View clinical trials related to Thyroid Cancer.
Filter by:The investigators expected to enroll 30 patients with papillary, follicular or anaplastic thyroid cancer, and collect their urine samples before operation, immediately after operation, post-operative 3, 6 12 months. The investigators will analyze the urine exosomal proteins and probable biological markers. The investigators hope to find the prognostic biological markers via this prospective study. The investigators further hope to find newly therapeutic mechanism and medications for such patients with poorly-differentiated or anaplastic thyroid cancer.
Thyroid cancer affects 6,000 Canadians each year. Nodules on the thyroid are detected using ultrasound imaging and surgery is the most common treatment. However, most nodules are benign, and therefore a biopsy is needed to decide whether surgery is necessary. Ultrasound imaging is very sensitive for localizing nodules, but does not differentiate between cancerous and benign ones. To address this limitation of US imaging, investigators have designed and constructed, in collaboration with Sogang University, Seoul, S. Korea, a novel imaging system that performs complimentary imaging modalities (ultrasound (US), photoacoustic (PA)) that could potentially help diagnose nodules without the need for biopsy and unnecessary surgery.
The purpose of this study is to assess the efficacy and safety of apatinib in locally advanced/metastatic radioactive iodine-refractory/resistant differentiated thyroid cancer
This is a multicenter, randomized, double-blind study being conducted as a postmarketing requirement to the US Food and Drug Administration (FDA) to evaluate whether there is a lower starting dosage of lenvatinib 24 mg once daily (QD) that provides comparable efficacy but has a better safety profile in participants with radioiodine-refractory differentiated thyroid cancer RR-DTC with radiographic evidence of disease progression within the prior 12 months.
Recently published European guidance recommends the evaluation of the radiation dose to the bone marrow in patients undergoing radioiodine therapy for thyroid cancer. The methods described in these guidelines require serial blood samples to be taken from the patient, followed by a sophisticated analysis to determine the radiation dose. However, radiation risk assessments carried out locally have indicated that a relatively high radiation exposure will be received by the operator taking the blood samples, which may prohibit this procedure being carried out routinely. The radiation dose to the operator will be lowered if the duration of the blood sampling procedure were reduced. The investigators hypothesize that the use of a lancet and pipette to collect blood from the finger tip will greatly reduce the time spent in proximity to the patient, significantly reducing the operator exposure and allowing this procedure to be performed routinely. The proposed method is also less invasive for the patient compared to the intravenous sampling recommended in the guidelines. A proof-of-principal pilot project using radioiodine diluted to the expected concentration in blood has indicated that using very small volumes of blood (such as from a lancet) does not compromise the accuracy of the dosimetry measurement when compared to large-volume standard blood samples. The primary aim of this study is to investigate whether sampling a small volume of blood using a lancet and pipette can replace standard intravenous blood samples for bone marrow dosimetry in patients undergoing radioiodine treatment for thyroid cancer. Statistical tests will determine whether there is a significant difference between the doses calculated using each blood sampling method. In addition, the investigators will measure the radiation exposure received by the operator during each procedure using Electronic Portable Dosimeters. The results of these measurements will be used to quantify the reduction in operator radiation exposure afforded by the new technique.
The purpose of the study is to evaluate the concordance between the 18F-PET/CT under thyrotropin stimulation and the diffusion-weighted Magnetic Resonance Imaging, in the detection of residual mass in 40 patients with partial response or relapsed differentiated thyroid carcinoma.
This is a patient pilot study testing the hypothesis that vemurafenib with the addition of KTN3379 can restore iodine incorporation in BRAF mutant (MUT), radioiodine-refractory (RAIR) thyroid cancer patients.
The purpose of this Phase II single-arm study is to evaluate the efficacy of Radium-223 in treating bone lesions from differentiated thyroid cancer that are I-131 refractory. Based on the results of the phase III trial, the protocol using an injection of Radium-223 activity of 50 kBq/kg b.w. given 6 times at 4 weeks interval will be applied. The end point of this study will be the evaluation of Radium-223 efficacy one month after 3 administrations, i.e. at 3 months after the first injection. If disease progression at that time is excluded, patients will be treated with 3 further injections for a total of 6 administrations of Radium-223. The principal response criterion at 3 and 6 months will be the metabolic response on FDG PET/CT, but other imaging techniques will also be performed: axial skeleton MRI, 99mTc-HMDP bone scan and FNa PET/CT. Axial skeleton MRI is the reference for soft tissue study. 99mTc- HMDP bone scan is the most used and available routine tool to detect bone metastases in cancer patients, but its sensitivity in patients with bone metastases from thyroid cancer is low, because most lesions are lytic [23]. 18FNa PET/CT shows higher sensitivity than 99mTc-HMDP bone scan to detect bone lesions in cancer patients and is able to detect micrometastases that are not seen on bone scan [24] [25]. Preliminary results show some interest of using this tracer to evaluate the sclerotic component of bone metastases from thyroid cancer [26]. Furthermore preliminary data show that FNa PET/CT can be useful to quantify response to Radium-223 in prostate cancer. In only five patients evaluated by FNa PET/CT at baseline, 6 weeks and 12 weeks after 100 KBq/Kg of Radium-223, semiquantitative analysis by SUV max showed a relationship between PSA and SUV max level decrease in 3 patients (-44%, -31%, -27% vs -52%, -75, and -49% respectively) [27]. Finally bone metastases that are visible on morphological imaging (CT scan or on RI) are frequently submitted to local treatment modalities, and this may induce fibrosis and recalcification. Therefore, already treated metastases and not treated metastases will be studied separately as two separate subgroups of target lesions.
Phase II study to investigate the antitumor activity in terms of objective response rate (ORR) of tipifarnib in subjects with advanced tumors that carry HRAS mutations and for whom there is no standard curative therapy available. Note; Only cohort 2 (Head & Neck SCC) and cohort 3 (Other SCC) are currently open
Radioiodine (I-131) therapy for thyroid disease is known to decrease salivary function in adult patients. The impact of pediatric I-131 exposure on salivary function is unknown. The investigators goals are to answer this question by measuring salivary gland function before and after I-131 administration in children who receive radioiodine therapy at our hospital for thyroid disease.