Colorectal Cancer | Pharma Strategy Blog

International Society of GastroIntestinal Oncology (ISGIO) meeting

By MaverickNY on September 22, 2010

It’s been quite a busy week with new projects, proposals and contracts on the go plus we’re heading off to the International Society of GastroIntestinal Oncology (ISGIO) meeting in Philadelphia tomorrow.

Jaffer Ajani does a really nice job of organising this educational conference. It includes the latest updates in the field from a esteemed panel of experts, as well as practical case studies, to help teach a diverse international and US audience how to manage complex or unusual cases.

There’s not a lot of science, but there is serious emphasis is on practical learning and questions from the attendees are encouraged, which I really like. They also have proffered papers on clinical issues, which encourages young up and coming clinicians or researchers to present their work and gain some feedback.

The thought leaders are generally relaxed, approachable and chatty during the breaks, so this makes networking much more fun. John Marshall from DC, for example, is nearly always guaranteed to make the audience (and sometimes his fellow panel members) sit up and pay attention by asking provocative questions or creating a controversy to challenge people’s thinking. A good debate usually follows as a result.

If anyone is going to the meeting or is in Philly and wants to meet up, do let me know and schedule permitting, I do try to accomodate requests. My email link is in the right margin and the phone link in the About page under the blog header – just click on the Google Voice widget to leave a message.

Finally, I would really like to thank all the readers who share papers, suggest topics either in person at conferences or by email or through their thoughts and observations as a result of interacting with this blog. It is much appreciated and I learn from others too. Science, cancer research, drug development and commercialisation were not meant for lonely activity by the nudist on the late shift, but as an interactive learning environment where we can all benefit. That’s what makes it all much more fun.

Please keep the correspondence and suggestions for new blog topics coming. I may not get round to them all in the week they are sent, but do try to research and schedule them at some point.

PIK3CA, MEK and mutant KRAS in cancer

By MaverickNY on September 10, 2010

One of the current challenges with developing new targeted agents in oncology is the tendency to rush various agents, whether monoclonal antibodies (mAB) or tyrosine kinase inhibitors (TKIs) into the clinic before we know how they might best work or in what potential combinations based on the precise underlying biology.

Another challenge I see is old school chemotherapy approaches permeating new development thinking. By this, I mean the traditional concept of testing therapies in advanced, metastatic and highly refractory disease where the tumour burden is high and the chances of getting a decent response is low.

This is one reason I love the I-SPY neoadjuvant concept in breast cancer. Testing a range of compounds prior to surgery based on the potential drivers of the cancer will let us know very early which agents are working or not and which could potentially be selected for subsequent adjuvant treatment after surgery.

Background

Recently, I reading a couple of papers (see references below) on phase I and II trials with a MEK inhibitor (PD-0325901), but it was a little bit with a sinking feeling because the trial design was rather old fashioned and traditional, ie take a bunch of solid tumours in phase I, see what (mixed) signals you get:

"PD-0325901 showed preliminary clinical activity. The maximum tolerated dose, based on first cycle dose-limiting toxicities, was 15 mg BID continuously. However, 10 and 15 mg BID continuous dosing and 10 mg BID 5 days on/2 days off schedules were associated with delayed development of RVO; thus, further enrollment to this trial was stopped."

Where RVO was retinal vein occlusion.

Next, do a phase II in a big (ie large potential patient numbers), advanced, metastatic and highly refractory cancer. Predictably, the results were unsurprising:

"PD-0325901 did not meet its primary efficacy end point."

If we looked at those results in isolation, we might be tempted to dismiss the idea that the MEK inhibitor doesn't work and abandon it.

A different way of thinking

That said, I was much more encouraged by another article from another group that looked at the problem completely differently with exactly the same MEK agent. If you think about it, a focused sniper rifle strategy is often going to be more effective than a bludgeoning blunderbuss.

They looked at the basic evidence that:

"Mutational activation of PIK3CA, which commonly co-occurs with KRAS mutation, provides resistance to MEK inhibition through reactivation of AKT signaling"

And then set out to look at this relationship more clearly in animal models:

"to determine the MEK dependence of tumors with mutational activation of the pathway. These studies indicate that many KRAS mutant tumor cell lines are, contrary to the prevailing view, sensitive to the MEK inhibitor PD0325901, and hence, dependent on the RAF/MEK/ERK signaling arm.

Resistance to MEK inhibitors in the relevant cell lines is not an intrinsic feature of KRAS oncogenic function but instead mutational activation of PIK3CA is present in most, but not all, MEK resistant KRAS mutant cancers."

It's hard to argue with that logical approach.

Findings

The article is well worth reading and nicely put together, but here are the main findings of the research:

A subset of KRAS mutant cells depends on MEK/ERK signaling
Coexistent KRAS and PIK3CA mutations prevent cyclin D degradation and sensitivity to MEK inhibition
Selective knockout of mutant PIK3CA allele confers MEK/ERK dependence
Sustained cyclin D expression and bypass of MEK inhibitor–induced G1 arrest correlates with MEK antagonist efficacy
Combined inhibition of both MEK/ERK and PI3K/AKT pathways suppresses the growth of tumors with coexisting KRAS and PIK3CA mutations

Implications for the future

The thoughtful approach behind Halilovic et al's data is particularly interesting:

"Mutational activation of KRAS is a common event in human tumors. Identification of the key signaling pathways downstream of mutant KRAS is essential for our understanding of how to pharmacologically target these cancers in patients.

We show that PD0325901, a small-molecule MEK inhibitor, decreases MEK/ERK pathway signaling and destabilizes cyclin D1, resulting in significant anticancer activity in a subset of KRAS mutant tumors in vitro and in vivo."

KRAS mutant tumours are particularly relevant to colorectal cancer. Recently, we have seen that patients with colorectal cancer who have wild type, but not mutant, KRAS are more much more likely to respond to treatment with EGFR therapy ie Erbitux and Vectibix, allowing for careful patient selection and exposure.

What about melanoma where mutant RAS may stop the activity of RAS inhibitor such as PLX4032? Could adding a MEK inhibitor help overcome the problem in some cases, or perhaps that would be too simple? We don't know, but I'd love to see some research data in appropriate xenograft models in this area.

The problem is that there is currently no therapeutic agent that directly inhibits KRAS function, so the Halilovi data have very important implications for tumours driven by mutant RAS.

What the new data tells us:

"These data suggest that tumors with both KRAS and phosphoinositide 3-kinase mutations are unlikely to respond to the inhibition of the MEK pathway alone but will require effective inhibition of both MEK and phosphoinositide 3-kinase/AKT pathway signaling."

Bingo! Now that's a much more elegant approach to defining which patient populations are most likely to respond based on preclinical research before attempting clinical trials and randomly exposing patients who had no hope of responding to the systemic side effects of a treatment.

Personally, I would dearly love to see more clinical trial selection based on logical, well researched preclinical data rather than a scattergun let's hope and see approach.

We need to get smarter and faster at well designed research that points us in the right direction to increase the chances of better success and improved outcomes. It will also conserve precious R&D dollars and focus it where it's needed most.

References

Halilovic, E., She, Q., Ye, Q., Pagliarini, R., Sellers, W., Solit, D., & Rosen, N. (2010). PIK3CA Mutation Uncouples Tumor Growth and Cyclin D1 Regulation from MEK/ERK and Mutant KRAS Signaling Cancer Research, 70 (17), 6804-6814 DOI: 10.1158/0008-5472.CAN-10-0409

Haura, E., Ricart, A., Larson, T., Stella, P., Bazhenova, L., Miller, V., Cohen, R., Eisenberg, P., Selaru, P., Wilner, K., & Gadgeel, S. (2010). A Phase II Study of PD-0325901, an Oral MEK Inhibitor, in Previously Treated Patients with Advanced Non-Small Cell Lung Cancer Clinical Cancer Research, 16 (8), 2450-2457 DOI: 10.1158/1078-0432.CCR-09-1920

LoRusso, P., Krishnamurthi, S., Rinehart, J., Nabell, L., Malburg, L., Chapman, P., DePrimo, S., Bentivegna, S., Wilner, K., Tan, W., & Ricart, A. (2010). Phase I Pharmacokinetic and Pharmacodynamic Study of the Oral MAPK/ERK Kinase Inhibitor PD-0325901 in Patients with Advanced Cancers Clinical Cancer Research, 16 (6), 1924-1937 DOI: 10.1158/1078-0432.CCR-09-1883

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Diabetes drug may protect against cancer

By MaverickNY on September 2, 2010

Yesterday, I covered some of the key pathways and kinases associated with cell energy metabolism, LKB1 and AMPK. These, together with Insulin-like Growth Factor-I (IGF-I) and the insulin receptor (IR), appear to play important roles in the broader regulation of energy and homeostasis. Experimental evidence suggests that an overexpression of IGF-I is implicated in pancreatic tumours, for example. Increased IGF-II and decreased IGF binding protein (IGFBP)-3 serum concentrations have also been linked to a number of other cancers (see journal link below).

If we look at the IGF-IR pathway, we can see more clearly how they all interlink and how mTOR, LKB1 and AMPK may all be a critical part of the process:

Source: Tao et al., (2007)

Research conducted over the past two decades has shown the importance of the type 1 insulin-like growth factor receptor (IGF-1R) in tumorigenesis, metastasis, and resistance to existing forms of cancer therapy. We also now know that feedback and cross-talk between IGF1R and IR can exist, driving hyperglycemia and free insulin production, as shown in a previous post regarding IGF-1R inhibition with figitumumab.

Clearly, there are drugs commercially available that reduce hyperglycemia in diabetes, so the next logical step would be to see what happens if they were to be used in cancer patients or people with a very high risk for developing cancer.

Background:

The journal Cancer Prevention Research has just published an interesting series of research papers around metformin, a generically available oral biguanide for the treatment of Type II diabetes, in cancer prevention. An excellent overview to the topic was covered in a comprehensive review of metformin for oncology applications by Michael Pollak, which is well worth reading.

In short, metformin was originally derived from a plant extract from the French lilac and activates AMPK in the liver. This means that it plays an important role in insulin signaling, whole body energy balance, and the metabolism of glucose. In diabetes, metformin therefore improves hyperglycemia primarily through its suppression of hepatic glucose production, ie gluconeogenesis.

If we accept the research that shows high levels of free IGFI (from the higher IGF-I/IGFBP-3 molar ratio) are important in cancer growth, then it makes logical sense to see what effects taking metformin might have on cancer prevention and risk reduction in animal models and humans.

Effect of metformin on lung cancer

Memmot et al., published a paper entitled, "Metformin Prevents Tobacco Carcinogen– Induced Lung Tumorigenesis" in Cancer Prevention and Research. The idea was that activation of the mammalian target of rapamycin (mTOR) pathway is an important and early event in tobacco carcinogen–induced lung tumorigenesis, thus therapies that target mTOR might be effective in the prevention or treatment of lung cancer. Since metformin activates AMPK, which in turn inhibits mTOR, they decided to investigate the possibilities in a mouse model. The mice were given a known cancer causing carcinogen, nitrosame ketone (NNK) and a group were treated with metformin and compared to controls (no treatment).

What they found was startling:

"Oral administration of 1 or 5 mg/mL metformin decreased lung tumor burden in mice by 38% and 53%, respectively."

What happened to the control mice who did not receive metformin? 100% of them developed tumorigenesis. To put these findings into perspective:

"The steady-state levels of metformin in mice given 5 mg/mL are similar to those in diabetic patients using metformin, suggesting the possibility that clinical prevention of lung cancer could be achieved with standard oral dosing."

Unsurprisingly even greater results were observed with direct intravenous metformin:

"intraperitoneal administration of metformin was more effective than oral administration and decreased tumor burden by 72%."

Overall, the researchers found that inhibition of the mTOR pathway in tumours was associated with decreases in levels of circulating IGF-I and insulin, which may well explain the dramatic results they saw with metformin.

Effect of metformin on colorectal cancer

Animal models are all very well, but what about human data? Japanese researchers have now reported the first study of metformin in people without diabetes, albeit on a small scale. Hosono et al., published an article, "Metformin Suppresses Colorectal Aberrant Crypt Foci in a Short-term Clinical Trial" after their earlier work in rodents. Rectal aberrant crypt foci (ACF) are an endoscopic surrogate marker of colorectal cancer, essentially an early precursor to malignant disease.

This work looked at prospectively randomized people without diabetes (n=26) with ACF to either treatment with metformin (250 mg/d, n=12) or no treatment (control, n=14). The initial results are promising:

"At 1 month, the metformin group had a significant decrease in the mean number of ACF per patient (8.78 ± 6.45 before treatment versus 5.11 ± 4.99 at 1 month, P = 0.007), whereas the mean ACF number did not change significantly in the control group (7.23 ± 6.65 versus 7.56 ± 6.75, P = 0.609)."

In other words, this is the first reported trial showing that metformin can inhibit colorectal carcinogenesis in man. It also provides preliminary evidence that metformin suppresses colonic epithelial proliferation and rectal ACF formation and may be a potentially useful agent for early cancer chemoprevention.

Conclusions

In an accompanying editorial, Engelman and Cantley provided some useful commentary on the underlying pathways and highlighted the promise of metformin for cancer prevention and therapy in the lung and other sites.

Of course, no pharma company is going to sponsor large scale epidemiology trials as metformin is now available generically, but given the prominence given to chemoprevention by Harold Varmus in his NCI acceptance speech earlier this year, perhaps we will see some progress from both the NCI and the NIH in this field. It's really a public health issue that needs a broader perspective than individual companies can offer alone.

We all intuitively know that preventing or catching cancer as early as possible will likely yield better long term outcomes for patients than treating end-stage metastatic disease with highly expensive therapies.

Additional References:

Douglas JB, Silverman DT, Pollak MN, Tao Y, Soliman AS, & Stolzenberg-Solomon RZ (2010). Serum IGF-I, IGF-II, IGFBP-3, and IGF-I/IGFBP-3 Molar Ratio and Risk of Pancreatic Cancer in the Prostate, Lung, Colorectal, and Ovarian Cancer Screening Trial. Cancer epidemiology, biomarkers & prevention : a publication of the American Association for Cancer Research, cosponsored by the American Society of Preventive Oncology PMID: 20699371

Tao Y, Pinzi V, Bourhis J, & Deutsch E (2007). Mechanisms of disease: signaling of the insulin-like growth factor 1 receptor pathway–therapeutic perspectives in cancer. Nature clinical practice. Oncology, 4 (10), 591-602 PMID: 17898809

Chitnis MM, Yuen JS, Protheroe AS, Pollak M, & Macaulay VM (2008). The type 1 insulin-like growth factor receptor pathway. Clinical cancer research : an official journal of the American Association for Cancer Research, 14 (20), 6364-70 PMID: 18927274

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Why do some cancer drugs work and others don't?

By MaverickNY on August 12, 2010

The news yesterday from Amgen that panitumumab (Vectibix) failed in Head and Neck cancer got me thinking. Why did it fail where cetuximab (Erbitux) succeeded? They're both monoclonal antibodies to EGFR, so that makes it rather interesting.

Many of you will remember that bevacizumab (Avastin) and Erbitux were both approved within a month of each other for colorectal cancer, both monoclonals, to VEGF and EGFR respectively. That was after a long string of failures for anti-angiogenesis compounds. Subsequently, vatalanib (PTK787), a small molecule tyrosine kinase inhibitor (TKI) of VEGF from Novartis failed in the same indication and did not achieve statistical significance in survival.

It gets even more interesting when you consider prostate cancer as another example:

Abbott's atrasentan got villified at it's ODAC meeting and never received approval. In a few months, however, we will hear what happens in the phase III trial for another endothelin-A inhibitor, zibotentan (AstraZeneca). The phase II data showed a difference in OS, but not PFS, so who knows what will happen with the phase III study?
Avastin also failed to achieve a survival advantage in prostate cancer, but does that mean that other VEGF inhibitors, such as sanofi-aventis/Regeneron's aflibercept (VEGF-Trap), will fall the same fate? We don't know yet, but as far as I know, that one's still alive and kicking.

I find it fascinating trying to work out why some drugs work and some don't even in the same class in the same indication. It could be all sorts of reasons:

Dosing
Scheduling
Patient population
Study design
Drug combinations
Compound structure
Availability of suitable biomarkers
Indications

Or one of many many other things or combination of reasons.

And there there is the related issue of 'pure' inhibitors (single target such as VEGF or BCR-ABL) versus multi-kinases or monoclonals (more than one target such as VEGF, EGFR, PDGF or FGFR, for example). Does it make a difference in efficacy and tolerability, will they affect outcomes differently?

Hopefully, we can learn from the failures to date for the future, allowing us to design better drugs and trials that have a more positive impact on outcomes.

Curiousity is killing this cat… R&D is such a crapshoot sometimes.

The growing importance of KRAS in ovarian cancer and its impact on pipelines

By MaverickNY on July 26, 2010

We've heard a lot about the impact of KRAS in colorectal cancer as a useful biomarker for determining whether or not to treat with EGFR therapy, depending on whether the mutation is wild-type or mutated, but now new evidence has emerged for it's possible role in ovarian cancer.

A paper by Ratner et al., from Yale University, looked at the relationship between an increased risk of OC and a KRAS variant.

Overall, the data demonstrated that a variant of the KRAS oncogene was present in 25% of all ovarian cancer patients. The same variant was also found in 61% of ovarian cancer patients with a family history of breast and ovarian cancer. Up until now though, it has proven impossible to tell which women with a strong family history of breast and ovarian cancers would go on to develop the disease. These results therefore offer some new clues in the puzzle.

Related research from another team from the UK, Denmark and US, published last year, looked at tagging single-nucleotide polymorphisms (SNPs) in candidate oncogenes and the susceptibility to ovarian cancer in approx. 1,800 women with invasive ovarian cancer compared with controls (n=3,000). The goal was to identify moderate/low-risk susceptibility alleles of the proto-oncogenes BRAF, ERBB2, KRAS, NMI, and PIK3CA, but no evidence of ovarian cancer association was found with these SNPs. When stratified by
histologic subtype, however, one common variant allele have borderline evidence of association with epithelial ovarian cancer.

What was interesting to me in the latest research from Yale is that all the women in the study had a strong family history of cancer, but only half had known genetic markers of ovarian cancer risk such as BRCA1 or BRCA2 mutations. The results, albeit from a small sample (n=157), suggest that the KRAS variant may offer a more sensitive than currently available.

The Yale group had previously established that the KRAS-variant is not somatic but germline, meaning it is identical in person's normal and tumour tissues, thereby enabling the researchers to collect primarily germline DNA from either blood or saliva, rather than from tumour biopsy samples. This is huge from a patient perspective and physician point of view in terms of ease of use and convenience.

This study is important because ovarian cancer is the single most deadly form of women's cancer and is usually diagnosed in advanced stage disease. Part of the reason is because of the lack of known risk factors or genetic markers of risk. To this end, the authors concluded:

"Our findings strongly support the hypothesis that the KRAS-variant is a genetic marker for increased risk of developing ovarian cancer, and they suggest that the KRAS-variant may be a new genetic marker of cancer risk for hereditary breast and ovarian cancer families without other known genetic abnormalities."

What we now need is validation in large scale clinical trials to determine whether the genetic marker can be used commercially to determine prognostic risk for ovarian cancer earlier. If the results ultimately prove useful in clinical trials, then this finding relating to the KRAS variant may well have important implications for future therapeutic strategies and pipeline development in ovarian cancer as well as for prognostic testing and earlier detection for improved outcomes.

Ratner, E., Lu, L., Boeke, M., Barnett, R., Nallur, S., Chin, L., Pelletier, C., Blitzblau, R., Tassi, R., Paranjape, T., Hui, P., Godwin, A., Yu, H., Risch, H., Rutherford, T., Schwartz, P., Santin, A., Matloff, E., Zelterman, D., Slack, F., & Weidhaas, J. (2010). A KRAS-Variant in Ovarian Cancer Acts as a Genetic Marker of Cancer Risk Cancer Research DOI: 10.1158/0008-5472.CAN-10-0689

Quaye, L., Song, H., Ramus, S., Gentry-Maharaj, A., Høgdall, E., DiCioccio, R., McGuire, V., Wu, A., Van Den Berg, D., Pike, M., Wozniak, E., Doherty, J., Rossing, M., Ness, R., Moysich, K., Høgdall, C., Blaakaer, J., Easton, D., Ponder, B., Jacobs, I., Menon, U., Whittemore, A., Krüger-Kjaer, S., Pearce, C., Pharoah, P., & Gayther, S. (2009). Tagging single-nucleotide polymorphisms in candidate oncogenes and susceptibility to ovarian cancer British Journal of Cancer, 100 (6), 993-1001 DOI: 10.1038/sj.bjc.6604947

Chin, L., Ratner, E., Leng, S., Zhai, R., Nallur, S., Babar, I., Muller, R., Straka, E., Su, L., Burki, E., Crowell, R., Patel, R., Kulkarni, T., Homer, R., Zelterman, D., Kidd, K., Zhu, Y., Christiani, D., Belinsky, S., Slack, F., & Weidhaas, J. (2008). A SNP in a let-7 microRNA Complementary Site in the KRAS 3' Untranslated Region Increases Non-Small Cell Lung Cancer Risk Cancer Research, 68 (20), 8535-8540 DOI: 10.1158/0008-5472.CAN-08-2129

Aeterna Zentaris and Keryx's Perifosine gets fast track designation for colorectal cancer

By MaverickNY on April 5, 2010

Last month at the ASCO GI Symposium, Keryx and Aeterna Zentaris reported statistically significant benefit in survival from updated results of a randomized, double-blind, placebo-controlled phase II study of KRX-0401 (perifosine) for the treatment of advanced metastatic colorectal cancer.

The study was based on 35 evaluable, but heavily pre-treated patients, with relapsed or refractory metastatic colon cancer were randomized to receive capecitabine (Xeloda) from Roche at 825 mg/m2 BID on days 1 – 14 every 21 days plus either perifosine (P-CAP) or placebo at 50 mg daily (CAP).

The results showed that the P-CAP arm had 1 PR and 8 SD for an overall response rate of 64%, while the CAP arm had 0 PR and only 3 SD for a response rate of 27%.

In addition, looking at the overall survival, the data favoured the P-CAP arm a MOS of 15.3 weeks compared with 6.8 weeks for CAP alone.

Typical adverse events reported appeared to be relatively mild:

"The P-CAP combination was well-tolerated with Grade 3 and 4 adverse events of > 10% incidence for the P-CAP arm versus CAP arm as follows: anemia (15% vs. 0%), fatigue (0% vs. 11%), abdominal pain (5% vs. 11%), and hand-foot syndrome (30% vs. 0%)."

Perifosine is also being developed for the treatment of multiple myeloma, which is currently in phase III development. The compound is an inhibitor of Akt and phosphoinositide 3-kinase (PI3K), as well as other pathways such as JNK and MAPK. These pathways are associated with programmed cell death (apoptosis), cell growth, cell differentiation and cell survival as shown in the diagram below:

Source: Aeterna Zentaris

Interestingly, this morning's news brought an announcement that the FDA have granted Fast Track Designation for the perifosine in advanced, refractory colorectal cancer. Based on the phase II data, a randomised phase III trial is expected to begin this quarter based on a similar trial design.

Clearly, it will be a little while before the data is available, but definitely one to watch out for in the future given new therapy options are always needed in the refractory cancer setting.

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Merck KGaA reviewing cardiac data for Erbitux in lung cancer trials

By MaverickNY on March 25, 2010

"Merck KGaA is reviewing heart risks of its tumor-fighting Erbitux drug in several types of cancer after European regulators asked for more information on the treatment’s safety.

The European Medicines Agency requested the review after rejecting Erbitux for use in lung cancer patients, according to a report published online on March 12. The drug regulator identified an “increased incidence of cardiac events” in lung cancer patients age 65 years or more, in particular high-risk patients with a history of heart problems."

Source: Bloomberg

This was an interesting snippet of news that I saw in the mass of alerts this morning, and no obvious press release from any of the companies involved with the drug, Merck KGaA (in Europe), BMS or Imclone (US partners).

Part of the problem here is that many people with lung cancer also tend to have cardiac co-morbidities and thus the two may go hand in hand. To be fair, similar side effects have not apparently been reported in other cancers, such as colon cancer.

If the analysis reveals negative findings, then it may lead to changes in the prescribing information, which will not be good news. Of course, the company are hopeful that will not happen, because changes in the EU labelling for Erbitux (cetuximab) may subsequently impact the US one too.

Merck are already having a rough week on the issues management and communications front with the suspension of the Stimuvax trials after a patient being treated with the vaccine developed encephalitis. At least the current issue didn't get reported on a Friday!

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Bench to Bedside: How can we speed up cancer drugs to the clinic?

By MaverickNY on March 18, 2010

After yesterday's post about the I-SPY trials in neoadjuvant therapy for breast cancer and how they may speed up the process of bringing new innovative cancer drugs to the clinic faster, I was reflecting on my own experiences with imatinib (Gleevec).

The Philadelphia Chromosome was first identified in 1960 by Nowell and Hungerford. Gleevec was finally approved by the FDA in May 2001, 41 years later.

Between 1999, when I arrived in the US and working in New Product Development at Novartis until 2001 when Gleevec was launched, I attended scientific meetings including AACR, ASH and ASCO. Often, Dr Judah Folkman, a scientific researcher from Harvard, would talk about angiogenesis and hypothesised that was the principal mechanism by which tumours grew. I listened to his ideas many times because I was curious and found the concept both fascinating and intuitive. There was a long line of drugs that failed to work though, and every meeting seemed to bring yet more negative results.

Now, Folkman first advanced the angiogenesis theory in 1971 in the New England Journal of Medicine, but it wasn't until 2002, when bevacizumab (Avastin), a VEGF inhibitor that prevented angiogenesis from happening, was finally approved for the treatment of colon cancer. At that point you go, 'oh wow' and realise that Folkman's theory was indeed proven correct.

Thus a tale of two incredible cancer drugs that both took a relatively long time to evolve from scientific idea to effective treatment in people with cancer. Or perhaps they were actually relatively 'quick' compared to others, but why it takes this long is something we can surely do better at.

Last night I was researching ideas for drug development and innovation since the concept of bench to bedside fascinates me and came across this enlightening video from a lunchtime talk that Dr Susan Desmond-Hellmann gave last year at UCSF. Oddly, she seems to have trodden similar thought processes and asked why and how can we speed things up as well.

The short lecture is well worth listening to for those interested in drug development – the good doctor explains the bench to bedside concept far better than I:

Sources for scholars and clinical scientists:

The NEJM doesn't appear to go back beyond 1993 online, but the original reference to Folkman's article is at:

Folkman J. Tumor angiogenesis: therapeutic implications. N Engl J Med 1971;285:1182-1186.

A more recent one from 1995, which provides an update is available online at: NEJM

Roche's ocrelizumab and AstraZeneca's cediranib bite the dust

By MaverickNY on March 8, 2010

This week kicked off with some interesting emails and alerts in my inbox.

You may well be wondering what on earth rheumatoid arthritis and colorectal cancer have in common. The answer is that yet more agents in development have bitten the dust.

Firstly, it seems that Roche and Biogen Idec have announced that they are suspending the development of their humanised anti-CD20 monoclonal antibody, ocrelizumab, for treatment of rheumatoid arthritis (RA) and Lupus.

This follows a recommendation of the independent Data and Safety Monitoring Board (DSMB) based on their assessment of the studies in RA. The review detected an infection related safety signal which included serious and opportunistic infections, some of which were fatal.

According to the Roche press release:

"As previously announced, the FILM study in MTX-naïve RA patients was placed on clinical hold following an assessment of benefit to risk in this specific RA patient population. In addition, the BELONG study in lupus nephritis patients was previously halted due to serious and opportunistic infection signals."

The trials in multiple sclerosis appear to be ongoing. Their other CD20 antibody, rituximab, has been on the market for several years for the treatment of cancers such as non-Hodgkins Lymphoma (NHL) and more recently, chronic lymphocytic leukemia (CLL). There have been no safety issues with this product.

Oddly, the second agent that flopped today went up against Roche's Avastin and was found to fall short of the required hurdle in a large phase III trial. AstraZeneca's cediranib (Recentin), is a oral small molecule VEGF inhibitor that was being evaluated for the treatment of colorectal cancer (CRC).

According to AstraZeneca's press release this morning:

"This study, HORIZON III, assessed the efficacy of cediranib compared with bevacizumab, both in combination with chemotherapy. Clinical activity was observed in the cediranib arm of the study and there was no statistically significant difference between treatment arms on the efficacy endpoints examined. However, the efficacy did not meet the pre-specified criteria for the primary endpoint of non-inferiority in progression-free survival."

Ouch!

However, these results are not entirely surprising given the previous failure of Novartis' vatalanib in CRC, another small molecule inhibitor, in phase III trials for colorectal cancer. There may well be some quirk in the mechanism of action in colorectal cancer that preferentially allows monoclonal antibodies to work more effectively than small molecules. The half life, dosing schedules or inhibiting the ligand differently could all play a crucial part in the process.

For AstraZeneca, though, their run of bad luck in oncology continues with Iressa, Zactima and now Recentin all struggling to make a major impact.

Photo Credit: Kiragon

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Cancer biology is becoming very complex #AACR

By MaverickNY on January 26, 2010

As we learn more about the biology of cancer, I’m finding that rather becoming simpler, it actually seems much more complex and sophisticated than we may have first realised.

Sometimes, we don’t know what we don’t know.

Take for example, the recent AACR meeting on the molecular origins of lung cancer that I attended and wrote a few summary posts on (with more to come!)

There was a particularly fascinating lecture from Robert Kerbel, who looked at the role of tyrosine kinase inhibitors (TKIs) in metastatic cancer. He noted that there have been many successful trials with TKI’s, with a two month improvement in survival being typical. There have also been failures, such as bevacizumab (Avastin) in 1st line pancreatic cancer, 2nd and 3rd line breast cancer and adjuvant colorectal cancer.

Numerous theories associated with how anti-angiogenic agents work, including the normalisation of blood vessels, allowing more drug to be delivered to the tumour and several other hypotheses have also been floated around.

What struck me though, was that the switch to a different concept, one where there are early indications that anti-angiogenic therapy actually promotes invasion and metastasis, for example in glioblastoma. Dr Kerbel then showed some scans clearly showing disease progression and growth and asked whether bevacizumab actually increases the aggressiveness of a metastatic tumour over time?

The evidence for this concept came from an paper published in Cancer Cell in 2009 by Paez-Ribes et al.,:

“The realization that potent angiogenesis inhibition can alter the
natural history of tumors by increasing invasion and metastasis
warrants clinical investigation, as the prospect has important
implications for the development of enduring antiangiogenic therapies.”

This invasion effect has been shown in bevacizumab and sunitinib (Sutent), both potent inhibitors of VEGF, so clearly the effect is a class one.

Kerbel discussed what else could explain the results other than increased tumour hypoxia?

Another idea looked at dose dependent circulating levels of plasma VEGF, which Ebos et al., proposed and was subsequently noted with sunitinib in phase II human breast cancer trials reported by Harold Burstein.

The issue then becomes one of potential consequences. Thus, plasma VEGF levels may explain drug resistance seen with anti-angiogenic agents, rapid tumour regrowth and rebound revascularisation may occur once therapy is stopped and an increase in malignant aggressiveness may be seen as invasion and metastasis increases.

The other question on my mind is why is there differences observed in adjuvant and metastatic disease as we have discussed previously with the negative bevacizumab results in adjuvant colorectal cancer. It is possible, based on these observations that treatment with anti-angiogenic agents may have the opposite effect to that intended by hastening progression and thus such therapies may be better suited to the metastatic setting.

The big question now is figuring out how to overcome the drug resistance seen with these agents while minimising the vascular stimulation effects seen.

Pàez-Ribes, M., Allen, E., Hudock, J., Takeda, T., Okuyama, H., Viñals, F., Inoue, M., Bergers, G., Hanahan, D., & Casanovas, O. (2009). Antiangiogenic Therapy Elicits Malignant Progression of Tumors to Increased Local Invasion and Distant Metastasis Cancer Cell, 15 (3), 220-231 DOI: 10.1016/j.ccr.2009.01.027

Ebos, J., Lee, C., Cruz-Munoz, W., Bjarnason, G., Christensen, J., & Kerbel, R. (2009). Accelerated Metastasis after Short-Term Treatment with a Potent Inhibitor of Tumor Angiogenesis Cancer Cell, 15 (3), 232-239 DOI: 10.1016/j.ccr.2009.01.021

Loges, S., Mazzone, M., Hohensinner, P., & Carmeliet, P. (2009). Silencing or Fueling Metastasis with VEGF Inhibitors: Antiangiogenesis Revisited Cancer Cell, 15 (3), 167-170 DOI: 10.1016/j.ccr.2009.02.007

Ebos, J., Lee, C., Christensen, J., Mutsaers, A., & Kerbel, R. (2007). Multiple circulating proangiogenic factors induced by sunitinib malate are tumor-independent and correlate with antitumor efficacy Proceedings of the National Academy of Sciences, 104 (43), 17069-17074 DOI: 10.1073/pnas.0708148104

Burstein, H., Elias, A., Rugo, H., Cobleigh, M., Wolff, A., Eisenberg, P., Lehman, M., Adams, B., Bello, C., DePrimo, S., Baum, C., & Miller, K. (2008). Phase II Study of Sunitinib Malate, an Oral Multitargeted Tyrosine Kinase Inhibitor, in Patients With Metastatic Breast Cancer Previously Treated With an Anthracycline and a Taxane Journal of Clinical Oncology, 26 (11), 1810-1816 DOI: 10.1200/JCO.2007.14.5375

Ebos JM, Lee CR, Cruz-Munoz W, Bjarnason GA, Christensen JG, & Kerbel RS (2009). Accelerated metastasis after short-term treatment with a potent inhibitor of tumor angiogenesis. Cancer cell, 15 (3), 232-9 PMID: 19249681

Pharma Strategy Blog

Commentary on Pharma & Biotech Oncology / Hematology New Product Development

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