Active clinical trials for "Head and Neck Neoplasms"

To develop an International registry on head and neck cancer patients infected with COVID-19

Background: Cisplatin is used to treat head and neck cancer. People who take this drug are at risk for hearing loss. Atorvastatin is a drug used to treat high cholesterol. It might reduce the risk of cisplatin-induced hearing loss. Objective: To find out if atorvastatin reduces hearing loss in people treated with cisplatin and radiation. Eligibility: People ages 18 and older with squamous cell carcinoma of the head and neck who will undergo treatment with cisplatin-based chemotherapy and radiation Design: Participants will be screened with their medical records. Participants currently taking a cholesterol-lowering statin medication are invited to participate in the observational arm of the study. Those not taking such a medication are invited to participate in the interventional arm of the study. All participants will have 2 visits. One before starting cisplatin treatment and within 3 months of completing treatment. They will have tympanograms. A small flexible tip will be placed in the ear canal. A puff of air will be delivered to assess mobility of the ear drum. They will have hearing tests. They will wear headphones. They will listen to tones that vary in loudness. They will be asked to indicate when they hear a sound. Participants in the interventional arm will have 2 additional visits for blood tests. These will occur upon consent and 12 weeks after. They will be randomly assigned to take the study drug or placebo orally, once daily. They will take it during cisplatin treatment and for 3 months after treatment. Long-term follow up will include a chart review 2 years after participants complete their cisplatin therapy.

The purpose of this study is to test the safety and tolerability of chemotherapy and radiation in combination with the investigational study drugs zimberelimab (AB122) and etrumadenant (AB928) in subjects with a locally advances head or neck cancer. The study will also ask how the study drugs change the following: The microbiome that lives in the mouth and on the skin Immune cells as they respond to a skin wound Scarring (fibrosis) caused by radiation After completing a screening phase, subjects will be assigned to one of three cohorts: Cohort 1: Subjects who will receive cisplatin, radiation and zimberelimab followed by zimberelimab only. Cohort 2: Subjects who will receive cisplatin, radiation, zimberelimab and etrumadenant followed by zimberelimab and etrumadent. Cohort 3: Subjects who will receive cisplatin and radiation followed by an observation period. All three cohorts will be followed for a 24 months following the conclusion of the chemoradiation.

People who have been treated for head and neck cancer (HNC survivors) can experience serious consequences from their cancer and its treatment, ongoing risks of new cancers, and other unrelated illnesses. These concerns pose challenges to the provision of comprehensive care to HNC survivors. We created HN-STAR to facilitate and tailor the ongoing care of HNC survivors. Survivors use HN-STAR on a computer or tablet to answer questions about symptoms and health concerns before a routine visit with a cancer care provider. During the clinic visit, the provider uses HN-STAR to see evidence-based recommendations for managing each concern reported by the survivor. The provider and survivor discuss recommendations and select appropriate actions (e.g., testing, referrals, prescriptions, self-management). HN-STAR produces a survivorship care plan that includes all reported concerns and the actions selected in clinic. The survivorship care plan is given to the survivor and the primary care provider. Three months, six months, and nine months later, the survivor uses HN-STAR from home (or clinic) to report their concerns again, and a new survivorship care plan is created each time. Our trial randomizes 20-36 oncology practices from the National Community Oncology Research Program to use HN-STAR or provide usual care to 298-400 recent survivors of head and neck cancer. We hypothesize that survivors in the HN-STAR arm will have greater improvement in patient-centered outcomes (including cancer-related well-being, symptoms, and patient activation) over one year compared to survivors in the usual care arm, measured by surveys at baseline and one year later. We also hypothesize that survivors in the HN-STAR arm will be more likely to receive care that is aligned with evidence-based recommendations during the year of the study than survivors in the usual care arm. Our final aim investigates the implementation of HN-STAR in clinical practice, using interviews and surveys of survivors, providers, and other clinic staff to understand the feasibility, acceptability, appropriateness, and other aspects of providing survivorship care to head and neck cancer survivors.

The purpose of this study is to identify and confirm new blood and tissue markers for prognosis and tumor hypoxia. Tumor hypoxia, or the condition of low oxygen in the tumor, has been shown to increase the risk of tumor spread and enhance tumor resistance to the standard treatment of radiation and chemotherapy in head and neck and lung cancers. We have recently identified several proteins or markers in the blood and in tumors (including osteopontin, lysyl oxidase, macrophage inhibiting factor and proteomic technology) in the laboratory that may be able to identify tumors with low oxygen levels or more aggressive behaving tumors.

The purpose of this study is to test the safety and tolerability of using a new treatment called autologous T lymphocyte chimeric antigen receptor cells against the CSPG4 antigen (iC9.CAR-CSPG4 T cells) in patients with head and neck cancer that came back after receiving standard therapy for this cancer. The iC9.CAR-CSPG4 treatment is experimental and has not been approved by the Food and Drug Administration. How many (dose) of the iC9.CAR. CSPG4 T cells are safe to use in patients without causing too many side effects, and what is the maximum dose that could be tolerated will be investigated. The information collected from the study would help cancer patients in the future. There are two parts to this study. In part 1, blood will be collected to prepare the iC9.CAR-CSPG4 T cells. Disease fighting T cells will be isolated and modified to prepare the iC9.CAR-CSPG4 T cells. In part 2, the iC9.CAR-CSPG4 T cells are given by infusion after completion of lymphodepletion chemotherapy. The data from the dose escalation will be used to determine a recommended phase 2 dose (RP2D), which will be decided based on the maximum tolerated dose (MTD). Additionally, recommended phase 2 dose will be tested. Eligible subjects will receive lymphodepletion chemotherapy standard followed by infusion of iC9-CAR.CSPG4 T cells. After treatment completion or discontinuation, subjects will be followed since involving gene transfer experiments.

The purpose of this study is to evaluate the tolerability and safety of Xevinapant when added to weekly cisplatin-based concurrent chemoradiotherapy (CRT) in the treatment of participants with unresectable locally advanced squamous cell carcinoma of the head and neck, suitable for definitive chemoradiotherapy.

Extranodal extension (ENE) refers to the spread of head and neck squamous cell carcinoma (HNSCC) outside the lymph nodes. It is a well-known factor that indicates a poorer prognosis and outcome for patients who have undergone surgical removal of the cancer. In such cases, it is recommended to combine chemotherapy with radiation therapy after surgery. As the number of cases of HNSCC related to the human papillomavirus (HPV) is increasing, treatment approaches have shifted towards using radiation therapy as the primary treatment method instead of surgery. This raises an important question about the significance of ENE observed through imaging tests (referred to as iENE) and its impact on the prognosis. Unfortunately, this question remains unanswered. The objective of this project is to conduct a comprehensive study across multiple medical institutions. The investigators will gather data including scan results, histopathology reports, and data from patient charts from individuals who have been treated for head and neck cancer. The aim is to analyze and correlate the findings between the pathological evidence of ENE and the imaging results, while also assessing the prognostic value of iENE. Additionally, the investigators will explore the influence of HPV status on these factors. By collecting and analyzing this data, the investigators hope to establish standardized criteria that can assist radiologists in accurately identifying ENE through imaging tests. This research is essential for enhancing our understanding of HNSCC and improving the effectiveness of diagnostic procedures and treatment planning.

The proposed study is to investigate the feasibility of using quantitative diffusion MRI (dMRI) methods for accurate and comprehensive assessment of treatment response. dMRI is a powerful tool to probe treatment-induced change in tumors. It is a unique in vivo imaging technique sensitive to cellular microstructures at the scale of water diffusion length on the order of a few microns. Previous studies have shown that both diffusion coefficient D and diffusional kurtosis coefficient K are promising imaging markers of (i) cell viability which can be used for evaluation of early treatment response. However, it is often underappreciated that these dMRI metrics are not fixed constants, but rather functions of the diffusion time t, D(t) and K(t); their t-dependency is determined by tissue properties, such as cell size and membrane permeability of tissue. D(t) and K(t) of tumors can vary substantially depending on t in the range of diffusion times (30-100 ms) typically used in clinical scan.

Aerodigestive tract cancers are common malignancies. These cancers were ranked to be top-ten cancer-related deaths in Taiwan. Although many new target therapies and immunotherapies have emerged, many of the treatment eventually fail. For example, a 30-40% failure rate has been reported for target therapy, and, even higher for immune checkpoint inhibitors. A reliable model to more accurately predict treatment response and survival is warranted. The radiomic features extracted from F-18 fluorodeoxyglucose (18F-FDG) positron emission tomography (PET) can be used to figure tumor biology such as metabolome and heterogeneity. It can therefore be used to predict treatment response and individual survival. On the other hand, genomic data derived from next-generation sequencing (NGS) can interrogate the genetic alteration of cancer cells. It can be used to feature genetic identification of the tumor and can also be used to identify target genes. However, both modalities have their weakness; a combination of the two may devise a more powerful predictive model for more precise clinical decision. The investigators plan to recruit patients aged at least 20-year with the diagnosis of aerodigestive tract cancers for radiogenomic study. Our previous studies have found that radiomic features derived from 18F-FDG PET can predict treatment response and survival in patients with esophageal cancer treated with tri-modality method. The investigators also discovered that radiomics could predict survival in patients with EGFR-mutated lung adenocarcinoma treated with target therapy. In addition, our study results showed that the level of PD-L1 expression is associated with radiomics as well. The investigators plan to add genomic data into radiomics and interrogate cancers from different aspects. The investigators seek to devise a more precise model to predict the treatment response and survival in patients with aerodigestive tract cancers.