Circulating Tumor DNA in Predicting Outcomes in Patients With Stage IV Head and Neck Cancer or Stage III-IV Non-small Cell Lung Cancer
- Conditions
- Stage IVA Squamous Cell Carcinoma of the LarynxStage IVA Squamous Cell Carcinoma of the OropharynxStage IVA Verrucous Carcinoma of the Oral CavityStage IVB Verrucous Carcinoma of the Oral CavityStage IVC Squamous Cell Carcinoma of the OropharynxMetastatic Squamous Neck Cancer With Occult Primary Squamous Cell CarcinomaStage IVB Squamous Cell Carcinoma of the LarynxStage IVC Salivary Gland CancerStage IVC Squamous Cell Carcinoma of the Paranasal Sinus and Nasal CavityStage IVC Verrucous Carcinoma of the Larynx
- Interventions
- Other: Cytology specimenOther: Laboratory biomarker analysis
- Registration Number
- NCT02245100
- Brief Summary
This pilot research trial studies circulating tumor deoxyribonucleic acid (DNA) in predicting outcomes in patients with stage IV head and neck cancer or stage III-IV non-small cell lung cancer. Studying circulating tumor DNA from patients with head and neck or lung cancer in the laboratory may help doctors predict how well patients will respond to treatment.
- Detailed Description
PRIMARY OBJECTIVES:
I. To evaluate the predictive value of the circulating tumor DNA for disease-free survival/progression-free survival in patients with advanced head and neck carcinoma (HNC) and non-small cell lung cancer (NSCLC).
SECONDARY OBJECTIVES:
I. To correlate the levels of plasma tumor DNA with the salivary tumor DNA. II. To correlate the mutations found in the circulating tumor DNA with the mutations in the tumor tissues.
III. To evaluate the association between presence and absence of circulating tumor DNA mutation with the tumor burden assessed by using the radiological findings and pre-treatment fludeoxyglucose (FDG) positron emission tomography (PET)-derived metrics: metabolic tumor volume (MTV), maximum standardized uptake value (SUVmax), total glycolytic activity (TGA).
IV. To quantify tumor-specific exosomes from plasma. V. To evaluate the utility of cancer-derived exosomes to serve as prognostic biomarkers for real-time monitoring of therapeutic efficacy and identifying early recurrence using longitudinal samples from cancer patients undergoing treatment.
OUTLINE:
Patients undergo blood sample collection within 1 month before surgery, radiation therapy, or chemotherapy; within 1 week after surgical resection (for patients having upfront surgery); within 1 month before beginning of post-operative radiation therapy (for patients having upfront surgery); during the second week of radiation therapy, during the last week of radiation therapy; and at 1 and 3 months after radiation therapy and then every 3 months for up to 18 months. Patients also undergo saliva sample collection within 1 month before surgery, radiation therapy, chemoradiation therapy, or system chemotherapy and tissue collection at the time of surgery (if upfront surgery is indicated). Blood, saliva, and tissue samples are analyzed for tumor mutations via next generation sequencing.
Recruitment & Eligibility
- Status
- COMPLETED
- Sex
- All
- Target Recruitment
- 130
- Patients older than 18 years age
- Diagnosis of advanced HNC (Stage III, IVA, IVB, IVC) or NSCLC (Stage IIA, IIB, IIIA, IIIB, IV) (patients with synchronous advanced HNC and NSCLC are eligible)
- ECOG performance status score of 0-3
- Life expectancy of 3 months or longer
- Patients able to provide a written informed consent prior to study entry
- Prior chemotherapy or full course of radiotherapy for their present advanced HNC or NSCLC
- Patients are excluded if they have a history of any other malignancy from which the patient has been disease-free for less than 2 years, with the exception of adequately treated basal or squamous cell carcinoma of skin
- Other severe acute or chronic medical or psychiatric condition that may increase the risk associated with study participation, and in the judgment of the investigator would make the subject inappropriate for entry into this study
Study & Design
- Study Type
- OBSERVATIONAL
- Study Design
- Not specified
- Arm && Interventions
Group Intervention Description Predictive value of circulating DNA Laboratory biomarker analysis Patients undergo blood sample collection within 1 month before surgery, radiation therapy, or chemotherapy; within 1 week after surgical resection (for patients having upfront surgery); within 1 month before beginning of post-operative radiation therapy (for patients having upfront surgery); during the second week of radiation therapy, during the last week of radiation therapy; and at 1 and 3 months after radiation therapy and then every 3 months for up to 18 months. Patients also undergo saliva sample collection within 1 month before surgery, radiation therapy, chemoradiation therapy, or system chemotherapy and tissue collection at the time of surgery (if upfront surgery is indicated). Blood, saliva, and tissue samples are analyzed for tumor mutations via next generation sequencing. Predictive value of circulating DNA Cytology specimen Patients undergo blood sample collection within 1 month before surgery, radiation therapy, or chemotherapy; within 1 week after surgical resection (for patients having upfront surgery); within 1 month before beginning of post-operative radiation therapy (for patients having upfront surgery); during the second week of radiation therapy, during the last week of radiation therapy; and at 1 and 3 months after radiation therapy and then every 3 months for up to 18 months. Patients also undergo saliva sample collection within 1 month before surgery, radiation therapy, chemoradiation therapy, or system chemotherapy and tissue collection at the time of surgery (if upfront surgery is indicated). Blood, saliva, and tissue samples are analyzed for tumor mutations via next generation sequencing.
- Primary Outcome Measures
Name Time Method Predictive value of circulating tumor DNA for disease-free survival (DFS)/progression-free survival (PFS) Up to 2 years To evaluate the predictive value of circulating tumor DNA for DFS/PFS, Cox proportional model will be utilized. Circulating tumor DNA will be treated as either continuous or categorical variables in the regression models. The optimal cut-off value to dichotomize the patients by circulating tumor DNA will be determined by time-dependent receiver operating characteristic curve.
- Secondary Outcome Measures
Name Time Method Correlation between plasma tumor DNA levels and salivary tumor DNA levels Up to 2 years The correlation between plasma tumor DNA and salivary tumor DNA levels will be modeled through linear regression with least squares approach or using the Spearman correlation coefficient.
Association between absence and presence of circulating tumor DNA mutation with FDG-PET tumor hypermetabolism status Up to 2 years Univariate chi-square tests will be used to access the association between absence and presence of circulating tumor DNA mutation with FDG-PET tumor hypermetabolism status.
Correlation between circulating tumor cells and circulating tumor DNA Up to 2 years The correlation between circulating tumor cells and circulating tumor DNA levels will be modeled through linear regression with least squares approach or using the Spearman correlation coefficient.
Correlation between mutations found in plasma and tissue mutations Up to 2 years The correlation between mutations found in plasma and tissue mutations will be first explored by univariate chi-square test and then multivariable logistic regression.
Association between absence and presence of circulating tumor DNA mutation with the tumor burden Up to 2 years Univariate chi-square tests will be used to access the association between absence and presence of circulating tumor DNA mutation with the tumor burden.
Trial Locations
- Locations (1)
Thomas Jefferson University
🇺🇸Philadelphia, Pennsylvania, United States