications described on the right.
Worldwide, influenza leads to 3-5 million severe cases of flu every year and between 300,000-600,000 flu-related respiratory deaths annually. About 8% of the U.S. population will experience symptoms every year, with approximately 500,000 hospitalizations and up to 50,000 deaths each year. Peak flu activity tends to come in the fall and winter in temperate climates, and it increases the number of outpatient visits, urgent care visits, and hospitalizations dramatically. Now on slide five, just to remind you, there are two major surface glycoproteins on the influenza virus, hemagglutinin and neuraminidase. Hemagglutinin is the primary target of current influenza vaccines. It is, as you can see from the image, the major surface glycoprotein and experiences significant antigenic drift and antigenic shift.
It is a key component of both influenza A and B strains that drive the majority of the pathogenicity in humans. Neuraminidase is a second antigen also present, although less frequently on the surface, and it is variably included in some influenza vaccines currently. It does experience a lower rate of antigenic drift compared to the HA head, and independently, antibodies to neuraminidase have been shown to correlate with protection. On the next slide, just to remind you of the disease burdens, influenza A strains are the major driver of influenza-related hospitalizations and deaths. As evidenced on this image, which is adapted from a recent publication looking at the drivers of hospitalization and mortality per 100,000 people in the United Kingdom, you can see that influenza A on the left leads to the majority of hospitalization and death.
That is more pronounced in older populations with a smaller amount, fortunately, in younger populations, particularly those under the age of four. Influenza B, which are present in the vaccines and do circulate, does not lead to a substantial amount of hospitalization or death, as you can see here. Recent studies of vaccine efficacy over the last couple of decades have found that the average VE or vaccine efficacy against H3 strains, one of the two strains in influenza A, has been lower, approximately 33% against illness. That is compared to approximately 61% for H1N1 and 54% against the influenza B strains. Lower vaccine efficacy against H3 strains may contribute to the higher medical burden from the influenza A family. Now next slide. Briefly, an overview of the current market of vaccines is represented here.
In the U.S., the estimated average economic burden of flu is approximately $11 billion each year. Now, there are 500 million doses of seasonal influenza vaccines that are administered globally in 2019, and the currently approved vaccines are 40%-60% effective and face significant challenges from both strain mismatch and antigenic drift. An improvement in the vaccine efficacy has the potential, we believe, to substantially increase this already quite large market. Now improving that efficacy, I'd like to talk to you for a moment on slide eight. If you look over the years at seasonal influenza virus vaccine effectiveness in the United States using data from the CDC, you will note, as these gray bars denote here, the variability in the efficacy of the vaccine against influenza. Approved vaccines vary between 40%-60% efficacy in well-matched years.
That efficacy can drop substantially into the 10%-20% range in years where there is substantial strain mismatching. Now, the gray bars here represent the efficacy of the vaccine in each year and each season, as denoted underneath. What you see in the purple line is the amount of strain matching that happened in the vaccine. As you'll note, in substantial mismatch years, efficacy significantly declines as low as 19%, for instance, in the 2014-2015 season. Now, the last point I'd like to make is the prevalent strains change dramatically year-over-year, as denoted by the pie chart at the bottom of each of these years. In some years, H1 is a predominant strain.
In other years, H3 is a predominant strain, and the B strains make up a minority in any given year of the then-circulating prevalent strains. The important nothing to note is that H3, H1, and the B strains all change in composition each year, and the amount of mismatching directionally correlates with the decreases in vaccine efficacy that are observed. The last thing I would note is that in the last four or five years, vaccine efficacy has been substantially lower, approximately between 29% and 48% across all of the then-circulating strains. If you look at the next slide, some of the reason for this may start to emerge. If you look at seasonal influenza virus vaccine effectiveness across the different strains, one thing to look at is what's happening in terms of global epidemiology. In particular, I'd like to focus on the H3N2 strain.
As evidenced here in this image from nextstrain.org, a resource we have all become familiar with through the COVID pandemic. The global circulating H3N2 virus strains over the last five years shows a dramatic amount of heterogeneity. In fact, data from Nextstrain shows that over the past six years, there have been co-circulation of multiple different clades of the H3N2 viruses each year. In fact, as you look to the right and you ask, at the beginning of the COVID pandemic, at the very beginning of 2020, before things were substantially disrupted epidemiologically for influenza, what was the most common strain in early 2020 for the H3N2 line? In fact, as you can denote, the most common strain was different across many of the largest countries in the Northern Hemisphere.
The U.K., Switzerland, United States, Japan, and Canada all had a slightly different strain that was more predominant. One of the challenges of the current vaccine regime is that a single clade is picked. Often, however, in the H3 category, it represents less than 40% of all circulating H3N2 viruses, creating a high likelihood of mismatch, at least in some countries. This, we think, represents one of the most significant opportunities for improving vaccine efficacy. Now, on the next slide, I'd like to remind you of the three legs of our strategy for seasonal influenza vaccines. The first is that we have moved forward with a quadrivalent vaccine, and that is a seasonal quadrivalent for flu vaccine mRNA-1010 using the WHO recommended strains.
This has a benefit of using an established regulatory pathway, although it will be subject to discussions that we have yet to have with regulators. The second is we're looking to expand coverage beyond quadrivalent flu vaccines. We announced today the two new development candidates in the mRNA-1010 line, mRNA-1011, and mRNA-1012, which add additional hemagglutinin antigens of the influenza A line, H3 or H1, to expand strain matching. This provides an enhanced antigen selection opportunity for public health officials and authorities and the potential for further regional variation to address any regional mismatches. The third pillar of our strategy previously announced is that we look to expand the immunologic breadth of our vaccines. This includes broader antigens, as we've already previously announced with the mRNA-1020 and mRNA-1030 vaccines.
We will accomplish this by adding neuraminidase antigens, which has the potential to improve immunity by targeting antigens that are more consistently conserved and subject to less antigenic drift over most years. With that, I'd like to turn it over to Jacqueline to walk you through some of the interim analysis data from mRNA-1010 quadrivalent flu program.
Thank you, Stephen. Good morning, good afternoon, good evening, everyone. My name is Jacqueline Miller, and I'm the Senior Vice President and Therapeutic Area Head for Infectious Diseases. It's my pleasure this morning to walk you through some of the safety and immunogenicity data from the first interim analysis of our phase I study, P101. On slide 12, you'll see a depiction of our clinical development timeline. We actually announced the start of our influenza vaccine development program last January. This has really been a very rapid development year for us in the influenza space. We conducted our IND-enabling studies between January and May, and then in July, we had our first participant dosed in our phase I study.
By September, that study was fully enrolled and now we're happy to share some of the initial results with you today. On slide 13, you see the depiction of the mRNA sequences that are included in mRNA-1010. mRNA-1010 is designed as a quadrivalent seasonal influenza vaccine with four mRNA sequences, which represent the four hemagglutinin molecules from the four strains selected each year by the WHO, FDA and other regulatory agencies. The transcripts each represent the full length of the hemagglutinin antigen, and these are membrane-bound proteins. If you go to the next slide, on slide 14, you see an overview of our ongoing study, P101, which has a phase I and phase II component.
Today, we're here to talk about the phase I component, and this study overall is evaluating the safety and immunogenicity of different dose levels of the messenger RNA influenza vaccine. As you can see in the box to the left, we investigated three dose levels of mRNA-1010 with 45 subjects in each group. The dose levels were 50 µg, 100 µg, and 200 µg, which were compared to a placebo control. Safety and immunogenicity have been assessed at day 29. We now are able to announce that we have selected our 50 µg dose as the lead candidate for conduct of our phase III studies. As the selection of a dose is always a balance between safety and immunogenicity, I'm going to review those data with you in detail in the following slides.
First, I'd like to talk about the phase II study that we have moved on to. In the phase II study, we have adjusted to the data that we have received in phase I, and we are looking to confirm that 50 µg dose. This time we are bracketing that 50 µg dose with 25 µg and 100 µg, and we will be comparing to a licensed flu competitor. This study will certainly give us more precision in our safety and immunogenicity estimates as there are 150 subjects in each group. Now let's jump into the data on slide 15.
What you see on this slide are the solicited local adverse events, and these are the aggregated reporting rates of injection site pain, injection site erythema, injection site swelling, and axillary or underarm tenderness and swelling. Very similar safety reactions to those you've become used to from our reports on mRNA-1273. You'll see that the data are presented by the younger cohort and older cohort. We do this because the safety profiles can differ between age groups. You see in the younger cohort, which is over 18 but less than 50 years of age, we have between 21 and 23 subjects per group that received mRNA-1010, and similar numbers in those who are over 50 years of age. The 50 µg data have been highlighted in the pink box on both tables.
Overall, we see reactogenicity that was tended to be lower in the older age group, but showed reporting rates of 82.6% in the younger group and 63.6% in the older group. The majority of these reactions were injection site pain, and axillary swelling and tenderness were also commonly reported, although the sample size is really quite low and we expect additional precision in our phase II study. Please note that there were no grade 3 events reported at this dose level in the younger age cohort. There was only one grade 3 event in the over 50-year-old group. No grade 4 events were reported in the entire study.
One final point to leave you with, we had 20% of subjects in both groups who received a saline placebo report adverse events, including one grade 3 adverse event in the older age group. Now on slide 16, let's look at solicited systemic adverse events. And again, you see the 50 µg box highlighted in pink. There were reported rates of any events, 78.3% of younger adults and 54.5% of older adults. The most commonly reported reactions were fatigue, myalgia, arthralgia, and headache. An adverse event profile that we have seen consistently with respect to the mRNA vaccine platform. Again, grade 4 events were not reported in this study.
We saw grade 3 events in three subjects in the younger age group and two subjects in the older age group. Once again, I would point out that we had approximately 1/3 of subjects in the placebo group in both age cohorts reporting systemic adverse events, including one subject reporting grade 3 adverse events in the older age cohort. Now on slide 17, let's switch gears to the immunogenicity data. I'm going to present to you the immunogenicity data first in the younger age cohort and then in the older age cohort. On this slide, you see the geometric mean titers in terms of hemagglutinin inhibition for the four influenza strains in the younger age cohort. The 50 µg dose is the one in the blue bars.
What you can see is that, pre-vaccination, antibody titers were relatively high, so the geometric mean titer was around 40 for influenza A titers, A strains, or, H1N1 and H3N2, and was actually closer to 160 for the influenza B strains. What you can see in the 50 µg group is that, there was relatively little discrimination between different dose levels. That really is the rationale to continue to explore even lower doses. At the lowest dose level, we see geometric mean titers that were around 530 for the influenza A strains, and 261 for the Victoria lineage and 467 for the Yamagata lineage. I would point out that the starting antibody titers were extremely high for the influenza B strain.
For the influenza A strain, we saw increases that were reassuring to us as we compared to results from recent other clinical trials, which I'll explain in subsequent slides. Now please go to slide 18, where you will see the data in terms of the older adult cohort for geometric mean titers. Once again, the 50 µg dose are in the blue bars. We see a similar pattern in pre-vaccination titers for the older age group, with approximately titers of 40 for the influenza A strains and approximately 80-160 for the influenza B strains.
Once again, the post-vaccination geometric mean titers had little dose response between the three dose levels with HAI titers of 263 for H3N2, 310 for H1N1, 215 for Victoria, and 305 for influenza B/ Yamagata. If you go to the next slide, you now see younger adults in terms of geometric fold rises or one of the key regulatory criteria for licensure and seroconversion rates. Let's start with the seroconversion rates on the right. Once again, in blue you see the four influenza strains with seroconversion rates of 77%-82% for H1N1 and H3N2 respectively, and for 18% in the Victoria strain and 41% for the Yamagata strain.
This translated into fold rises of about 2.5-3 for the influenza B strains, and importantly, in the selected dose level, a geometric mean fold rise of 8-fold for H3N2 and 10-fold for H1N1. Now, if you look in the older adults, the seroconversion rates were 57% and 81% for H1N1 and H3N2, and were 43% and 10% for Yamagata and Victoria respectively. Again, titers were 2- 3-fold for the influenza B strains and 6-fold geometric mean fold rises for the influenza A strains. What does this mean on slide 21 with respect to comparison to other influenza vaccines?
We had the opportunity to participate in a clinical trial sponsored by Sanofi Pasteur this past summer investigating the concomitant use of Fluzone High-Dose, a vaccine intended for the older adult age cohort with mRNA-1273. The reason why these are important data is because they represent testing of an influenza vaccine during a time when the seroprevalence of the various influenza strains was similar because it was taken at the time that the seroprevalence was represented by pre-vaccination titers in our study. Also because the strains that were used were the same, except for a difference in the H3N2 strain. This really allowed us to compare, although must compare cautiously because the assays utilized are different and these data were collected in different studies.
Nonetheless, we see some similar patterns to what I've just shown you. On this slide, you see the older adults with mRNA-1010 on the left, Fluzone on the right. If you look at the H1N1 titers, you see larger seroconversion rates with approximately comparable geometric mean titers around the level of 320, with 6-fold rises in H1N1 and H3N2, and an 8-fold rise for H1N1 for Fluzone, but below a 4-fold rise for H3N2, one of the strains that causes the most morbidity and mortality in older age groups. If you look at the influenza B strains in terms of geometric fold rise, in the Fluzone High-Dose arm, results were also less than four.
We think it's going to be critically important to compare the results in our phase II study to the licensed comparator, and that will really give us confidence in our dose selection for the phase III study. Let me now give you an overview of the next steps we will take in clinical development. As I mentioned, our phase II study is fully enrolled with 500 participants. There are going to be three dose arms at 25, 50, and 100 µg with 150 subjects in each arm. We are looking to compare to a licensed U.S. seasonal flu comparator. The interim analysis data are expected early in 2022, and in this study we'll be testing the Northern Hemisphere strains for the 2021-2022 influenza season.
In terms of phase III, we're continuing our study preparations, and importantly, now that we have clinical data, are prepared to discuss pathway to licensure with regulatory agencies. We are looking to talk not only with the FDA, but regulatory agencies worldwide. The active comparator arm in the phase III study will allow us to assess non-inferiority, and we expect to start this study in 2022. On slide 23, the key takeaways from this presentation are that the mRNA-1010 phase I results indicate that the lowest dose tested achieves high geometric mean titers and reaches some of the immunogenicity endpoints which have been set by regulators for current flu vaccines. The mRNA-1010 shows similar immunogenicity, at least in a side-by-side comparison of not identical studies as a current enhanced flu vaccine.
There's no dose response observed between the 50, 100, and 200 µg , and there may be a potential in the evaluation of lower doses. In terms of preparations for phase III, our phase II study, which evaluates 25, 50, and 100 µg, is fully enrolled. We expect to report interim analysis data in 2022, and the active arm comparator will allow for the head-to-head comparison. These phase III data are really critical because they will enable us to feel even more confidence in our phase III dose selection. With that, I'll conclude and hand over to Stéphane Bancel to finish the presentation.
Thank you, Jacqueline and Stephen. Good morning or good afternoon, everyone. With today's new flu clinical milestone, we have one more component of our pan-respiratory annual booster vaccine. You recall our RSV vaccine is already in phase II/III. As you know, this is our company number one priority. We now have a line of sight to an annual booster that could contain COVID, plus flu, plus RSV in a single shot. Next slide.
Because the modularity of our mRNA platform, don't think of mRNA-1010 as our ultimate best flu product. We think of mRNA-1010 as a first step into a fast iteration development cycle. mRNA-1010 is our first step toward regulatory approval, and it already looks non-inferior to the most efficacious flu vaccine on the market. As Stephen explained, we are working to expand flu strain coverage with mRNA-1011 and mRNA-1012 , adding more HA antigen like H3N2 or H1N1.
We're also including immunologic breadth by adding NA antigens to HA antigens. Our vision for pan-respiratory annual booster vaccine is a combo of COVID plus flu plus RSV with best-in-class performance with expanded coverage and immunologic breadth on flu. One of the additional uniqueness of our strategy is we can adapt the annual booster to a country or region of the world. Why would Canada use an Australia flu strain if we can incorporate the relevant strain to protect people in Canada? We believe a pan-respiratory annual booster vaccine will present a large opportunity for Moderna. We believe we can create a lot of value for the healthcare system and should be able to capture premium pricing. A single vaccine to cover multiple viruses, starting with the sum of the parts, COVID cost, flu cost, RSV cost, compliance. With a pan-respiratory annual booster, we drive value for payers.
Convenience to the consumer. Everybody will prepare one shot, two, [three] shots every fall. Of course, reduction in vaccine administration costs in healthcare system. As you know, in many countries it is more expensive to administer the vaccine than the current cost of a COVID-19 vaccine. We also believe that post-COVID, the pan respiratory market will be much larger than the flu market. We believe Moderna could be the first company to market with a COVID plus flu and then a COVID plus flu plus RSV booster. Millions of people suffer each year of viral respiratory infection. We get disease, some of us end up hospitalized, and the most unfortunate die. We believe we have a unique opportunity to have a profound impact to prevent these diseases, these hospitalizations, and these deaths. Our strategy is very clear.
We as a company are laser focused on execution, and this focus is well exemplified by the Moderna team having already enrolled the phase II study for flu. We have a unique opportunity to profoundly transform disease prevention and help hundreds of millions of people around the planet each year. With this, we'll be happy to take your questions now. Thank you.
If you want to ask a question, please press star then one. If your question has been answered and you'd like to remove yourself from the queue, please press the pound key. Our first question comes from Salveen Richter with Goldman Sachs. Your line is open.
Good morning. Thanks for taking my questions. Two questions for you. When you look at the younger adults and older adults, you observed a 3-fold GMFR change for the B/ Yamagata strain and a 2-fold for the B/ Victoria from baseline versus higher fold for other strains. Why might that be the case? Do these strains have higher prevalence, which could lead to higher titers from pre-exposure? Maybe you could just help us understand also what's driving the confidence that a lower dose may work.
Thank you for the question. Looking maybe just at the younger adults, we saw 8- 10-fold rises in GMFR for the influenza A. As I tried to cover in the epidemiology, that is where the burden of disease is, particularly in older adults. There, where we saw [8- 10-fold] in younger adults and the 6-fold GMFR rise in the older adults, we think it's going after the current epidemiology, the morbidity and mortality. Influenza B, as I covered, is predominantly seen as a disease burden in younger patient populations, actually children. In that case, it has generally been seen, as Jacqueline presented, that boosting in the influenza B category, for instance, with Fluzone this past fall, GMFRs and titers have been slightly lower.
As you noted, I would also note that the baseline titers are higher, and so many baseline titers are well above 1:40, both in our study and in the Fluzone HD study that Jacqueline presented, you know, often above 1:160. It's just a simple function of math that you can't get to a higher boosting if you start with a higher baseline titer. Now the question you ask about why is that? I think it's a fair question about whether there's a burden of disease or whether influenza B is circulating pretty regularly in adult populations without creating disease and therefore maintaining higher titers.
It could also be a function of just the hemagglutinin, the antigens on those viruses, and particularly the two influenza B strains that were most recently included in the vaccines. That may change as other influenza B strains are changed, so that may change year over year and really be a function of the antigen. I think the evidence for that could come from the fact that both the enhanced premium Fluzone HD vaccine and Moderna saw the similar type responses in terms of the boosting of the GMFR against those viruses. Now lastly, on your question of 25 µg. We did not see for any of these antigens as a significant dose response, which I think leads us to conclude that we can go even lower than 50 µg if we were to choose to.
Now, this is looking though at neutralizing antibodies, and one of the other considerations that you always wanna have is obviously boosting T-cell responses and other forms that are not captured in the measurements that we're doing at this point in just this phase I study. In order to be sure about that choice, as Jacqueline said, we really wanna evaluate the 25 µg dose, but also the 50 and 100 µg dose in the phase II against a licensed comparator. That will probably be the first time that we have a real direct comparison head-to-head in that study. It's also been powered to 150 per arm, which will give us much more consistency in terms of the data and the individual performance.
It is possible that in looking at that data we will see that 25 µg is more than enough as a dose, and ultimately we think we wanna have a look to know for sure. As Jacqueline said, our ingoing assumption is that the 50 µg dose will be more than sufficient to achieve very high immunogenicity and at least to first approximation, an immunogenicity response that looks as good as the best enhanced premium vaccine on the market today.
Thank you.
Our next question comes from Matthew Harrison with Morgan Stanley. Your line is open.
Great. Good morning. Thanks for taking the question. I guess two for me. First on dose response. You haven't discussed seroconversion. It does look like with the exception of H3, you do have somewhat of a dose response on seroconversion. Maybe you could just discuss how that goes into your thinking when thinking about dose.
Just on overall titers and fold increases that you can achieve, could you maybe comment on how you're thinking about that with additional constructs or, you know, or adding different antigens and just your thoughts on the ability to potentially increase the folds that you can achieve with this? Thanks.
Thanks, Matt, for the question. On seroconversion, I think you're correct that seroconversion rates were technically a little bit higher at higher doses, particularly I think in the older adults, if you look at it in the H1N1 line. That wasn't consistent. In fact, in the H3N2 seroconversion rates, you'll see that wasn't the case, and we had very high, you know, 81% at 50 µg seroconversion. I think the short answer is we need a larger N in the study to be able to resolve whether those are in fact differences that are real. There are hints in a couple of places, for instance, in H1N1, as you point out, but we wouldn't make the decision based just on this data.
We'll look in the phase II to increase the N and try and sharpen that, and we'll know for sure whether we think there's a benefit there. The thing I would say about addition of antigens is that, you know, part of our strategy has always been in vaccines and including in the flu vaccine program, is to move forward with a product with the quadrivalent vaccine, the mRNA-1010, that is, we think is hopefully going to be as good or better as what's out there in the enhanced vaccine market. We're on that path with this data today. That is just the entry point, and what we would wanna do over time is add, even in that mRNA-1010 framework, additional antigens.
We said with the mRNA-1011 and mRNA-1012 programs is particularly additional HAs for the influenza A lines. Why does that matter and relate to the seroconversion? We think additional strain coverage in both H1 and H3 will improve matching and potential coverage of circulating strains and deal with some of the pressure that gets put on the virus circulating intraseason as a result of vaccines. There will perhaps be some benefit, cross-benefit to increasing the number of antigens that we put in the influenza A stage. We'll have to look at that, but that would also increase seroconversion rates.
A question around, to tie the two halves of the question together, around whether we should explore higher doses to push to even higher, north of 80% seroconversion rates, we actually think, first, we need to look at that from a dose perspective and make sure there is a difference there. That second, if we do wanna go down that path, does it make more sense to add more diverse antigens to improve that across a range of strains, or does it make sense to do it through dose escalation against individual strains? We will evaluate that as part of the mRNA-1010, mRNA-1011, and mRNA-1012 programs.
Our next question comes from Michael Yee with Jefferies. Your line is open.
Hi, thank you. We had two questions. One is maybe a high-level strategy question, which is to hear you clearly say whether you're similar or differentiated to the high dose, you know, high efficacy vaccines, and how important it is just to get the product to market and to really just try to enhance all of this stuff in the future. As part of that, the second question is the combinability question, which I think has always attempted to be a differentiation. When you look at your high doses here, there is, you know, clearly some differentiation in terms of more side effects.
How confident are you that you could actually combine a couple of different diseases and get up to 150 µg and still be okay on side effects as a combined vaccine? Thank you.
Thank you, Michael. Both great questions, let me try and cover them first. As a strategy matter, just to be clear, I think you asked the question about whether we are superior, inferior to Fluzone HD. Obviously, the data is not head-to-head. We can't make a direct comparison. We present it as a benchmark, but only, you know, as guidance. I think the best place we will start to have data, as Jacqueline said, is from a phase II study where we include an active licensed comparator, you know, head-to-head in the same population, at the same time, against the same strains in the same assay. That is an important caveat.
As a strategy point, as I tried to lay out at the beginning, our view on mRNA-1010 from the beginning has been that we want to aim at being as good as the best enhanced vaccines in the market, those that achieve premium pricing for older adults like Fluzone HD does with the highest market share in the U.S. That we wanna use that as the starting point for what we then go build off of for our overall flu franchise.
The reason we wanna aim at that right now is many of the things that we're talking about doing in our platform, for instance, adding additional clades in the influenza A line, the mRNA-1011 and mRNA-1012 programs, and adding different additional antigens like the neuraminidase enzyme to broaden protection, those are not precedented in the current market. Obviously for that reason, don't have the benefit of previous regulatory pathways and clear guidance around that. In order to work within the existing framework, we are prioritizing moving quickly forward with the mRNA-1010 program, a quadrivalent influenza vaccine.
Ultimately, hopefully going down more established regulatory pathways more quickly while we bring in the second, third, and subsequent generations of product improvements that we really do think will drive efficacy improvements and close some of the gaps from mismatch and other challenges in the flu market. Now, why push forward with that mRNA-1010 product as rapidly as we are? First, we think that there's an opportunity to in the enhanced vaccine space for an mRNA vaccine. Second, as Stéphane said. Our overall strategy is eventually do combinations, and maybe to get to your second question, which is we do believe that there's a substantial value to be created by combining a very strong influenza vaccine, seasonal influenza vaccine platform with mRNA-1010, with COVID and eventually COVID plus RSV boosters.
We think that will manifest itself not just in the, you know, combination with ... we believe a very strong COVID booster, which is mRNA-1273 and subsequent generations of that product, but also to facilitate better compliance and lower cost for administration healthcare systems, which no doubt will be an issue as we go forward. We're big believers in that, and that's ultimately the role the mRNA-1010 program plays for us. We want to be as good as we're seeing with enhanced vaccines with that program, and then what we want to do is do combinations, and then use mRNA-1010 as the foundation to build even taller with the addition of additional variant antigens.
mRNA-1010 also does have the opportunity to do more regional tailoring, as Stéphane described, because of the, you know, we've all seen the flexibility of mRNA manufacturing processes in, for instance, in terms of the variants and the response to COVID. That does provide an immediate opportunity to also create value where we do see regional sub-optimization in the selection of antigens today. Now, on the question of reactogenicity, I take your point on the influenza vaccine study presented here, mRNA-1010, which is that we did see a trend towards higher reactogenicity at higher doses.
That is consistent, and although these are low-end, generally, you know, as Jacqueline pointed out, we saw quite high reactogenicity even in the placebo arm, which is probably just a function of in these phase I studies, you work really hard to solicit that day seven reactogenicity. You put in place tools that are even, you know, more aggressive because we wanna make sure that we characterize and understand it. It makes it very hard to compare that reactogenicity against other standards until you do something like we're doing in our phase II, which is you bring in an active comparator control, and therefore you really do know what you're up against and how it compares.
Subject to that data, I don't know for sure where we are on that spectrum, but I do agree with the general trend that we've seen, which is that higher doses do elicit those sorts of increased solicited reactogenicity tolerability questions over the first week. What drives that? The ultimate answer is we'll have to run the combination studies and show that we do not see any sort of synergy or additive effect as we go combine vaccines and boosters across many different strengths. That data will be dispositive. We are running those experiments as we speak with, we are running combination studies with approved vaccines as we speak right now for the mRNA-1273 program.
What we will really need to do is show that combinations, for instance, our mRNA-1073 program, which is a combination of flu and a COVID booster, show similar, comparable or better, but we have to evaluate the reactogenicity in that vaccine context. Most of the reactogenicity I think you see here, and most of the reactogenicity you see as we increase doses in our vaccines is we believe related to the antigens. In particular, as you push up in doses, you tend to see higher responses to the antigens, and not specifically to the technology, the mRNA and the LNP. As evidence for that, I would say that you see this emerge in different dose levels across different vaccines and for different dose frequencies, right?
First dose versus second or third dose in our CMV vaccine. I think what I would say in summation is I don't think we can look at a single number and make that hard determination today about whether 200 µg or 150 µg is gonna be the right answer. It is likely going to be a combination of what amount of antigens and what kind of immunogenicity against those antigens. We also think it's one of those things, therefore, that you have to evaluate clinically to know for sure.
we have reasons to hope and believe that we're gonna be able to combine things and achieve good protection, good boosting, as we would hope to do, and ultimately an acceptable safety and tolerability profile for an annual vaccine. I hope I answered that question.
I appreciate. Yep. No, that was very helpful, particularly on the reactogenicity points. Thank you very much.
Thanks, Michael.
Our next question comes from Gena Wang with Barclays. Your line is open.
Thank you for taking my questions. I have two. One is regarding efficacy, and the other is regarding safety. Thank you for sharing the data compared to Fluzone, but I think a much better cross-trial comparison should be seroconversion rates, and since those also will be the approvable endpoint and not the GMT fold change. When we pull out the data, and we did see, you know, your number showed quite high or better compared to a few strains, however, the B/ Victoria seems a little bit lower compared to Fluzone. Wanted to know that if your the for the 50 µg or each dose cohort, what's the ratio of each four sequences? Were these 1-1-1-1 ?
If that's the case, given overall low seroconversion rates for B/Victoria, do you need to increase RNA concentration for this strain? My second question is regarding the safety, and you did share some high level, the reactogenicity rates. But just wondering, you know, regarding only for your 50 µg cohort, how's your, say, injection site pain, headache, fatigue, myalgia compared to the other, flu or the Fluzone's rates? You know, we know that, you know, there's 47% for injection site pain, headache is 16%, fatigue at 11%, myalgia is 24%. That's for Fluzone, and how does that compare to your 50 µg? Was yours also comparable to Fluzone or was it higher?
Thank you, Gena, for both great questions. Let me try and take and then I'll invite Jacqueline to comment on anything I get wrong here. Just first on the seroconversion rate. Thank you for pointing that out. Seroconversion rate is also another important endpoint. If you look at the seroconversion rates, particularly in the older adults, and we focus a lot of our attention in the older adult population because, as we've talked about, that's where we think the pan-respiratory vaccine need is the most significant. If we look at those older adults, as you noted, in influenza A, we saw actually higher seroconversion rates than have been reported elsewhere, particularly in the H3 lineage, which is exciting.
As you noted, in the influenza B/Victoria strain, we saw slightly lower. We did see higher, I believe, when you compare against the published rates in the B/Yamagata strain. It is a bit of a mixed picture and strain specific, but we are pleased with the strength in influenza A, and obviously with Yamagata and we do know, as you said, that the lower seroconversion rates in Victoria. I would note, though, that generally people have reported quite low seroconversion rates for Victoria, particularly in the older populations, including for Fluzone HD. We have to be careful about over-interpreting whether there's those differences, any of them, candidly, are significant when we're dealing with such a low end in our current study.
The answer to that question really has to come from the phase II study, where we've increased that end quite dramatically at these dose levels and will help us drive that resolution. But on the specific question of the relative masses, it is 1-1-1-1 . So, you know, you can divide the dose mass by four and you get the representative mass for each of the strains. Again, that is consistent with approaches taken in general in the influenza vaccines. On the question of whether we think we should increase the mass for the B/Victoria strain.
You know, I think the answer there is complex because you might say if we were managing to that result, just the B/Victoria seroconversion rate, you might say, "Well, sure, why not increase it?" But that is, you know, maybe just solving for that one value. If you kind of pull back and say, well, where is the epidemiology? Where is the disease that will ultimately show up in a vaccine efficacy measure, and ultimately show up as a decrease in cases and hopefully then on the market, morbidity and mortality. It is really not in the Victoria strain that you would go do that. It would be continuing to focus on having the highest possible responses in influenza A.
I think a difficult challenge for us would be the decision to increase the mass in Victoria, and perhaps to do that at some expense to what's happening in influenza A. We really do believe the epidemiology says we should be focusing on H1 and H3. The last thing I'd say is because there's so much uncertainty about any of the current vaccine's ability to effectively boost or seroconvert against the Victoria strain, I think there's an open question as to whether or not that strain is actually, from an antigen perspective, suboptimal and whether, you know, a subsequent strain evolutions that happen for instance, in the coming year, might obviate that need. Again, these are strains that are getting updated in the current vaccine as we speak.
We're not at the present time planning to change that mix or ratios. We're gonna continue to look at additional strains of B as we go forward, and we're quite pleased to focus on the influenza A strain, where we think that the influenza A virus is where the opportunity for improvement on current vaccine is most important. Now, second question on the safety tolerability profile, I would really caution against direct comparisons. We have to provide that data, but we think it has to come from the phase II study where we have an active comparator. The reason I would say that is we are dealing with incredibly low numbers, you have 20 subjects. In many cases, when you're looking, you know, at a grade 2 or grade 3 difference versus placebo, it is a single subject difference.
We are soliciting quite substantially in a phase I study those results for that first week. You know, while you, there's a tendency, and I'm sure it will happen, for people who wanna sort of directly compare these numbers, we on our side, we're gonna wait till we have an active comparator in the same regimen before we feel like we can feel confident about it. I would point out what Jacqueline said before, which is, you know, the rates of solicited adverse events, both systemic and local, for the placebo were actually very high. You even saw grade three events in the older adults.
That just, you know, is again a sign of the types of solicited reporting that we're doing in these phase I studies to make sure that we're appropriately monitoring safety and tolerability and can be a confounder. We would not recommend direct comparison of that yet. Intra-study comparisons are acceptable, and that's where we conclude we don't think we need to go higher on dose towards 200 µg. There's no dose response. You know, we see more reactogenicity. Actually, between-study comparisons are really something we should hold off from doing and wait till the phase II results, particularly on something like tolerability, which is so subject to solicitation. That's why we're pleased that the phase II study is fully enrolled.
There's 500 people in it, 150 in each of the dose arms, which gives us good resolution. We have, as I said a moment ago, in the same study, blinded, an active comparator, which is a licensed influenza vaccine. That'll be the first time we really can make a comparison about tolerability.
Gena, it's Jacqueline. Maybe just to conclude on the immunogenicity point, I think it's important to remember that while immunogenicity is an important endpoint, it's not exactly the same as efficacy. There actually are licensed flu vaccines that have failed on the regulatory criteria from an immunogenicity perspective for B strains. In particular, Flublok, one of the most recently licensed vaccines.
They missed on their GMTs for the B/Victoria strain in one study and missed on seroconversion rates for H1N1 and B/Victoria in a second study. The other thing I would say is that, while the hemagglutinin inhibition antibodies are an important marker of how these vaccines work, there are also other elements that we know that messenger RNA as a platform are capable of inducing. We've seen, particularly in the mRNA-1273 program, the induction of cell-mediated immunity, and we will be studying that in our program as well. There may be components that we're not measuring here that will ultimately contribute to efficacy, and certainly with Flublok, despite missing some of those immunogenicity endpoints, it's a quite efficacious vaccine.
Thank you very much.
Our next question comes from Andrew Galler with Wolfe Research. Your line is open.
Hi. Thanks for taking my question. I just had two. First, I just wanna know if you had any data on an IGA response, mucosal immunity. Secondly, just on reactogenicity, I just wanted to see how you think the grade 3 events compare to licensed vaccines. Thank you.
Thank you for the question. First on the IGA, in this phase I study, we did not sample that. We do have data from our other respiratory vaccines, so actually specifically mRNA-1273, but we've also looked at it preclinically across a range, and we have seen mucosal immunity from this platform, now obviously both in humans through prevention of infection with SARS-CoV-2 and in animals, but not in this study. I think on the question of reactogenicity in comparison, yeah, I'd just reference that we're still dealing with a phase I study. It's a very different, small number of N, and so we would advise against direct comparisons 'cause it is ultimately a very self-selected group of people that we go look at this from in the phase I.
We need larger N to be able to make direct comparisons, we believe, in the future. The other thing I'd say is that obviously protocol's all different. This as a dosing regime is a single booster in the context of, you know, current flu, whereas some of our other vaccines we've studied, we've seen, you know, multiple doses and other regimes. It just makes direct comparison quite difficult.
Great. Thank you.
Our next question comes from Cory Kasimov with JP Morgan. Your line is open.
Hey. Good morning, guys. Thank you for taking my questions. Two for me as well. In terms of the phase III design, should we assume the comparison versus an established standard of care will be designed as non-inferiority and not superiority? Second question is kind of thinking about the newer mRNA-1011 and mRNA-1012 programs. Is there any sort of expectation for added safety liabilities as you add additional strains, or would you anticipate the profile to look similar overall? Thank you.
Great. Thank you. Let me, I'll take the first one. The short answer is, the established regulatory pathways do or are based on non-inferiority, the accelerated approval pathways and guidances that are out there. However, our ultimate design for that study is gonna be dependent upon regulatory consultations that are up and running now that we have clinical data, as Jacqueline said. Can't answer that question for sure, but I would point to the precedented pathways that exist and the fact that our objective with the quadrivalent mRNA-1010 program is to move quickly so that we can eventually move to combination quickly there. The reactogenicity profiles, we add additional antigens.
You know, in general, you know, the profile we see as we add antigens, I mean, not to be lost in this moment is this is a quadrivalent influenza vaccine, which an mRNA quadrivalent influenza vaccine has not happened before. It is quite, you know, comforting to us to see the balance of reactogenicity and immunogenicity that we saw in this study. As we you know look to add additional strains in the future and do additional combinations, we will evaluate that. Obviously, we've done that pre-clinically, but there's limitations to the ability of pre-clinical to sort of guide those decisions. We do not currently believe that there is gonna be a limit that is related to the technology, i.e., the amount of mRNA or lipid nanoparticle.
Really what this is a balancing act between the antigens and making sure that we get the right immunogenicity and that any one of those antigens don't over-contribute in terms of reactogenicity. We think those are ultimately clinical endpoints, but we are quite pleased with the direction that we're heading right now with the four mRNAs that are already there. I believe if we get there with the quadrivalent vaccine in mRNA-1010, that the addition of a fifth or a sixth mRNA around a hemagglutinin antigen will not dramatically change that picture. It feels relatively consistent as we have now gone from a single monovalent in our prior flu experiences to the quadrivalent here.
Okay. Thank you, Stephen.
Thank you.
Our next question comes from Tyler Van Buren with Cowen. Your line is open.
Hey, guys. Good morning. Thanks very much for taking the questions. I had two topics I wanted to ask on. The first was at the recent Vaccines Day, Sanofi was vocal in saying that late strain selection is not the solution for improved efficacy and that two out of the 10 past years had strain mismatch. Curious to get your thoughts on those comments and if the speed of manufacturing and prediction of accurate strains is now less of a competitive edge relative to the new mRNA-1011 and mRNA-1012 candidates adding one and two additional flu A antigens. The second is just at a high level, why do you think efficacy here seems to be similar to traditional vaccines for flu when mRNA was so superior for COVID?
Great questions. Let me take the first one, which is the strain mismatch point. I mean, if you look at that mismatch as simply, was it, the number one strain? I think you asked that question. That question gets asked very narrowly. If you look at the Nextstrain data across, let's just say H3 and the evolution of the picture over the last four or five years, what you see is that there are multiple circulating H3 clades. Again, clades are defined as having different immunogenicity often between them. The question really is, you know, why is quadrivalent and the definition of whether you got the number one H3 on average globally the success measure here?
We actually understand why it has been historically, but we believe that providing tools to public health officials to think more broadly about that, i.e., that there are multiple H3 strains circulating that have 20%, 30%, 40% of the circulating epidemiology. We think that actually is the right way to think about this disease. It's just, you know, following the epidemiology as rather than following precedent.
Our view on mismatch and whether or not narrowly we focus just on whether it was mismatched one year in seven or one year in 10, as others may have commented, probably misses that nuance and also misses the nuance that the most prevalent strain in different geographies might be different and might need some regional adaptation or might need polyvalency and multivalency solutions. Our goal is to bring forward solutions that could work with public health officials. It's ultimately their decision, particularly as it is right now with groups like the WHO, about what goes into these vaccines. We wanna make sure that we actually advance the science towards something where you can do more, where you can cover more strains.
Of course, we also can make later strain selections, but I think as you pointed out, later strain selections or multiple strains and additions of, you know, a pentavalent, hexavalent, heptavalent vaccine actually achieve similar results. We're quite comfortable using our platform to try and address the problem from either one of those directions. If we can actually move beyond quadrivalent, we may be able to address much of that mismatch risk, as well as address the fact that there are regional differences rather than a single global norm of a single clade, or at least particularly with H3N2. I apologize. The second question, could you just restate it again?
Yeah. It was just at a high level, why do you think the efficacy here seems to be similar to traditional vaccines for flu when mRNA was superior for COVID, and how should we think about that when it comes to, you know, RSV or CMV or other diseases?
Great question. Thank you for reminding me. First of all, I would remind you that we're not looking at efficacy here. We are looking at immunogenicity, and so there's a desire to extrapolate from this immunogenicity absolute confidence about what the curve of efficacy looks like. I don't think that's clearly doable. I know we all wish to do it. I think where we see immunogenicity at a very high level in a well-matched strain, when we match, let's say in the quadrivalent, we're quite encouraged by that because we do think that it. You know, a lot of the challenge in terms of vaccine efficacy is actually matching circulating strains and, as I said a moment ago, the diversity of the circulating strains, which is a feature that we think mRNA uniquely competes on.
When you match well, you can get good efficacy. I think the complaint often around influenza vaccines generally is just when we get to those mismatches, and also regional or country-level mismatches. We are looking ultimately at immunogenicity here, not efficacy. Efficacy will come later, and it is possible that you would see even in equally matched superior efficacy as a result of the mRNA platform. We ultimately need to go prove that with other data, not with just the titers today. The second thing I'd point to is that these titers, while we all do compare the HAI titers and assays, and you can look at things like GMFR and seroconversion rates and try and intuit comparisons between these, are still different assays.
We've all gotten quite accustomed to the idea that looking between different companies and different assays can be challenging. Until you have head-to-head in the same assay as we're doing in the phase II, it is difficult to know for sure. We have not yet passed judgment, at least internally, on the quadrivalent mRNA-1010 program and what its efficacy might be. I will note though, as I think one of the earlier questions asked, our goal with the mRNA-1010 program is to be at least as good as the best, and move very quickly through established paradigms and then show how you improve, which we think is about epidemiology, not necessarily just technology.
Now, our ability to address that epidemiology is a function of mRNA technology and the fact that we think we can quickly add fifth, sixth, seventh strains if necessary.
I t's Jacqueline. If you don't mind, I'll just add to go back to an earlier point that hemagglutinin inhibition titers are useful. As you said, they're not the same as full efficacy. There's an entire side of the immune adaptive response, the T-cell response that we aren't measuring that we'll measure in subsequent studies and be able to report on. I wanna take a step back and just remind everyone that the novel coronavirus was something that the human population as a whole hadn't seen before and is likely the reason why it has spread so quickly through the population.
Vaccinating a completely naive population is very different than vaccinating a highly boosted and exposed population, which is the case with influenza, where all of us have had multiple flu infections and, if we're good about vaccination, yearly influenza boosters. In particular, we were running this study at a time when, if you'll remember in the early summer, everybody was starting to mix again after a long time of social distancing. I think we may be seeing pre-existing titers that maybe are not the usual pattern. It's why we compared to Fluzone HD in a study that was conducted during a comparable time period.
The other thing I would mention is that Fluzone HD is not a standard seasonal influenza vaccine. It's the high-dose influenza vaccine intended for older adults. I think there's good reason to hope that our mRNA-1010 will be highly efficacious and capitalize on the benefit of the technology. As Stephen said, we're not relying on that. We're looking at other ways to improve.
Our next question comes from Hartaj Singh with Oppenheimer & Co. Your line is open.
Hey, thank you for the questions. I've just got two quick ones and really nice data. One is, Stephen, I think you had mentioned this, but can you just walk us through when, you know, the quad vaccine or beyond quad and the additional antigens could actually be in the clinic? I mean, would you have to wait for the phase II data or have a full phase III data set before we could start seeing those in the clinic? And then just remind us what the cold chain requirements are for mRNA-1010 and the other ones. Thank you for the question.
Great. Thank you. Both questions. We are planning, and as Jacqueline said, intending to initiate the phase III study for the quadrivalent mRNA-1010 program next year in 2022. We will have interim analysis from that phase II data in the early part of 2022. That will be confirmatory, we hope, and allow the direct comparisons. If that's the case, we will go forward quickly into that phase III study. Again, subject to regulatory consultations on the scope of that and some of the questions that were just asked about what that comparator will look like and how and what tests will be running in that study. The [mRNA-1011] and [mRNA-1012] programs, we would expect to move very quickly behind it.
We have not yet guided on when we'd start those in the clinic, but, you know, I would note that, we do now have quite a comfortable level of safety data with H3, and what we're starting to see here. We will look to add in an additional, you know, mRNA-1011 and mRNA-1012 additional antigens quite quickly, perhaps even in 2022. I think the question for us is a little bit of a regulatory one as well, which is what is the best way to move forward, in this platform where we're adding additional antigens?
One strategy might be to pursue mRNA-1010 all the way through and hopefully a precedented regulatory pathway towards perhaps an accelerated approval, again, subject to regulators agreeing with that, and then using subsequent updates to add additional HA antigens in the influenza A line like mRNA-1011, mRNA-1012. That would certainly be our hope. We think it would follow on precedent, for instance, when vaccines went to quadrivalent, which was just a few years ago. Ultimately, that's gonna be subject to those regulatory consultations over the next month, so it just makes it very hard for me to provide anything other than directional sense of how we're thinking about it.
On the question of cold chain and storage, our target product profile here that we'd like to aim at, we want to be acceptable in the existing market, which tends to be refrigerated single-dose forms. We have, as you know, a number of different ways that we've demonstrated that in our past. The mRNA-1273 program, we are continuing to extend that shelf life, and that is a quite large mRNA. But we have actual experience in other vaccines where we have gone to refrigerated forms in the past, and so we have some reason for optimism, hope there. It is a seasonal vaccine as well, and so you do not need many years of shelf life in that case or 18 months.
In fact, it's gonna be updated quite regularly, particularly if we go regional with it. We are hopeful that we are gonna be able to hit a you know non-inferior profile in terms of storage that ultimately we think will be beneficial in the flu market.
Great. Thank you, Stephen. Thanks for answering the questions.
Our next question comes from Joseph Stringer with Needham & Company. Your line is open.
Hi. Good morning. Thanks for taking our questions. Can you just remind us, as you look at inclusion of customized antigens, perhaps on a regional basis, what the turnaround time is on manufacture of those and how that compares to, say, the COVID variants? Then secondly, just more generally on the phase II readout early next year, just help us, you know, would you be looking for just non-inferiority essentially, you know, versus the active comparator? Would that or do you need to see more in terms of efficacy, to give you confidence in your phase III discussion and design? Thank you.
Thanks for the question. I'll take the second one first on the phase II. You know, obviously we'll want to see results that are consistent with what we saw here today, and obviously, we hope favorably in the comparison with the licensed standard dose vaccine. I think if we do see results that, you know, we're seeing GMFRs here in older adults of six in the influenza A strains and quite high titer seroconversion rates in that sort of, you know, as we saw here, 60%-80%, that gets quite encouraging. Obviously, better is better, and we'll hope for that as well as we increase the N in terms of that update.
I think the pathway though for us in the mRNA-1010 programs, I keep saying, is principally to, in a well precedented established way, try to get approvals, and that those pathways exist. They are clear, and we would like to follow them as best as possible before we perhaps bring more disruptive innovations into that framework, which would include the addition of additional HA antigens and neuraminidase, which we are working on in parallel. Our goal is not to have there be a long delay between moving forward first with mRNA-1010 and then those more disruptive innovations. We're trying to move those in parallel.
We recognize that we, you know, have some work to do to move forward the mRNA-1010 quadrivalent program, and we wanna make sure that we do that in a way that is most well established and comfortable for both regulators and public health officials. I think on the second question, actually, if you could just restate it.
I'm sorry. Just in terms of, turnaround time manufacturer for inclusion of the regional. Yep.
Sorry. It was your first question. I apologize for that. On the turnaround. You know, you've seen us turn around quite quickly in multivalent vaccines with the COVID space. I will note that the volumes of what we're doing in COVID are dramatically bigger than the, you know, than even the entire flu market today. I mean, you know, we're talking about hundreds of millions of doses. You know, and if we, in 100 days, are able to turn around here, for instance, with an Omicron booster, and that's not subject to today's conversation, but as we've talked about, if we start to do that and producing tens of millions to hundreds of millions of doses, that is very similar to what you might need for a regional variation here.
I would note that actually if you look again back at the strain evolutions, there is multiple different strains that are evolving, and they are maybe different at a country level or a regional level in terms of what's most predominant. If you look at the top two, three, four within, let's say, the H3 clades, you actually get quite substantial coverage. Maybe the answer is if you pick up three H3s and it actually provides broad coverage, you don't need too much regional sub-specialization. Oftentimes you have some lead time to those clades, right? It's not like you need to do it in 100 days, which is something obviously we know we can do based on prior experiences with COVID.
I think we're quite comfortable based on the experience of the last 18 months, based on the volumes of our production and based on the number of times we've demonstrated our ability to pivot and maybe even in the coming months demonstrate our ability to pivot again, that we will be able to, at the smaller volumes in the flu market, be able to address those issues with sub-specialization.
Thank you.
Our next question comes from Geoff Meacham with Bank of America. Your line is open.
Hi, this is Alex Hammond on for Geoff Meacham. Thank you for taking our question. Just a couple from us. Just wanted to know if you commented on what the active comparator will be in the phase II trial. Also, how will you guys weigh safety and immunogenicity when determining the dose selection for the phase III? Thank you.
Thanks for both questions. We haven't commented yet on the active comparator. We may in the future. I just don't think we did today, and so I will refrain from doing so. I think how will we compare reactogenicity and immunogenicity for the mRNA-1010 program out of the phase II and guide us? I think, as I said a moment ago, if we see good seroconversion, particularly seroconversion GMFRs like we saw here in against the influenza A strains, which are the primary strains of concern in the older adult population, the flu market, if we see those look like what we've seen here today in the phase I think we will feel very good about moving forward.
As was noted, seroconversion and GMFRs there are quite high and look quite good in the H3 line. I think in terms of reactogenicity, we want to make sure that it's a developable profile and it's competitive in the flu market for older adults. The best way we will know that is, again, the comparison against the active comparator in that study so that we can assess whether there are differences at all in reactogenicity, and if there are, whether a 25 µg or a 50 µg dose will be the optimal choice for those populations.
Great. Thank you. Maybe just one follow-up. What are your thoughts on the idea of the ideal valency for the flu vaccine when you put it into a combo with RSV and COVID?
We have gone pre-clinically into the, you know, well north of 10 different antigens, and we continue to see that we see good immunogenicity. I don't think that there's a technical limit. The question is maybe around an epidemiologic one, which is at what point does it become more than is needed? I think where we will be guided is where is the epidemiology of the different viruses. Obviously, we'll want to make sure that we cover RSV, and if there's still a single dominant strain for COVID, then you could have a single mRNA for that. If there's a couple of strains for COVID, then you could imagine a couple of slots there.
In influenza, we want to obviously have the quadrivalent strains that are getting selected and used broadly now by many vaccines. The question of how many H3s and H1s given influenza A drive most of the morbidity and mortality is really one that's gonna be guided by epidemiology. It does not need to be the same answer every year. That's another issue with, we think, the current approaches that mRNA might be able to resolve. In some years, you might choose more diversity, and in other years you might think that is less necessary. That's something that we hope to bring as an innovation to this market.
Great. Thank you for the color.
Our next question comes from Mani Foroohar with SVB Leerink. Your line is open.
Hey, guys. Thanks for taking the question. I've got a couple quick ones that we'll go in series. It sounds like you guys haven't disclosed whether or not you're gonna be using the high dose or standard dose as a comparator in the phase II. Should we expect one or the other, and is there a rationale not to disclose that?
Mani, sorry about the question. We'll be evaluating a standard dose comparator in phase II. You could choose either standard or high dose. You just need to benchmark in the same study, and then obviously you can compare. That's why we're for now for the timing of that study and matching the strains, we're using a standard dose. At that point, you'll be able to compare it against a standard dose.
You caution against comparing cross-trial after spending about an hour comparing cross-trial versus a high dose on efficacy. Doing essentially the same thing now and looking at the prescribing information, your all AEs, your grade 3 AEs across the board are between 2.5-6 x higher after 29 days than the 180 days captured on the prescribing information for high dose. Is it rational to move forward into a combo vaccine with COVID RSV with mRNA-1010? Or is it more appropriate to go back to the drawing board and improve and look for a new flu construct that doesn't have this severe of a reactogenicity profile?
You know, I guess as I said, I think it's dangerous to make those sorts of comparisons. We've tried to be measured in our comparisons on immunogenicity and reactogenicity. I think I'm gonna be guided by the phase II data results. If you look at our saline placebo, you will probably note that that is also higher and more reactogenic than the authorized, you know, labels that you're looking at. Which I think gets to the point that until you get an active control, you really need to be careful at what you're looking at in terms of solicited adverse events.
There is a little bit more history of comparing across assays on things like GMFR and seroconversion rates in both the regulatory guidance and in literature, which is why we cautiously present that data as a comparison here. Again, I wouldn't be guided by that either until we see the active comparator in our phase II on immunogenicity responses. I think it's, you know, it's not appropriate to draw too many conclusions, and that's where we are.
I'm sorry. I don't think you answered the question about whether or not it makes sense to go to a safer flu backbone or push through with the lower dose of mRNA-1010.
You're asking a question about whether or not we believe the reactogenicity profile is appropriate for moving forward to phase III. At present, we believe that from the phase I data, that particularly the reactogenicity profile of the 50 microgram dose is appropriate to move forward to phase II, as we have done. We're gonna be guided by that phase II data to actively compare it against the flu vaccine. Until you do that, we don't know how to answer that narrow of a question. We see reactogenicity in the placebo arm that exceeds the flu market. If that were the standard, we wouldn't be going forward at all, and that is in the placebo arm.
We really do need a direct comparison before you can make any of the statements that I think you're making as a precedent to the question. We will evaluate it in phase II. We will be guided by that data. I, you know, as I said before, I think you run the risk of taking low numbers, a single instance in case of a grade 3 difference between placebo and the 50 µg dose level and trying to draw too many conclusions from it, including ones that would involve, as you say, going back to the drawing board. I think we wanna go see that data. We are in parallel evaluating a lower dose. 25 µg may achieve the same immunogenicity, as well as have even better tolerability.
That is ultimately the goal of the phase II study is to answer these questions.
Okay, that's helpful. You guys repeatedly mentioned the absence of grade 4 AEs. In combination with your, with the noted reactogenicity profile of mRNA-1273, should we expect an additive reactogenicity profile, i.e., is there some risk of a higher grade 3 rate or grade 4 AEs when you add in the additional immune activation of your COVID vaccine as well in an eventual combo vaccine?
I tried to answer this question a moment ago, and you know, I think I did to the best of my ability, which is that we do not have any evidence yet on whether there's gonna be additive synergistic or not additive reactogenicity profiles. It is not something you can tell from the current data in my opinion. You need to go run the clinical study. We have dosed in our platform technology up to 1 mg consistently in the PCV space. We've gone up to several hundred milligrams in some of our other vaccines, including respiratory vaccines like the mRNA-1653 program. We do not believe that this is a limit in terms of technology. It's a function of antigens, and therefore you have to actually combine the antigens to know.
That is a clinical trial that we look to run in the future.
Okay. Thanks. That's really helpful.
Our last question comes from Emmanuel Papadakis with Deutsche Bank. Your line is open.
Thank you for taking the question. Perhaps I'll take a couple please as well. First, on the regulatory pathway, perhaps I could just push you a little more on the regulatory probabilities. I appreciate you've not yet had the discussions in question. Based on your engagement with the FDA to date, do you think the phase II head-to-head immunogenicity data is likely to be approvable as the phase III more likely a pre-approval requirement? Then perhaps more interestingly, what does the regulatory pathway look like for combined vaccine? I think Stéphane said you have line of sight for single combined annual respiratory booster. From a regulatory perspective, does that need full phase III efficacy studies or again is early immunogenicity data likely to be sufficient?
Perhaps a question on the commercial now that we've heard existing market leaders discuss at length the importance of full efficacy and outcomes data to drive contracting and uptake in the flu market. Based on your discussions to date, to what extent do you think committees, payers are likely to first want to see long-term outcomes data, for example, around hospitalization and comorbidity outcomes to really drive significant commercial uptake of mRNA-1010, assuming it does get to the market over the coming years? Thank you.
Thanks for the questions. As you hinted in your question, I will struggle to provide guidance that we haven't gotten yet from regulators. I think I will note that the published guidance does call for demonstration of efficacy even following accelerated approval. We would fully expect to do that ourselves anyway. We will be looking to demonstrating clinical studies either pre or post-approval, depending upon that regulatory guidance, the efficacy of the mRNA-1010 vaccine. We would hope if we move forward with, you know, better matching, that we can also demonstrate over time, improved performance of the vaccine relative to other competitors. That again is subject to discussions with regulators about whether that's happening before or after.
Yeah, It's Stéphane. I'll take the other one. We've had a lot of discussions thanks to COVID. We've health ministers, payers, scientific advisors to many governments around the world and private payers as well. The feedback has been very strong. People are really excited about the idea of having a non-inferior flu product that can be adapted for their geography. For example, in Canada, as you know, we have an agreement with Canadian government to build a plant there. One of the key feature of that partnership, which is a multi-year partnership, is to provide adapted product that will be designed in collaboration with the government of Canada and the scientists at Moderna. The other piece is the addition of COVID.
People are very worried in governments that the chance of people getting an annual COVID booster and an annual flu booster is gonna be a big issue. It's a very large worry for governments. When you talk about the combination, this is a piece that people are so excited about. People are telling us, "If you can give us a non-inferior flu shot and, from real world evidence, the most effective COVID booster," people are very excited. That's exactly what we're doing. The piece I think that people are not kind of getting from where we are today, this is our first iteration on flu. As we've said in our remarks, this is not our last flu product. This is our first one.
Our first shot on flu is non-inferior to the best product on the market that people have worked on for 20 or 30 or 40 years in traditional pharma. We're gonna keep moving very fast. We're gonna keep adding components like the hemagglutinin, the H antigen, the NA antigen. We're gonna keep adapting the strain, as Stephen said, to the country. And of course it will be in COVID. All the discussion we've had with buyers, governments or private payers are very strong, and we anticipate to have a big impact there.
Very helpful, thank you. Just on the efficacy and outcomes data to drive U.S. commercial uptake.
Sorry, can you say the question again?
Efficacy and outcomes data, for example, hospitalization, how significant do you think that is likely to be in driving U.S. commercial uptake? Your flu vaccine-
[crosstalk]
Of course that would be important, that's what we'll get from a clinical study. That's why Stephen was saying that getting the right dose in the phase II is gonna be very important to then drive the phase III and to get all that data that of course the government and the payer are gonna be looking for.
I'd like to turn the call back over to Stéphane Bancel for any closing remarks.
Well, thank you very much for joining us today. We are very excited about this data, and we think we're gonna be able to keep pushing the envelope on respiratory vaccines. We look forward to providing an Omicron update soon. Have a good day.
This concludes the program. You may now disconnect. Everyone, have a great day.