Tumor Survivin Is Downregulated by the Antisense Oligonucleotide LY2181308: A Proof-of-Concept, First-in-Human Dose Study

Talbot, Denis; Ranson, Malcolm R; Davies, J.; Lahn, Michael; Callies, Sophie; Andre, Valérie; Kadam, Sunil; Burgess, Michael; Slapak, Christopher A.; Olsen, Anna L; McHugh, Peter J.; Bono, Johann S. de; Matthews, Julian C.; Saleem, Azeem; Price, Patricia M

doi:10.1158/1078-0432.ccr-10-1932

Cited by 93 publications

(71 citation statements)

References 29 publications

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“…Despite this, early proof-of-concept studies and encouraging phase 2 efficacy data demonstrate that with higher doses, generation-2.0 ASOs targeted to either survivin (LY2181308) or clusterin (OGX-011, custirsen) resulted in the inhibition of their target RNA and protein levels in tumor cells of cancer patients. 125,126 In the case of OGX-011, encouraging signs of clinical efficacy were also observed where increased time to progression-free survival was demonstrated in a phase 2 prostate cancer trial. 127,128 Unfortunately, however, a more recent evaluation of the top-line results from the phase 3 SYNERGY Trial of OGX-011 in advanced prostate cancer did not meet its primary end point.…”

Section: Clinical Experience With Mrna Targeting Single-stranded Asosmentioning

confidence: 95%

RNA Therapeutics in Oncology: Advances, Challenges, and Future Directions

MacLeod

Crooke

2017

The Journal of Clinical Pharma

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RNA-based therapeutic technologies represent a rapidly expanding class of therapeutic opportunities with the power to modulate cellular biology in ways never before possible. With RNA-targeted therapeutics, inhibitors of previously undruggable proteins, gene expression modulators, and even therapeutic proteins can be rationally designed based on sequence information alone, something that is not possible with other therapeutic modalities. The most advanced RNA therapeutic modalities are antisense oligonucleotides (ASOs) and small interfering RNAs. Particularly with ASOs, recent clinical data have demonstrated proof of mechanism and clinical benefit with these approaches across several nononcology disease areas by multiple routes of administration. In cancer, next-generation ASOs have recently demonstrated single-agent activity in patients with highly refractory cancers. Here we discuss advances in RNA therapeutics for the treatment of cancer and the challenges that remain to solidify these as mainstay therapeutic modalities to bridge the pharmacogenomic divide that remains in cancer drug discovery.

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Section: Clinical Experience With Mrna Targeting Single-stranded Asosmentioning

confidence: 95%

RNA Therapeutics in Oncology: Advances, Challenges, and Future Directions

MacLeod

Crooke

2017

The Journal of Clinical Pharma

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“…We agree that targeting survivin in HNSCC is a strategy worthy of exploration, though, at present, limited numbers of patients treated in clinical trials [2,3] …”

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confidence: 86%

In Reply: Response to Marioni

Church

Talbot

2012

Curr Oncol Rep

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“…in optimizing anti-cancer drugs [7], as up-regulation of pumps that exclude drugs from tumours is well described [8]. PET biodistribution studies can be integrated with conventional stable isotope DMPK studies [9] or with pharmacodynamic measures [10]. It is important to recognize, however, that it is the distribution of the radionuclide, not the molecule, that is directly measured in the PET experiment.…”

Section: Marketed Drugsmentioning

confidence: 99%

Positron emission tomography molecular imaging for drug development

Matthews

Rabiner

Passchier

et al. 2012

Brit J Clinical Pharma

291

193

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Human in vivo molecular imaging with positron emission tomography (PET) enables a new kind of 'precision pharmacology' , able to address questions central to drug development. Biodistribution studies with drug molecules carrying positron-emitting radioisotopes can test whether a new chemical entity reaches a target tissue compartment (such as the brain) in sufficient amounts to be pharmacologically active. Competition studies, using a radioligand that binds to the target of therapeutic interest with adequate specificity, enable direct assessment of the relationship between drug plasma concentration and target occupancy. Tailored radiotracers can be used to measure relative rates of biological processes, while radioligands specific for tissue markers expected to change with treatment can provide specific pharmacodynamic information. Integrated application of PET and magnetic resonance imaging (MRI) methods allows molecular interactions to be related directly to anatomical or physiological changes in a tissue. Applications of imaging in early drug development can suggest approaches to patient stratification for a personalized medicine able to deliver higher value from a drug after approval. Although imaging experimental medicine adds complexity to early drug development and costs per patient are high, appropriate use can increase returns on R and D investment by improving early decision making to reduce new drug attrition in later stages. We urge that the potential value of a translational molecular imaging strategy be considered routinely and at the earliest stages of new drug development.

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Tumor Survivin Is Downregulated by the Antisense Oligonucleotide LY2181308: A Proof-of-Concept, First-in-Human Dose Study

Cited by 93 publications

References 29 publications

RNA Therapeutics in Oncology: Advances, Challenges, and Future Directions

RNA Therapeutics in Oncology: Advances, Challenges, and Future Directions

In Reply: Response to Marioni

Positron emission tomography molecular imaging for drug development

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