- ICH GCP
- US Clinical Trials Registry
- Clinical Trial NCT01586520
Diagnosing Thyroid Cancer Using a Blood Test
Study Overview
Status
Conditions
Detailed Description
This project will utilize two powerful technologies for diagnosing endocrine diseases: proteomics and genetic (RNA and DNA) markers. Proteomics is a relatively new, rapidly expanding and exciting area of biomedical research (Robin et al, 2009, Frolich et al, 2009). Posttranslational modifications of proteins are critical for function. Modified proteins may be markers of cancer phenotypes and therefore be useful tumor markers (Narimatsu et al, 2010). Proteomic research in thyroid cancer is in its infancy (Krause et al, 2009). The available studies on thyroid cancer have utilised tissue rather than serum samples, nonetheless the results are encouraging (Brown et al, 2006, Wang et al, 2006, Netea-Maier et al, 2008, Krause et al, 2007, Moretz et al, 2008).
Genomic markers of thyroid cancer have been described and are increasingly being used on biopsy material for accurate diagnosis. Among the described markers point mutations (BRAF V600E, NRAS codon 61, HRAS codon 61), gene rearrangements (RET / PTC1, RET / PTC3, PAX8 / PPARgamma) and other polymorphisms have been found to be useful (Nikiforova and Nikiforov, 2009, Ohori et al, 2010). There is good evidence that in recurrent thyroid cancer small numbers of thyroid cancer cells can be detected in peripheral blood, in sufficient quantities to detect thyroid-specific mRNA by RT PCR (Karavitaki et al, 2005, Barbosa et al, 2008, Milas et al, 2009). Most of these studies have focused on the detection of thyroglobulin mRNA with moderate success. A significant difficulty with this approach is that detection of thyroglobulin mRNA in peripheral blood cannot distinguish between the presence of normal thyroid tissue or thyroid cancer.
The project is a collaborative venture between Newcastle Biomedicine, the NHS, and Biosignatures Ltd (a North-East based proteomics diagnostics company). Biosignatures has invested a great deal of research in optimizing sample handling and sample analysis, thus giving rise to plasma proteomic protocols that are stable and suitable for large comparative studies (Elliott et al, Jackson et al, 2010, Bramwell et al, 2007). The data generated from plasma 2D gel electrophoresis and mass spectroscopy is analysed by proprietary "supervised learning" technology. The system is given multiple examples of group classes (disease cases) and from this derives a signature pattern ('proteomic fingerprint') that allows the classes to be discriminated. This signature will then be validated against a novel patient dataset to ensure robust disease status discrimination. The combination of this research and technology can produce blood derived signatures of disease in an applied clinical setting (Cash and Argo, 2009, Borthwick et al, 2009).
Thyroid cancer affects 2000 new patients in the UK per annum (Cancer Research UK). Once the initial treatment of thyroid cancer is completed (thyroidectomy followed by radioiodine ablation), monitoring is essential to detect residual disease or recurrence. Recurrence rates in thyroid cancer are as high as 30% (Mazzaferri and Kloos, 2001) and can declare themselves decades after initial treatment, so that patients have to be monitored regularly for life. Monitoring for disease recurrence consists of iodine scans, an ultrasound scan of the neck 6-8 months after initial treatment, and 6-12 monthly blood tests thereafter for the serum marker thyroglobulin. Thyroglobulin is a valuable marker in many people with thyroid cancer (Spencer and Fatemi, 2006). Unfortunately in approximately 30% of patients antibody interference with the assay renders this test unreliable (Spencer and Fatemi, 2006). In such cases patients are subjected to repeated scans, though a negative scan has a far less predictive value than a negative thyroglobulin blood test when the analyte can be measured reliably. We have selected thyroid cancer as the primary topic of study for proof of concept for the following reasons:
- Current diagnostics technology (measurement of serum thyroglobulin) suffers from interference of measurement of the analyte in 30% of cases, rendering this tumour marker entirely unreliable when such antibodies are present. Attempts using conventional biochemical analytical technology to overcome this problem over the past 3 decades have failed. Thus a proteomics/genomics approach has only to perform with a better than 70% specificity to provide a superior diagnostic test.
- The potential cost savings to the NHS by the development of such a diagnostic test (by avoidance of expensive scans) will be considerable.
- Exposure of patients to radiation from repeated scans will be reduced with obvious safety benefits.
- The study is non-interventional, will induce no additional discomfort, and is expected to have no impact on the care received by participants at this stage.
- Extrapolation of such technology to the evaluation of thyroid nodules (present clinically in 5% of the adult population) and even screening of the population for thyroid malignancy, would have profoundly beneficial preventative and public health consequences.
Study Type
Enrollment (Actual)
Contacts and Locations
Study Locations
-
-
-
Newcastle upon Tyne, United Kingdom, NE7 7DN
- Sir Bobby Robson Cancer Research Unit, Northern Centre for cancer care
-
-
Tyne and Wear
-
Newcastle upon Tyne, Tyne and Wear, United Kingdom, NE7 7DN
- Sir Bobby Robson Cancer Researhc Unit
-
-
Participation Criteria
Eligibility Criteria
Ages Eligible for Study
Accepts Healthy Volunteers
Genders Eligible for Study
Sampling Method
Study Population
Description
Inclusion Criteria:
- Age over 18 years.
- Patient has thyroid cancer.
- Patient is judged as being capable of understanding the information sheet and of giving informed consent (Mental Capacity Act 2005).
- Responsible clinician is approached and is happy for the patient to be included in the study.
Exclusion Criteria:
- Age of less than 18 years.
- Patient has additional risk infections (HIV, Hep B/C)
- Patient is involved in other medicinal or treatment based clinical trial at the time of recruitment or in the previous 4 months.
Study Plan
How is the study designed?
Design Details
- Observational Models: Case-Control
- Time Perspectives: Prospective
Cohorts and Interventions
Group / Cohort |
---|
Disease positive
Imaging or biopsy evidence of disease
|
Disease negative
No evidence of disease
|
What is the study measuring?
Primary Outcome Measures
Outcome Measure |
Measure Description |
Time Frame |
---|---|---|
Proteomic markers of differentiated thyroid cancer
Time Frame: 24 months
|
The primary objective of the study is to derive molecular (proteomic) diagnostic signatures that that can distinguish patients with recurrent / residual thyroid cancer from those with no residual disease.
|
24 months
|
Secondary Outcome Measures
Outcome Measure |
Measure Description |
Time Frame |
---|---|---|
Genetic markers of diffferentiated thyroid cancer
Time Frame: 24 months
|
The secondary objective is to identify genetic markers of thyroid cancer status (recurrent / residual disease versus no disease) from peripheral blood samples.
Information from the proteomics component of the study are expected to identify multiple potential protein markers.
Genes encoding these differentially expressed proteins will be sequenced and will guide our team as to which genetic markers in peripheral blood may be targeted in order to improve the diagnostic power of molecular testing.
|
24 months
|
Collaborators and Investigators
Study record dates
Study Major Dates
Study Start
Primary Completion (Actual)
Study Completion (Actual)
Study Registration Dates
First Submitted
First Submitted That Met QC Criteria
First Posted (Estimate)
Study Record Updates
Last Update Posted (Actual)
Last Update Submitted That Met QC Criteria
Last Verified
More Information
Terms related to this study
Additional Relevant MeSH Terms
Other Study ID Numbers
- 5559
This information was retrieved directly from the website clinicaltrials.gov without any changes. If you have any requests to change, remove or update your study details, please contact register@clinicaltrials.gov. As soon as a change is implemented on clinicaltrials.gov, this will be updated automatically on our website as well.
Clinical Trials on Differentiated Thyroid Cancer
-
Thomas Jefferson UniversityActive, not recruitingDifferentiated Thyroid Cancer (DTC) | Poorly Differentiated Thyroid CancerUnited States
-
University of PennsylvaniaCompletedMetastatic Medullary Thyroid Cancer | Metastatic Differentiated Thyroid Cancer | Metastatic Anaplastic Thyroid Cancer | Metastatic Poorly Differentiated Thyroid CancerUnited States
-
National Cancer Institute (NCI)TerminatedThyroid Neoplasms | Differentiated Thyroid Cancer | Poorly Differentiated and Undifferentiated Thyroid CancerUnited States
-
H. Lee Moffitt Cancer Center and Research InstituteTerminatedThyroid Cancer, Medullary | Thyroid Cancer | Papillary Thyroid Cancer | Differentiated Thyroid Cancer | Poorly Differentiated Thyroid Gland Carcinoma | Follicular Thyroid CancerUnited States
-
Children's Hospital of PhiladelphiaBayerRecruitingCancer | Pediatric Cancer | Differentiated Thyroid Cancer | Cancer, ThyroidUnited States
-
Istituti Clinici Scientifici Maugeri SpAMerck Sharp & Dohme LLCRecruiting
-
National Taiwan University HospitalRecruitingDifferentiated Thyroid CancerTaiwan
-
Suzhou Zelgen Biopharmaceuticals Co.,LtdActive, not recruitingDifferentiated Thyroid CancerChina
-
Genzyme, a Sanofi CompanyCompletedEvaluation of Efficacy, Safety of Vandetanib in Patients With Differentiated Thyroid Cancer (VERIFY)Differentiated Thyroid CancerUnited States, Sweden, Brazil, Italy, Poland, Spain, China, Russian Federation, France, Japan, Denmark, Czechia
-
Suzhou Zelgen Biopharmaceuticals Co.,LtdTerminatedDifferentiated Thyroid CancerChina