View clinical trials related to Skin Cancer.
Filter by:This is a 2-part, open-label, multicenter, dose-escalation, proof-of-concept study with a safety run-in designed to assess the safety, tolerability, MTD, and objective antitumor efficacy of ascending dose strengths of VP-315 when administered intratumorally to adults with biopsy proven basal cell carcinoma (BCC). The study is expected to enroll approximately 80 subjects with a histological diagnosis of BCC in at least 1 eligible target lesion (confirmed by punch or shave biopsy).
The primary objects of this study is to explore the potential effect of the autologous patch to optimize wound healing after skin cancer surgery with Mohs micrographic surgery (MMS) in the face in a randomized controlled trial comparing autologous patch healing versus secondary intention healing.
Americans who work outdoors are exposed to an extreme amount of solar ultraviolet radiation over a lifetime that substantially increases their risk for developing skin cancer. In Phase I, the feasibility of a virtual learning environment (VLE) for distributing our effective Sun Safe Workplaces (SSW) intervention to American employers will be established with input from senior managers and Hispanic and African American outdoor workers and development and evaluation of a prototype of the SSW Works VLE. In Phase II, the full SSW Works will be produced and tested for effectiveness at improving outdoor workers' sun protection in a randomized trial enrolling employers nationwide.
The purpose of this prospective, interventional, single-arm pilot study is to evaluate whether virtually delivered group-based physical activity is feasible for adolescent and young adult (AYA) cancer survivors. AYAs who were diagnosed with cancer and have completed cancer treatment will be recruited for this study. This study will enroll 20 participants in total and will last approximately 3 months.
Medical imaging commonly involves the use of radiation, such as x-rays, that can give detailed images of internal structures of the body but can carry a small risk of tissue damage due to the radiation involved. As such, the number of x-rays and computed tomography (CT) scans that an individual can have has to be minimised. Methods have recently been developed that make use of electromagnetic radiation for imaging purposes at terahertz (THz) frequencies, the region of the spectrum between millimetre wavelengths and infrared. Terahertz spectroscopic imaging uses low power levels such that adverse effects on tissues are insignificant and is safe for in vivo imaging of humans [1]. The terahertz region is between the radio frequency region and the optical region generally associated with lasers. Both the IEEE RF safety standard and the ANSI Laser safety standard have limits into the terahertz region. The focus of this project is to investigate THz spectroscopic imaging as a new and powerful tool for analysing skin properties, termed "THz skinometry". The novelty in this project lies in tailoring the instrumentation and algorithms of THz scanning to accurately measure properties of human skin (e.g. hydration levels and skin thickness) in vivo. The customised non-contact and pressure-controlled contact THz probes developed will be able to do spectroscopic measurements of skin in vivo at the molecular level. This will be the first demonstration of in vivo THz imaging of skin globally and will facilitate quantitative characterisation of skin in a way that has hitherto not been possible and could lead to a step change in THz technology usage (similar to that currently used in airport security scanners).
Investigators hypothesize that the introduction of basic science explanations within the instructional design of case-based training in visual diagnostics will improve students' learning curves, retention, and retrieval of knowledge/skill following a washout period. Research question: In a group of medical students with limited dermatological training, what is the effect of integrating biomedical causal explanations of visual criteria during a prolonged case-based skin cancer training program in visual pattern recognition when compared with an identical instructional design without biomedical explanations? How will the displacement of students' cognitive resources from practicing pattern recognition towards understanding the pattern, affect their learning behavior, learning curve (accuracy and time per diagnosis), and retrieval of pattern recognition skills following a washout period? The above-mentioned research questions will be tested through a randomized trial with an allocation ratio of 1:1. All participants will be trained in skin cancer diagnostics through a mobile application that offers simulation training and learning through written modules about the various differential diagnoses. Approximately half of the participants will be subject to a written content that displays the dermoscopic visual criteria without an explanation while the remaining half will be subject to the dermoscopic criteria + an explanation of the underlying cause. The training program consists of 500 training cases, a 14 day wash-out period, and a final training session of 100 cases.
This is a Phase 1/2, multi-center, open-label, dose-escalation and expansion study to evaluate safety and tolerability, PK, pharmacodynamic, and early signal of anti-tumor activity of MDNA11 alone or in combination with a checkpoint inhibitor in patients with advanced solid tumors.
The incidence of skin cancer has been continuously increasing over the past decades und the number of non melanoma skin cancer is well as melanoma is still going to increase. Invasive biopsy and histological examination represents the gold standard in diagnosis of benign and malignant skin tumors. However, novel technologies such as reflectance confocal microscopy (RCM) and optical coherence tomography (OCT) have been introduced in dermatology. Multiple studies have shown the applicability of both technologies for diagnosis of skin tumors as well as other skin diseases and to increase the specificity of diagnosis resulting in the reduction of unnecessary biopsies. New technological developments resulted in a high resolution OCT scanner (AMO, Taiwan), which allows vertical and horizontal evaluation (3D) of the skin at cellular resolution and up to a depth of around 400 μm and thus combines the advantages of both above mentioned techniques. ApolloVue® S100 Image System is a FDA-cleared 510(k) Class II medical device. Other non-invasive imaging method (reflectance confocal microscopy and conventional optical coherence tomography) will be used to evaluate a subset of skin lesions.
A unique combinational treatment for cancer employing intratumoral diffusing alpha radiation emitter device with check point inhibitor for recurrent unresectable or metastatic Head and Neck Squamous Cell Carcinoma
The study has 2 parts. Part 1 will investigate the effects of introducing teledermoscopy in clinical practice, more specifically the change in referral patterns, the risk of undetected skin cancers and the effect on diagnostic accuracy in general practitioners. Part 2 will investigate how to introduce artificial intelligence (AI) within teledermocsopy. In this study the investigators will measure the diagnostic accuracy of teledermoscopic assessors that had access to the results of artificial intelligence algorithm compared to those who did not. Data will be collcted through teledermoscopic referrals, patient records, national registries and questionnairs.