Archive for March, 2011

AACR 2011 ~ 102nd meeting

The American Association for Cancer Research (AACR) is the oldest and largest scientific organization in the world focused on every facet of cancer research. AACR was founded in 1907 by 11 physicians and scientists interested in research with the goal to “to further the investigation and spread the knowledge of cancer.” Since then, the AACR has grown to 33,000 members and publishes seven peer-reviewed journals: Cancer Research; Clinical Cancer Research; Molecular Cancer Therapeutics; Molecular Cancer Research; Cancer Epidemiology, Biomarkers & Prevention; and Cancer Prevention Research, and launched a new journal in 2010, Cancer Discovery.

AACR’s mission is to accelerates progress toward the prevention and cure of cancer by promoting research, education, communication, and collaboration.

The 102nd Annual Meeting 2011 begins April 2 in Orlando FL and will feature over 6000 abstracts presented by basic science, translational, and clinical researchers. Over 17,000 attendees and presenters will learn in a variety of settings: plenary lectures, symposia, minisymposia, workshops, poster sessions, and other formats.

A selection of neuroblastoma-related presentations

Several presentations and posters on neuroblastoma are of interest. Click on the title to see the abstract on AACR site.

4336/4 – Oncolytic reovirus as a novel therapy for neuroblastoma Amelia Kellar, Nicole Redding, Karen Blote, Qiao Shi, Jason Spurrell, Paul Beaudry, Don Morris. University of Calgary, Calgary, AB, Canada Poster Session

4340/8 – Sorafenib induces growth arrest and apoptosis in neuroblastoma cells via inhibition of JAK2/STAT3 and MEK1/2/MAPK (p44/42) signaling pathways Fan Yang1, Veronica Jove1, Ralf Buettner1, Hong Xin1, Sangkil Nam1, Tasnim Ara2, Yves A. DeClerck2, Robert C. Seeger2, Hua Yu1, Richard Jove1. 1City of Hope, Duarte, CA; 2The Saban Research Institute of Children’s Hospital Los Angeles, Los Angeles, CA Poster Session

4346/14 – Differential response of a novel protein kinase C-iota inhibitor (ICA-1) on neuroblastoma cells Prajit P. Pillai, Mildred Acevedo-Duncan. Univ. of South Florida, Tampa, FL Poster Session

954 – ABCC/MRP multidrug transporters contribute to neuroblastoma biology, pathogenesis and clinical outcome, independently of any role in cytotoxic drug efflux Murray D. Norris1, Michelle J. Henderson1, Antonio Porro2, Marcia Munoz1, Nunzio Iraci2, Chengyuan Xue1, Jayne Murray1, Claudia Flemming1, Jamie Fletcher1, Samuele Gherardi2, Alan Kwek1, Amanda Russell1, Wendy B. London3, Allen B. Buxton3, Lesley Ashton1, Alan C. Sartorelli4, Susan L. Cohn5, Manfred Schwab6, Glenn M. Marshall1, Giovanni Perini2, Michelle Haber1. 1Children’s Cancer Institute Australia, Sydney, Australia; 2University of Bologna, Bologna, Italy; 3University of Florida and Children’s Oncology Group Statistics and Data Center, Gainesville, FL; 4Yale University School of Medicine, New Haven, CT; 5University of Chicago, Chicago, IL; 6German Cancer Research Center, Heidelberg, Germany Minisymposium

4758 – Inhibition of checkpoint kinase 1 (Chk1) as a potential therapeutic for pediatric neuroblastoma Mike R. Russell, Kristina A. Cole, John M. Maris. Children’s Hospital of Philadelphia, Philadelphia, PA Minisymposium

LB-312/3 – Methylated RASSF1a is the first specific DNA marker for minimal residual disease testing in neuroblastoma Janine Stutterheim, Fatima Ait Ichou, Emmy Den Ouden, Rogier Versteeg, Huib N. Caron, Godelieve A.M. Tytgat, C. Ellen Van der Schoot. Sanquin, Amsterdam, Netherlands, Academic Medical Center, Amsterdam, Netherlands

4563/5 – Antibody targeting of anaplastic lymphoma kinase induces cytotoxicity of human neuroblastoma Erica L. Carpenter1, Elizabeth A. Haglund1, Adrian K. Chow1, Andrew C. Wood1, Lili T. Belcastro1, James G. Christensen2, Marc Vigny3, John M. Maris1, Mark A. Lemmon4, Yael P. Mosse1. 1Children’s Hospital of Philadelphia, Philadelphia, PA; 2Pfizer Global Research and Development, La Jolla, CA; 3INSERM, Paris, France; 4University of Pennsylvania, Philadelphia, PA Poster Session

LB-366/11 – Patient-derived EBV-immortalized B-lymphocytes are a dominant contaminant of in vitro cultured human neuroblastoma tumor-initiating cells isolated from bone marrow. Sven Påhlman, Sofie A. Johnsson, Alexander Pietras, Caroline Wigerup, Ingrid Øra, Michael Andäng, Kenneth Nilsson, Tor Olofsson, David Gisselsson. Lund Univ., Malmö, Sweden, Lund Univ., Lund, Sweden, Karolinska Institute, Stockholm, Sweden, Uppsala Univ., Uppsala, Sweden Late-Breaking Poster Session

742/26 – Mechanisms of resistance to small molecule inhibition of anaplastic lymphoma kinase in human neuroblastoma Erica L. Carpenter1, Elizabeth A. Haglund1, Adrian K. Chow1, James G. Christensen2, John M. Maris1, Yael P. Mosse1. 1Children’s Hospital of Philadelphia, Philadelphia, PA; 2Pfizer Global Research and Development, La Jolla, CA Poster Session

3942/29 – A pilot trial testing the feasibility of using molecular-guided therapy in patients with refractory or recurrent neuroblastoma Giselle L. Saulnier Sholler1, Javed Kahn2, William Ferguson3, Genvieve Bergendahl1, Erika Currier1, Shannon Lenox1, Jeffrey Bond1, William Roberts4, Deanna Mitchell5, Don Eslin6, Jacqueline Kraveka7, Joel Kaplan8, Nehal Parikh9, Suman Malempati10, Gina Hanna11, Barton Kamen12, Craig Webb13. 1University of Vermont, Burlington, VT; 2National Institute of Health, Bethesda, MD; 3St. Louis University School of Medicine, St. Louis, MO; 4University of California San Diego School of Medicine, San Diego, CA; 5Michigan State University, Grand Rapids, MI; 6MD Anderson Cancer Center Orlando, Orlando, FL; 7Medical University of South Carolina, Charleston, SC; 8Levine Children’s Hospital, Charlotte, NC; 9Connecticut Children’s Medical Center, Hartford, CT; 10Oregon Health & Science University, Portland, OR; 11Inova Fairfax Hospital for Children and Women, Falls Church, VA; 12Cancer Institute of New Jersey, New Brunswick, NJ; 13Van Andel Research Institute, Grand Rapids, MI Poster Session

1558/6 – Paracrine signaling through Mycn enhances tumor-vascular microenvironment in neuroblastoma Yvan H. Chanthery, W. Clay Gustafson, William A. Weiss. UCSF, San Francisco, CA Poster Session

4350/18 – Translating diagnostic gene expression profiles for pediatric solid tumors Daniel H. Wai1, Michele R. Wing2, Kelley Kneile2, Yvonne Moyer2, Jonathan D. Buckley3, Robert C. Seeger4, Douglas S. Hawkins5, Stephen X. Skapek6, Timothy J. Triche4. 1Center for Personalized Medicine, Los Angeles, CA; 2The Research Institute at Nationwide Children’s Hospital, Columbus, OH; 3University of Southern California, Los Angeles, CA; 4Children’s Hospital Los Angeles, Los Angeles, CA; 5Seattle Children’s Hospital, Seattle, WA; 6University of Chicago, Chicago, IL Poster Session

5237/25 – Development of organ-selective neuroblastoma cell lines to identify genes mediating bone marrow and liver colonization Zillan Neiron1, Kacper Jankowski1, Jayne Murray1, Sophia Champion2, Murray D. Norris1, Michelle Haber1, Jamie I. Fletcher1. 1Children’s Cancer Institute Australia, Randwick, NSW, Australia; 2University of New South Wales, Kensington, NSW, Australia Poster Session

130/14 – MiR-204 acts as a tumor suppressor in neuroblastoma through down-regulation of the neurotrophic receptor TrkB Jacqueline M. Ryan1, Amanda Tivnan1, Isabella Bray1, Joanna Fay1, Andrew M. Davidoff2, Lorraine Tracey2, Raymond Stallings1. 1Royal College of Surgeons in Ireland & National Children’s Research Centre, Dublin, Ireland; 2St. Jude Children’s Research Hospital, Memphis, TN Poster Session

4685 – Mechanistic guidance of ALK inhibition for the treatment of neuroblastoma Scott C. Bresler1, Andrew Wood2, Elizabeth Haglund2, James Christensen3, John M. Maris2, Mark A. Lemmon1, Yael P. Mosse2. 1University of Pennsylvania School of Medicine, Philadelphia, PA; 2Children’s Hospital of Philadelphia, Philadelphia, PA; 3Pfizer Inc., La Jolla, CA Minisymposium

1808/28 – Neuroblastoma cell lines established from progressive disease that exhibit partial or multi drug resistance are highly sensitive to chimeric receptor scFv(ch14.18)-zeta mediated NK cell killing Diana Seidel1, Anastasia Shibina2, C. Patrick Reynolds2, Winfried S. Wels3, Holger N. Lode1, Nicole Huebener1. 1University Medicine Greifswald, Greifswald, Germany; 2Texas Tech University Health Sciences Center, Lubbock, TX; 3Chemotherapeutisches Forschungsinstitut, Georg-Speyer-Haus, Frankfurt, Germany Poster Session

508/4 – Signal transduction and activator of transcription (STAT) 3 is necessary for environment-mediated drug resistance Tasnim Ara1, Rie Nakata1, Hiroyuki Shimada1, Ralf Buettner2, Robert C. Seeger1, Hua Yu2, Richard Jove2, Yves A. DeClerck1. 1USC/Children’s Hospital Los Angeles, Los Angeles, CA; 2Beckman Research Institute/City of Hope, Duarte, CA Poster Session

926 – Whole genome and transcriptome sequencing defines the spectrum of somatic changes in high-risk neuroblastoma Olena Morozova1, Inanc Birol1, Richard Corbett1, Karen Mungall1, Edward F. Attiyeh2, Shahab Asgharzadeh3, Yongjun Zhao1, Richard A. Moore1, Martin Hirst1, Steven Jones1, Michael D. Hogarty2, Sharon Diskin2, Yael P. Mosse2, Maura Diamond2, Richard Sposto3, Lingyun Ji3, Daniela S. Gerhard4, Malcolm A. Smith4, Javed Khan4, Robert C. Seeger3, Marco A. Marra5, John M. Maris2, the NCI TARGET Initiative. 1Genome Sciences Centre, BC Cancer Agency, Vancouver, BC, Canada; 2Children’s Hospital of Philadelphia and University of Pennsylvania School of Medicine, Philadelphia, PA; 3Children’s Hospital of Los Angeles and Keck School of Medicine, University of Southern California, Los Angeles, CA; 4National Cancer Institute, Bethesda, MD; 5Genome Sciences Centre, BC Cancer Agency and Department of Medical Genetics, University of British Columbia, Vancouver, BC, Canada Minisymposium

1800/20 – 4-HPR (fenretinide) sensitizes human neuroblastoma cells for antibody-independent and ch14.18-mediated NK cell killing Anastasia Shibina1, Diana Seidel2, Srinivas Somanchi3, Holger N. Lode2, Dean A. Lee3, C.Patrick Reynolds1, Nicole Huebener2. 1Texas Tech Univ. Health Sciences Ctr., Lubbock, TX; 2University Medicine Greifswald, Pediatric Hematology/Oncology, Greifswald, Germany; 3The University of Texas MD Anderson Cancer Center, Houston, TX Poster Session

1423/15 – Effects of DFMO-based combination therapy in advanced stage neuroblastoma Dana-Lynn T. Koomoa, Ingo Lange, Andre S. Bachmann. University of Hawaii, College of Pharmacy, Hilo, HI Poster Session

TARGET Project Team Highlights: Neuroblastoma Javed Khan. National Insts. of Health, Bethesda, MD NCI/NIH-Sponsored Session

NIH15. The NCI Therapeutically Applicable Research to Generate Effective Treatments (TARGET) Initiative: Using Large-Scale Genomics to Identify Novel Therapeutic Targets for Childhood Cancers

Towards a personalized approach to pediatric cancer management: Neuroblastoma as an example John M. Maris. Children’s Hospital of Philadelphia, Philadelphia, PA Major Symposium
Recent Findings from Genomic Analyses of Tumors

5359/30 – Cytotoxicity of MLN8237 and SAHA in pediatric cancer cell lines Jodi Muscal1, Kathy Scorsone1, Jeffrey Ecsedy2, Stacey Berg1. 1Baylor College of Medicine, Houston, TX; 2Millenium Pharmaceuticals, Inc., Cambridge, MA Poster Session

4756 – Exome sequencing of 81 neuroblastomas identifies a wide diversity of somatic mutation Trevor J. Pugh1, Michael Lawrence1, Carrie Sougnez1, Gad Getz1, Edward Attiyeh2, Michael Hogarty2, Sharon Diskin2, Mosse Yael2, Maura Diamond2, Shahab Asgharzadeh3, Richard Sposto3, Jun S. Wei4, Thomas Badgett4, Wendy B. London5, Julie Gastier-Foster6, Malcolm A. Smith4, Daniela S. Gerhard4, Robert Seeger3, Javed Khan4, Matthew L. Meyerson1, John M. Maris2, NCI Therapeutically Applicable Research to Generate Effective Treatments (TARGET) Initiative. 1The Broad Institute of MIT and Harvard, Cambridge, MA; 2Children’s Hospital of Philadelphia, Philadelphia, PA; 3Children’s Hospital of Los Angeles, Los Angeles, CA; 4National Cancer Institute, Bethesda, MD; 5Dana-Farber Cancer Institute and Children’s Oncology Group Statistic and Data Center, Boston, MA; 6Nationwide Children’s Hospital, Columbus, OH Minisymposium

Overview of environment: Mediated drug resistance Yves A. DeClerck. USC/Children’s Hospital Los Angeles, Los Angeles, CA Educational Session

 

Leave a Comment

March 31, 2011 · Filed under Meetings

Two years of cis-retinoic acid

A new trial opens: prolonged use of isotretinoin

Aflac ST1001 Prolonged Isotretinoin

Dr Howard Katzenstein at Emory University (Aflac) in Atlanta Georgia is the principal investigator of a single-institution trial to explore the prolonged use of isotretinoin (13-cis retinoic acid, cisRA, and also known as”Accutane”). The phase I trial will accrue 20 children/young adults (under 30 years old) who will take isotretinoin after frontline therapy for 24 months instead of the current protocol using 6 months. The study will look at progression-free survival and toxicities, including bone growth and psychological effects.
.
Children will be enrolled after completing high-risk therapy. Since the COG-ANBL0931 ch14.18 antibody trial is also open at that institution, the prolonged use of isotretinoin trial will be offered to those children who do not qualify or refuse the ch14.18 trial.
.
This may be a promising strategy for increasing survival, but this is a small study and any survival advantage must be dramatic to be statistically significant. The toxicities of prolonged use of this dose isotretinoin in young children are unknown. In Germany, the GPOH frontline protocol current uses the same daily dose 160 mg/m2/d for 14 days per 28 day cycle for 6 months, 3 month break, and then another 3 months.
.
Effect on bone growth?

Growth in survivors of high-risk neuroblastoma can be affected by deficiency in growth hormones, as well as premature closure of growth plates in the long bones. Dr Lisa Diller (Boston Children’s/Dana-Farber Cancer Institute) reviewed recent published data on late effects and presented new data in the Neuroblastoma Update Course the Advances in Neuroblastoma Research (ANR) meeting last June in Stockholm, Sweden[1]. She mentioned evidence from institutional data from CHOP (just published this month) that advanced bone age or epiphyseal closure and short stature is more common in children treated with cis-retinoic acid[2]. This report provides new evidence for careful consideration of long-term use of isotretinoin in small children.

Effect on emotions?

Since this drug is used in large numbers of adolescents and young adults for severe acne, a large amount of data has been accumulated on psychopathology, or psychological effects. A 2009 comprehensive review of the data concludes:

The evidence described in this review strongly suggests a link between the use of isotretinoin and psychopathology. There is a great number of reports that support this association. Interestingly, isotretinoin is the only non-psychotropic drug in the FDA’s top 10 list of drugs associated with depression. By contrast, the absence of double-blind, placebo-controlled studies, some flaws in the methodology of the current literature and some contradicting results in the studies of animal models seem to be the major reasons for the lack of an established causal link between isotretinoin use and psychiatric symptoms. However, given all the evidence, the association between isotretinoin use and psychopathology seems most likely to be justified. The multiformity of reported psychiatric adverse events (depression, suicide, psychosis) is probably associated with the multiplicity of isotretinoin’s effects on various neurotransmitter systems and with the various types of vulnerability of the exposed individuals. Therefore, clinicians should be on the alert for potential psychiatric side effects following treatment with isotretinoin, especially in vulnerable populations. [3]

An important point for neuroblastoma parents to note, however, is that all of the psychopathology reports on this drug to date have been on patients treated for acne, not neuroblastoma. The significant difference is in the dose used. Acne patients get between 0.1 -1.0 mg/kg/day, which is at most one-fifth the dose that is prescribed for children with neuroblastoma (roughly 5 mg/kg/day, given 14 days with 14 days rest). This review provides evidence that careful consideration is suggested with prolonged use of high-dose isotretinoin in adolescents and young adults.

Since survival advantage has been demonstrated by the use of isotretinoin in 1999, parents have often questioned why isotretinoin is only used for 6 months. Why not longer? This new trial may provide some answers to these questions, and all these points merit discussion with pediatric oncologists treating children with neuroblastoma.

 

References

1. ANR 2010 “Neuroblastoma Update Course” ANR 2010 Abstract Programme, p 80.

2. Prevalence of advanced bone age in a cohort of patients who received cis-retinoic acid for high-risk neuroblastoma. Pediatr Blood Cancer. 2011 Mar;56(3):474-6.

3. Isotretinoin and psychopathology: a review Ann Gen Psychiatry. 2009 Jan 20;8:2. PMCID: PMC2637283

 

Leave a Comment

March 24, 2011 · Filed under Clinical Trials

New antibody trials in 2011

Antibodies for relapsed neuroblastoma

Given that recent studies such as COG-3973 [1] and others reveal that half or more of all children with high-risk neuroblastoma are refractory to induction or relapse, and that the majority worldwide never received antibodies as part of frontline treatment, there is currently a significant demand for access to antibody treatment after relapse.

Currently, the only offerings of antibodies for relapse are:

  • 3F8 (murine) at Memorial-Sloan Kettering Cancer Center,
  • ch14.18/CHO (chimeric) at Griefswald in Germany, and
  • hu14.18K322A (humanized) at St Jude’s, Memphis TN

Memorial-Sloan Kettering Cancer Center (MSKCC) in New York has been using 3F8 antibodies in the relapse setting for 20 years or more [2]. Ideally the relapsed disease must first be reduced to minimal or undetectable levels. Dr Kushner presented at ASCO in 2007 showing that 20% of children with bone marrow refractory disease became long term survivors [3]. Bone disease and soft tissue relapses are less responsive to 3F8. Since MSKCC uses a 100% mouse antibody, the child can make antibodies against the 3F8, called HAMA, for human anti-mouse antibodies. These antibodies prevent further treatment with 3F8, unless HAMA can be reduced using Rituxan (rituximab) and waiting for HAMA to subside. Rituxan, also an antibody, targets CD20 that is highly expressed on B-cells which are responsible for making antibodies. Prior to beginning treatment with 3F8, high doses of cyclophosphamide are given (4200 mg/m2) in order to reduce the immune system’s capacity to produce HAMA.

MSKCC has opened various 3F8 trials in the past decade, including heat-modified [4], with beta-glucan, high-dose, and use after donor (parent) NK cells, with the latter two open currently for relapse. The Band of Parents funds neuroblastoma projects at MSKCC and anticipates a humanized version of 3F8 and a “turbo” version of 3F8 to be available in 2011 for children with relapsed or refractory disease. In short, antibodies have been available for relapse at MSKCC for the past 20 years.

Meanwhile, the chimeric (25% mouse/75% humanized) antibody ch14.18 given with IL2 and GM-CSF that improved the two-year event-free survival by 20% over the no-antibody arm is now available to all children as part of frontline treatment in the COG (North America and Australia). Randomization was stopped after early review in March 2009, and the study continues to accrue for more safety and efficacy data (COG-ANBL0032), as well as an additional study open for the registration data to gain FDA approval (COG-ANBL0931). This antibody is not currently available to relapsed children in the COG. A NANT trial for relapsed children will open in late 2011 with ch14.18 in combination with lenalidomide (stimulates production of natural cytokines in the tumor environment), and NED (remission) after relapse will be eligible.

In Europe, the availability of ch14.18/CHO (produced from hamster rather than mouse cells) for frontline treatment is limited to those treated on the current SIOP high-risk protocol. The study has been modified several times since it opened in 2002. These randomization arms have closed:

  • G-CSF or no G-CSF –all get G-CSF after showing less neutropenia, fever, hospitalization days, chemo delays [5]
  • busulfan + melphalan (BuMel) or carboplatin + etoposide + melphalan --all now receive BuMel for survival advantage [not published as of 3/2011]
  • ch14.18 or no ch14.18 –all get ch14.18 with or without subcutaneous IL2 [trial listing not updated as of 3/2011]

Dr Holger Lode has a trial open to treat relapsed and refractory neuroblastoma with ch14.18 and IL2 at Griefswald in Germany. In the past year families have traveled from the UK, Australia, and other countries to access this treatment.

A COG trial using hu14.18-IL2 with GM-CSF and cis-retinoic acid is opening very soon, and will be open to relapsed and refractory neuroblastoma with measurable or detectable disease (second response will not be eligible). This is a humanized antibody with IL2 fused directly to the antibody. It has completed phase I and phase II studies in neuroblastoma and melanoma, and a pilot is ongoing for melanoma at University of Wisconsin-Madison.

Now that hu14.18-IL2 and ch14.18 are licensed to Apeiron and United Therapeutics respectively, availability for trials will be governed by these companies.

Extrapolating the annual incidence of high-risk neuroblastoma and relapse, a minimum of 800 children in SIOP and COG countries will require ch14.18 for frontline treatment every year, and potentially another 400 for relapse treatment. Hopefully, this demand will be satisfied soon. Since melanoma expresses GD2 also, these anti-GD2 antibodies may be in demand to treat melanoma also.

 

References

 

1. Response and toxicity to a dose-intensive multi-agent chemotherapy induction regimen for high risk neuroblastoma (HR-NB): A Children’s Oncology Group (COG A3973) study. Journal of Clinical Oncology, 2007 ASCO Annual Meeting Proceedings Part I. Vol 25, No. 18S (June 20 Supplement), 2007: 9505

2. GM-CSF enhances 3F8 monoclonal antibody-dependent cellular cytotoxicity against human melanoma and neuroblastoma. Blood. 1989 May 15;73(7):1936-41.

3. Anti-GD2 monoclonal antibody 3F8 plus granulocyte-macrophage colony-stimulating factor (GM-CSF) for primary refractory neuroblastoma (NB) in bone marrow (BM). Journal of Clinical Oncology, 2007 ASCO Annual Meeting Proceedings Part I. Vol 25, No. 18S (June 20 Supplement), 2007: 9502

4. Successful Multifold Dose Escalation of Anti-GD2 Monoclonal Antibody 3F8 in Patients With Neuroblastoma: A Phase I Study; J Clin Oncol. 2011 Feb 22.

5. Randomized Trial of prophylactic granulocyte colony-stimulating factor during rapid COJEC induction in pediatric patients with high-risk neuroblastoma: the European HR-NBL1/SIOPEN study. J Clin Oncol. 2010 Jul 20;28(21):3516-24. Epub 2010 Jun 21.

Creative Commons Attribution-NonCommercial-ShareAlike 3.0 Unported This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 3.0 Unported.

Leave a Comment

March 12, 2011 · Filed under Clinical Trials, General

This site is protected by WP-CopyRightPro