Solid Tumours Clinical Trial
Official title:
Tissue Collection Framework To Improve Outcomes In Solid Tumours
Background:
Cancer therapies have significantly improved over the last decades, allowing cancer
specialists to keep cancer under control for longer than ever before. However, metastatic
cancer still develops in a large number of patients and drug resistance occurs in the
majority of them after an initial period of response and leads to cancer progression and
death.
Aims:
To date, the mechanisms which allow cancer cells to spread through the body to form
metastases and to become resistant even to the most powerful treatments are poorly
understood. Our aim is to collect cancer specimens and normal tissue specimens such as blood
from patients with solid tumours and to analyse these samples with some of the latest
molecular profiling technologies in the research laboratory. This comprehensive analysis
should reveal what molecular defects fuel the growth of cancer cells adn what allows them to
spread through the body and then develop resistance to cancer therapies. Such insights could
subsequently lead to the development of better more improved treatments which prevent drug
resistance, to novel molecular tests which can also predict which treatment is most likely to
be effective and tolerable in individual patients.
Methods:
To achieve this, we aim to collect multiple samples from consenting patients starting from
the diagnosis of a tumour to the time drug resistance develops more. Importantly, this study
will collect tissues from interventional procedures which are performed as part of routine
patient management of patients seen at Barts Health NHS trust. We will then apply molecular
tests such as proteomics and DNA sequencing to these samples. Tissues which are left over
after these tests have been applied will be stored in a licensed tissue bank to allow future
research with novel technologies.
Approximately 320,000 patients are diagnosed with some form cancer in the UK each year.
Despite improved therapies, half of these patients still die of their disease, usually after
the failure of anticancer drug treatment. To date, mechanisms of drug resistance and also
determinants of treatment toxicity which varies significantly between individual patients are
poorly understood. Recent advances in molecular profiling techniques allow the comprehensive
interrogation of large numbers of genes, transcripts and proteins which may be altered and
contribute to progression and drug resistance in tumour tissues.
These technologies, including genome wide RNA expression and methylation profiling and DNA
sequencing can be used to analyse the causes of cancer drug resistance in detail and this
information can subsequently be used to develop better cancer drugs which prevent or overcome
resistance and prolong patient survival. Furthermore, molecular studies can help to
understand why some patients develop excessive toxicities during treatment with drugs which
are well tolerated by most patients. This could help to develop tests that predict which
individual patients will not tolerate a specific drug.
Importantly, we recently demonstrated that individual human tumours can contain highly
heterogeneous cancer cell populations, for example good and poor prognosis cancer cells
within the same tumour. This intratumour heterogeneity may have hampered the identification
of markers of drug sensitivity or tumour aggressiveness in the past as single tumour biopsies
are unlikely to reveal this complexity. Thus, our project uses our established sample
collection protocols to comprehensively sample surgical specimens. This will allow the
analysis of intratumour heterogeneity and its impact on outcome which is an urgent clinical
need.
Tumour tissues can also change their molecular characteristics over time, for example during
treatment, which mandates the longitudinal collection of tissue and blood specimens in order
to understand how treatment resistance develops. We and others have recently shown that blood
samples can be used to obtain information about tumour progression without the need for
rebiopsies (Gerlinger, unpublished results and Forshew et al. Sci Transl Med 2012,
4:136ra68). Our aim is to regularly collect blood specimens from which tumour DNA and tumour
cells can be extracted and studies as a surrogate of the tumour lesions. Taken together,
multiregion sampling of tumours at surgery and longitudinal monitoring of molecular
alterations over time should provide crucial insights into tumour heterogeneity and tumour
evolution critical for progression and drug resistance.
The understanding of mechanisms of tumour progression also requires the use of cancer model
systems in the laboratory and established cancer cell lines are generally used for this
purpose. Such cell lines have often adapted to the laboratory tissue culture environment
which changed their characteristics over time. Thus, they frequently behave differently from
cells isolated directly from fresh tumour specimens, hindering their use for the
identification of drug targets and resistance mechanisms. To circumvent this limitation, we
will also use the collected tissues to isolate primary tumour and stromal cells and to
maintain them in the laboratory for a limited period of time. This will provide the
opportunity to study tumour characteristics in greater detail and will prevent false
conclusions which can arise from artifacts which cannot be avoided in long term tissue
culture.
Together, these efforts should improve our understanding of tumour evolution over time and
reveal some of the mechanisms whih allow tumours to spread through the body and to develop
cancer drug resistance. This will be a major improvement over traditional approaches which
have most likely failed to identify mechanisms of cancer progression and treatment failure
because they relied on single biopsies, missing heterogeneous changes in individual tumours
and changes occurring over time (for further information: see Gerlinger et al (NEJM, March
2012) and Yap et al (Sci Transl Med, March 2012).
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