View clinical trials related to Carcinoma, Basal Cell.
Filter by:The purpose of the study is to investigate the ability of mass spectrometry imaging to locate aggregates of basal cell carcinoma (BCC) and squamous cell carcinoma (SCC) ex-vivo, and to distinguish areas containing these carcinomas from normal skin. It is suggested that non-melanoma skin cancer (NMSC) cells show a different profile of endogenous lipids than healthe skin tissue which can be used as identifying biomarkers. If that hypothesis is correct it will be possible in the future to develop real-time tissue diagnosis and treatment of NMSC using mass spectrometry guided surgery. Method between 60 and 100 patients with BCCs, SCCs, and actinic keratoses (AK) will be recruited. For patients referred for Mohs surgical procedure at the Department of Dermatology, Bispebjerg Hospital, to treat BCCs or SCCs, three skin sections (5-10 um thick) of the tissue that is already removed will be use in our study. One section will be HE stained so we know exactly where the regions of interest are. Two sections will be used for MS analysis (MSI spectrum and REIMS spectrum). When patients are referred for a procedure to have treated several actinic keratoses (grade 1, 2 or 3) at Department of Dermatology, Bispebjerg Hospital we will take an extra punch biopsy (2-4 mm) depending on the size of the lesion. The biopsy is embedded and sectioned. We will use 3 skin sections (5-10 um thick) we will again use one section for HE staining and two for MS analysis. Multivariate statistical analysis will be performed on all mass spectra using Matlab or similar program. Linear discriminant analysis will be used to identify spectral differences between pre-malignant, cancer and normal tissue. Classification performance will be recorded with a leave-one- patient- out cross- validation scheme.
Basal cell carcinoma (BCC) is the most common form of cancer among the Caucasian population. Equivocal BCC lesions are usually diagnosed by means of a punch biopsy, but since the last few decades, non-invasive imaging techniques for the diagnosis of BCC gained popularity within the field of dermatology. Conventional optical coherence tomography (cOCT) is an example of a non-invasive imaging technique. Recent studies revealed that OCT assessors may achieve high diagnostic certainty and accuracy for diagnosing BCC. However, cOCT has a limited axial and lateral resolution and can therefore only visualize the gross architecture of the skin. It has been proposed that the diagnostic certainty and accuracy of cOCT could be optimized by improving the resolution. Line-field confocal optical coherence tomography (LC-OCT) is a new non-invasive imaging technique that provides tridimensional images of the skin with a cellular resolution. Although the resolution of LC-OCT is superior to cOCT, the penetration depth of LC-OCT (500µm) is limited compared to that of cOCT (1.0-1.5mm). In the proposed study, we aim to assess whether LC-OCT is superior to cOCT in terms of diagnostic accuracy for diagnosing BCC in equivocal BCC lesions.
A double-blind, randomized, placebo controlled intervention trial on patients with actinic keratosis.
This pilot study will examine the treatment of basal cell carcinoma (BCC) with laser technology under the guidance of imaging modalities to assist with surgical excision, including optical coherence tomography imaging (OCT) and reflectance confocal microscopy (RCM). The laser modality that we plan to use is the long-pulse Nd:YAG 1064nm laser, which is a nonablative laser already shown to effectively treat BCC. The addition of OCT and RCM has the opportunity to enhance outcomes by better targeting the treatment and permitting more precise monitoring of clearance. OCT is being used to enhance the effectiveness of Mohs Micrographic Surgery of these cancers by elucidating more definitive tumor margins. RCM has been shown to detect changes in the composition of cells consistent with BCC. We propose to use these imaging devices to guide the laser treatment to achieve optimal efficacy with minimized side-effects. Primary outcome measured include complete clearance of the BCC lesion, which will be determined through clinical examination, dermoscopy, imaging (OCT and/or RCM), and saucerization biopsy. Secondary outcome variables include the significance of lesion depth (by OCT and/or RCM), lateral extent (by OCT and/or RCM), BCC type, and anatomical region on rate of clearance and recurrence.
Rationale: To date, the diagnosis and subtyping of basal cell carcinoma (BCC) is verified with histopathology which requires a biopsy. Because this technique is invasive, new non-invasive strategies have been developed, including Optical Coherence Tomography (OCT). This innovative technique enables microscopically detailed examination of lesions, which is useful for diagnosing and identification of various subtypes of BCC. The diagnostic value of the VIVOSIGHT OCT in daily clinical practice, has not been established to date.
Part I is designed as a study of P-MNA application in healthy human volunteers. The goal of Part I is to determine several factors possibly affecting the rate and extent of microneedle array dissolution, such as anatomic location; age; duration of array exposure to the skin; and the criticality of proper array application to the skin. Part II will be a randomized study in which doxorubicin-containing arrays will be applied to subjects demonstrated by biopsy to have basal cell cancer. A subject will be randomized to one of four dose groups: placebo microneedle array and 50 µg, 100 µg, and 200 µg doses of doxorubicin in a tip-loaded, dissolvable microneedle arrays (D-MNA).
The purpose of this study is to refine and pilot test educational material developed to educate and support patients receiving immunotherapy for advanced cancer. The intervention is an educational video and question prompt list (QPL) to promote communication between patients, caregivers, and the oncology team about the risks and benefits of immunotherapy.
The purpose of this study is to find out whether injecting ALA into the skin with a jet-injection device and activating the drug with light is a safe treatment that causes few or mild side effects in people with basal cell carcinoma.
The purpose of this study is to evaluate anti-PD-1 Neoadjuvant therapy in Basal cell carcinoma to provide a better outcome when administered prior to surgery and provide a therapeutic strategy to avoid surgery altogether. The study team will gather information about how Basal cell carcinoma responds to Pembrolizumab prior to surgery and to gather information about recurrence rates. Pembrolizumab, is an investigational (experimental) drug that may improve the response of the immune system against cancer. Pembrolizumab is a manufactured antibody, much like the antibodies usually made by the human body to fight off infection. The idea behind developing this experimental drug is to stimulate the body's immune system to kill cancer cells. Pembrolizumab antibody has been specifically made to block a program cell death-1 (PD-1) protein receptor, which is found on cells of the immune system. PD-1 receptor seems to slow down the immune response. Blocking PD-1 with pembrolizumab antibody may make the immune response more active and may improve the response of the immune system against cancer. Pembrolizumab is currently FDA approved for use in other malignancies. It has been used to treat a number of other diseases such as certain types of lung cancer, cervical cancer and lymphoma. The use of Pembrolizumab in this study is experimental because it is not approved by the Food and Drug Administration (FDA) for use in the treatment of Basal cell carcinoma.
The purpose of this study is to evaluate the safety and tolerability, pharmacokinetics, and pharmacodynamics of INCB099318 in select solid tumors.