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Wednesday, June 29, 2016

Actinium Moves Iomab-B Into Phase 3

On June 29, 2016, Actinium Pharmaceuticals (ATNM) announced the initiation of the SIERRA Phase 3 clinical trial for Iomab-B. SIERRA - Study of Iomab-B in Elderly Relapsed or Refractory AML - is a randomized, controlled, multi-center study with a target enrollment of 150 patients with refractory or relapsed Acute Myeloid Leukemia (AML) over the age of 55. Patients will be split equally between Iomab-B and (physician's choice) conventional care prior to allogeneic hematopoietic stem cell transplantation (HSCT). The primary endpoint of SIERRA is durable complete remission (dCR) at six months from HSCT. Secondary outcome measures include overall survival (OS) at one-year and safety. Additional data about SIERRA can is available on the ClinicalTrials.gov website (NCT02665065).

What Happens To Actinium Post-Phase 3

The success of SIERRA will be a major valuation inflection for Actinium Pharma. One needs to look no further than Celator Pharmaceuticals (NASDAQ: CPXX) as an example of what positive Phase 3 data in AML are worth. In early March 2016, Celator was trading at only $1.65 per share. Following release of the VYXEOS top-line results, the company's stock quickly rocketed to over $12 per share, allowing Celator management to raise $43.7 million in new funds at $9.50 per share. Expanded data from the Phase 3 trial at AACR in April and hints of new data at ASCO in June pushed the shares to nearly $18 per share in May 2016. On May 31, 2016, Celator agreed to be acquired by Jazz Pharmaceuticals for $1.5 billion, which equated to over $30 per share. This is the path that Actinium is on if SIERRA is successful.


Another company that has been successful with Radiopharma 2.0 is Advanced Accelerator Applications (NASDAQ: AAAP). AAA is a radiopharmaceutical company that develops and commercializes innovative therapeutic and diagnostic products. The company is a leader in the production and commercialization of molecular nuclear diagnostic radiopharmaceuticals for PET and SPECT in Europe. AAA currently markets radiopharmaceuticals mainly used for diagnosis in clinical oncology, cardiology, and neurology, which is admittedly a division that Actinium does not possess, but the bulk of the valuation in my view is the company's emerging molecular nuclear medicine pipeline for the treatment of neuroendocrine cancers.

AAA’s lead therapeutic product candidate is Lutathera, a novel radiopharma compound under development for the treatment of midgut neuroendocrine tumors. Lutathera is a Lutetium-177 (Lu-177) labeled somatostatin analog peptide. The drug has received orphan drug designation from the EMA and FDA, along with being granted Fast-Track designation for the treatment of inoperable progressive midgut neuroendocrine tumors. Phase 3 data on Lutathera were positive, and AAA filed the New Drug Application (NDA) in March 2016. The product is currently available under an expanded access program, and in June 2016 received priority review from the U.S. FDA.

AAA currently has a market capitalization of $1.2 billion. Positive Phase 3 data with Lutathera had come before the company was public, but the initial public offering (IPO) only a month later saw nearly a 100% return in only a few weeks. Beyond Lutathera, AAA has additional radiopharma candidates in preclinical and Phase 1 trials. However, I believe the opportunity for Iomab-B exceeds the opportunity for Lutathera specifically because midgut neuroendocrine tumors are rare, with an incidence of less than 10,000 per year between the U.S. and EU. Above I outlined the potential patient population for Iomab-B at approximately 20,000 per year between the U.S. and EU. Even at a price of $100,000 per year, the opportunity with Lutathera is smaller than Iomab-B. So why is the market valuing Actinium shares at less than one-tenth the value of AAA? Completion of the Phase 3 studies and having an application under U.S. FDA review seems to be the primary reason.

Background On Iomab-B

Actinium's Iomab-B (BC8-I131) was invented by researchers at the Fred Hutchinson Cancer Research Center (FHCRC). The drug is a combination monoclonal antibody that targets a common lymphocyte antigen, CD45, and radioactive iodine-131. CD45 plays a crucial role in the function of hematopoietic cell activation and differentiation. By specifically targeting CD45, a cell surface antigen widely expressed on hematopoietic (myeloid and lymphoid) cells but not other tissues, Iomab-B can effectively offer target-specific ablation as a conditioning regimen prior to hematopoietic stem cell transplantation (HSCT) with the potential for improved efficacy and safety / tolerability. Importantly, because expression of CD45 is found on both normal and leukemic cells, it can be used to target marrow in both remission and relapsed patients.


Iomab-B development is initially focusing on the treatment of elderly patients with refractory / relapsing AML. These are patients that have failed the "7+3" induction phase of chemotherapy and cannot tolerate intensive or even reduced conditioning myeloablation. There is no treatment option for these patients today, resulting in an inverse correlation between age and expected survival (1). In fact, elderly patients that fall into this "poor risk" category achieve response rates to salvage chemotherapy below 20% and see long-term survival rates below 10% (2). Many are simply placed on palliative care.

Myeloconditioning / myeloablation before HSCT is an incredibly complex and delicate balance between safety and efficacy (3). Failure to ablate enough cells can result in high relapse rates or increased risk of Graft vs. Host Disease (GvHD), whereas overly intense therapy causes increased risk of treatment-related mortality. Selective radiation of leukemia cells using radiolabeled monoclonal antibodies against antigens on marrow cells promise to improve results by targeting malignant cells and causing less systemic damage (4). Iomab-B also has the potential to shorten the induction and conditioning time ahead of transplantation, as Iomab-B is given for six days versus standard induction chemotherapy which averages between 28 and 42 days.


A Phase 1 study conducted in 59 patients with refractory / relapsing AML demonstrated impressive targeted delivery of radioactive isotope with Iomab-B. Results show that 52 (88%) patients receiving Iomab-B had higher estimated absorbed radiation in targeted locations such as bone marrow and spleen than in any other organ (5). Iomab-B biodistribution to the lungs and kidneys (i.e. off-target organs) was minimal (6). The estimated 3-year non-relapse mortality and disease-free survival for these patients were 21% and 61%, respectively. Importantly, the initial work with Iomab-B showed an overall incidence of GvHD similar to standard conditioning.

These findings are important because peer work has shown a consistent correlation between response rates and whole-body radiation dose. For example, work done by FHCRC found lower relapse rate for AML patients receiving higher doses of total body irradiation (TBI) (7). Later work by FHCRC also found a direct correlation between TBI dose and response rate in patients with chronic leukemia (8); however, in both studies, the higher TBI exposure was associated with significantly higher treatment-related mortality, such that there was no difference in long-term disease-free survival between the two randomized groups.

Data from the Phase 1/2 trial (NCT00008177) was compared to standard conditioning and chemotherapy (outcome analysis compiled by the MD Anderson Cancer Center) and published in Blood in 2009. In a subset of 18 elderly patients with poor cytogenetics, Iomab-B when added to FLU plus 2Gy TBI resulted in a 1-year overall survival of 33% compared to 3% for standard conditioning and high-intensity chemotherapy. After two years, 16% of the Iomab-B cohort was still alive compared to 0% for standard conditioning and chemotherapy (unpublished).


Iomab-B Market Opportunity

The market opportunity with Iomab-B is significant. According to the U.S. National Cancer Institute (NCI), there were an estimated 20,800 new cases of AML in the U.S. in 2015. Another 20,000 new cases arise in Europe each year. There are no currently approved treatment options for elderly patients with refractory AML, a patient population of approximately 12,000 individuals in the U.S. and EU each year, the majority of which cannot tolerate standard conditioning regimens that allow them to receive a HSCT.

By offering a more effective and more tolerable solution to the 12,000 elderly relapsed / refractory AML patients in the U.S. and Europe, Actinium is sitting on a sizable market opportunity with Iomab-B. Standard conditioning regimens cost between $50,000 and $200,000 ahead of HSCT. They can also take as long as 28 to 42 days. At $75,000 for a course of treatment over only six days, Iomab-B targets a $900 million opportunity.

Both Phase 1 and Phase 2 trials with Iomab-B have led to effective cures in patients with no options. Once commercialized, I believe it makes sense for Actinium to test Iomab-B earlier in the treatment paradigm for these elderly "high risk" patients, or even move Iomab-B clinical studies into new indications such as myelodysplastic syndrome, acute lymphoblastic leukemia, Hodgkin’s disease, and non-Hodgkin lymphoma. From a mechanistic standpoint, pursuing these follow-on indications holds merit and could open up potentially billions of dollars in additional revenue opportunity for the company or its commercial partner.

Plus, I believe the recent success of Celator's Phase 3 VYXEOS (cytarabine + daunorubicin liposome injection) clinical trial and likely substantial use once approved increases the potential market opportunity for Actinium's Iomab-B. This is because the more patients that respond to the induction phase of chemotherapy means the more patients that will enter the consolidation or maintenance phase. Based on the Celator Phase 3 data, patients on VYXEOS had a CR+CRi of 47.7% vs. 33.3% for 7+3. That is a 43% increase in the patient population making it to the consolidation or maintenance phase of treatment.

The median overall survival rate from the VYXEOS Phase 3 trial was 9.56 months. That means half the patients are making it past 9.56 months. In fact, 41.5% were still alive one year post-diagnosis. This survival rate is a dramatic increase from 7+3, which had a median overall survival of only 5.95 months and one year survival rate of only 27.6% in Celator's Phase 3 study. Increasing the odds of patient survival past one or two years increases the number of patients that will likely qualify for a transplant. By keeping patients alive longer and putting more patients into consolidation, VYXEOS increases the target population for Iomab-B.

Actinium's Radiopharma 2.0 Strategy Reduces Risk

I still see and hear significant investor angst around Actinium's use of radioactive isotopes given the failure of some previous high-profile radiopharma drugs targeting AML. For example, the failures of Bexxar and Zevalin are often brought up when I discuss the market opportunity for Iomab-B with investors. I think there is still widespread misunderstanding of Actinium's approach and its "Radiopharma 2.0" strategy versus these doomed drugs. Below I explain why.

In June 2003, GlaxoSmithKline gained approval for Bexxar, a combination of the murine IgG anti-CD20 monoclonal antibody tositumomab conjugated to radioactive Iodine-131. CD20 is an antigen found on the surface of both healthy and malignant B cells. Bexxar was initially approved for treatment of rituximab-refractory, low-grade NHL. The label was expanded eighteen months later to include relapsed / refractory follicular lymphoma.

There were several reasons why Bexxar failed. Firstly, the drug had to be administered by a nuclear medicine physician. This requirement meant that practicing oncologists could not deliver the drug at their local infusion center along with chemotherapy. Instead, patients had to be referred to nuclear medicine pharmacy or a radiation oncologist who could handle the drug, resulting in lost revenues and patient follow-up by the original treating oncologist. Oncologists do not like to lose patients because patients pay bills. And speaking of bills, Bexxar was rather expensive at the time and many hospitals were finding push-back from Medicare on the price. Lack of enthusiasm for treating physicians or the hospitals they sometimes begrudgingly referred patients to played a major role in the slow uptake of the drug, as did logistical and manufacturing issues.

However, the end game for Bexxar came in 2011 when the drug failed to demonstrate a clinical benefit over CHOP chemotherapy plus Rituxan (rituximab) in patients with newly diagnosed follicular NHL (9). The failed trial was the proverbial "nail in the coffin" for Bexxar. Not only was the drug undesirable to prescribe, but it also offered no benefit to what the oncologist could accomplish alone.

Another radiopharma drug, Zevalin, a combination of the murine IgG anti-CD20 monoclonal antibody ibritumomab conjugated to radioactive Yttrium-90, looks equally ill-fated. Zevalin has been bounced around over the past decade, from Biogen to Cell Therapeutics, to currently at Spectrum Pharmaceutical. The drug is used in combination with rituximab in patients with both newly diagnosed and low-grade or follicular relapsed B cell NHL. The issues that keep Zevalin at minuscule sales levels ($3.7 million in the fourth quarter 2015) are the same issues that slowed uptake of Bexxar.

I do not see the issues that plague first-generation radiopharma drugs like Bexxar and Zevalin as relevant to Actinium's Iomab-B. Actinium’s “Radiopharma 2.0” strategy is not analogous to these older generation drugs. Iomab-B is a myeloconditioning / myeloablative agent for patients preparing to undergo HSCT. With Iomab-B, Actinium will target patients that cannot be treated with alternative measures by the oncologist at an infusion center. These are patients already referred for reduced intensive conditioning, which includes TBI and potentially the use of busulfan, cyclophosphamide, and/or fludarabine. Iomab-B is designed to be a safer alternative to TBI+FLU/BU/CY in elderly patients that simply cannot handle standard myeloablation, but still effective enough to wipe-out all leukemia cells and prevent GvHD.

Instead, Actinium’s strategy is far more analogous to Algeta, a Norwegian-based radiopharma company acquired by Bayer in December 2013 for $2.9 billion. In May 2013, Algeta received approval in the U.S. for Xofigo, a radium-223 dichloride used to treat men with advanced prostate cancer. Bayer and Algeta were previously co-promoting Xofigo. An analyst at Geneva-based Helvea S.A. estimated at the time of the deal that Xofigo peak sales were $1.1 billion (10). Consensus Xofigo sales for 2020 are $938 million (11). This sales level is similar to what I believe to be the market opportunity for Iomab-B.

Beyond Xofigo, Algeta had a platform technology capable of linking targeted monoclonal antibodies to radioactive alpha particles (thorium-227). This targeted radiopharmaceutical strategy is exactly what Actinium is doing with Phase 2 asset, Actimab-A. In this regard, I find it fascinating that in February 2015, Dr. Roland Turck, former President, Global Specialty Medicine at Algeta/Bayer Healthcare, joined Actinium as an advisor to the Board of Directors. At that time, Dr. Turck stated that Iomab-B could shift the paradigm in how AML patients are prepared for bone marrow transplant.

Conclusion

The initiation of the SIERRA officially makes Actinium a Phase 3 biopharma company. Enrollment should begin imminently and is expected to take place at many of the highest volume bone marrow transplant centers in the U.S. The protocol calls for an independent Data Monitoring Committee (DMC) to review patient data at 25, 50, 75 and 100 percent patient enrollment, with the potential for two additional ad-hoc DMC reports if necessary. Thus, investors should be kept abreast of the progress of SIERRA over the next several quarters.

I believe this trial starts the process of unlocking significant value for Actinium shareholders, as successful completion likely means Actinium is worth similar levels to AAA at $1.2 billion or Celator at $1.5 billion. Once commercialized, it could be worth similar levels to what Bayer paid for Algeta at $2.9 billion. This is why I believe shares of Actinium Pharmaceuticals offering a compelling value today.

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This article was written by Jason Napodano, CFA of BioNap, Inc.
Please see additional information on our Disclaimer.

5 comments:

  1. I think this is the next CPXX!
    Thanks Jason!

    ReplyDelete
  2. What about the selling pressure from Memorial Sloan Kettering? They are still unloading 150,000 shares per week.

    ReplyDelete
  3. Jason,

    Jason, Really like Atnm and would like to add more but have 2 questions

    1. will they need to raise funds soon? Have 20 mill in cash but I read where they expect phase 3 trial to cost 25 million. Wandering when u think that will occur.

    2 also, I listened to webinar of Sierra trial and heard u question them on different scenarios regarding the end points of trial. Do u have any concerns there?

    Thanks

    ReplyDelete
  4. How does Iomab-B compare to Seatle Genetic SGN-CD33A? Is Iomab-A a closer product to SGN-CD33a?

    Both products attack AML. Does approval of one make the other product invalid or non-approvable?

    Seatle is much larger (7 Bill) and the started their Ph 3 in May, 2016. How does ATNM valuation affect if SGN-33A is first to market?

    ReplyDelete