View clinical trials related to Barrett Esophagus.
Filter by:The aim of this first-in-man study is to evaluate the safety of calcium electroporation used in patients with Barrett's esophagus high-grade dysplasia through an endoscopic system.
The purpose of this study is to create a registry (collect data and keep it in a research database) to learn more about two methods of taking small tissue samples from your esophagus (the esophagus is the tube that carries food and liquid from your mouth to your stomach). The two methods of sampling are: 1) Using forceps that take biopsies (small tissue samples) from your esophagus, and 2) Using a brush that also takes biopsies from your esophagus.
The study will assess the performance of the combined system, i.e., the use of the EsoGuard assay (lab developed test) on cells collected using the EsoCheck (501k cleared device) to detect Barrett's Esophagus (BE), with or without dysplasia, and esophageal adenocarcinoma (EAC) as compared to Esophagogastroduodenoscopy (EGD) plus biopsies in both confirmed cases of BE/EAC and in controls (subjects without a prior diagnosis but undergoing screening for BE/EAC)
This study is to identify potential biomarkers for the early detection of Barrett's Esophagus, esophageal carcinoma (both adenocarcinoma and squamous cell carcinoma), and gastric cancer via sponge cytology.
This prospective cohort study aims to assess the utility of a panel of molecular biomarkers for predicting the risk of relapse of Barrett's Oesophagus after endoscopic treatment of early oesophageal neoplasia with RadioFrequency Ablation (RFA). Patients who received endoscopic treatment of early oesophageal neoplasia with RFA and achieved endoscopic remission will be recruited. During the surveillance visits patients will receive a Cytosponge test followed by an endoscopy with Narrow Band Imaging (NBI) magnification and biopsies. Patients will receive an endoscopy every 6 months and Cytosponge every 12 months for at least 2 years. Molecular biomarkers including a methylation panel on DNA and immunohistochemical markers on formalin fixed paraffin embedded samples. After 2 years of intensive endoscopic follow up, patients will be prospectively tracked for up to 3 years. The investigators will also evaluate: - The risk of progression to dysplasia or oesophageal intestinal metaplasia (IM) in patients with IM at the GOJ post RFA in the absence of retreatment - the diagnostic accuracy of NBI for IM/dysplasia at the GOJ .
Barrett's esophagus is a complication of chronic gastroesophageal reflux disease that occurs in up to 10% to 15% of patients with this pathology. Well-defined risk factors have been established and are important because they are considered a precancerous lesion (intestinal metaplasia). The conventional diagnostic methods are ineffective in reliably detecting potentially treatable lesions. Investigators propose the use of vital chromoendoscopy with acetic acid using the simplified classification of Portsmouth looking for areas with loss of acetowhitening and taking targeted biopsies to increase the detection of esophageal neoplastic lesions.
This study aims to determine whether a breath test could be used for early detection of oesophageal cancer and Barrett's high grade dysplasia. Patients who are attending for a planned gastroscopy or who are scheduled to undergo elective resection of histologically confirmed early stage oesophageal adenocarcinoma or dysplasia will be approached to provide a breath sample. Multi platform mass spectrometry analysis will be performed to establish volatile biomarkers that can discriminate between early stage (T1) oesophageal cancer/ Hight grade dysplasia from non cancer healthy controls/non dysplastic Barrett's cancer.
This study will evaluate if the sponge capsule device can accurately detect the presence of Barrett's Esophagus and prevalent dysplasia/adenocarcinoma detection, in a screening population, with and without chronic gastroesophageal reflux disease.
To improve detection of esophageal (pre)malignant lesions during surveillance endoscopy of patients at risk of developing malignancies, for example in Barrett's Esophagus (BE), there is a need for better endoscopic visualization and the ability for targeted biopsies. Optical molecular imaging of neoplasia associated biomarkers could form a promising technique to accommodate this need. It is known that the biomarker Vascular Endothelial Growth Factor (VEGF) is overexpressed in dysplastic and neoplastic areas in BE segments versus normal tissue and has proven to be a valid target for molecular imaging. The University Medical Center Groningen (UMCG) developed a fluorescent tracer by labeling the VEGF-targeting humanized monoclonal antibody bevacizumab, currently used in anti-cancer therapy, with the fluorescent dye IRDye800CW. The phase I study, named VICE, completed within the UMCG, showed that synchronal use of VEGFA-guided near-infrared fluorescence molecular endoscopy (NIR-FME) and high-definition white light endoscopy (HD-WLE), following topical or systemic tracer administration, could be practiced to recognize dysplastic and early EAC lesions in patients with BE. Furthermore, early lesion detection was improved by ~33% using the topically applied tracer approach compared with HD-WL/NBI endoscopy. With this phase 2 intervention study the investigators aim to statistically confirm previous pilot (Phase I) clinical data showing that the combination of HD-WLE and FME using labelled bevacizumab improves early EC detection over the current clinical standard.
The investigators have developed a new technology, termed in-vivo laser capture microdissection (IVLCM), that addresses the limitations of endoscopic biopsy for screening for BE and provides targeted genomic profiling of aberrant tissue for more precise prediction of EAC risk. The device is a tethered capsule endomicroscope (TCE) that implements optical coherence tomography (OCT) to grab 10-mm-resolution, cross-sectional microscopic images of the entire esophagus after the capsule is swallowed. This OCT-based TCE technology is used in unsedated patients to visualize images of BE and dysplastic BE. During the IVLCM procedure, TCE images of abnormal BE tissue are identified in real time and selectively adhered onto the device. When the capsule is removed from the patient, these tissues, targeted based on their abnormal OCT morphology, are sent for genomic analysis. By enabling the precise isolation of aberrant esophageal tissues using a swallowable capsule, this technology has the potential to solve the major problems that currently prohibit adequate BE screening and prevention of Esophageal Adenocarcinoma EAC.