Background Previous studies examining the effect of fellow participation on adenoma detection rate in colonoscopy have yielded conflicting results, and factors such as adenoma size and location have ...not been rigorously evaluated. Objective To examine whether fellow participation during screening, surveillance, or diagnostic colonoscopy affects overall, size-specific, or location-specific adenoma or polyp detection rate. Methods This was a retrospective study of 2430 colonoscopies performed in our ambulatory surgical center between September 2006 and December 2007, comparing adenoma and polyp detection rates of colonoscopies performed by fellows with supervising staff endoscopists (n = 318) with colonoscopies performed by staff endoscopists without fellow participation (n = 2112). Study participants included patients who underwent screening, surveillance, or diagnostic colonoscopies in our GI suite. Logistic regression analysis was used to evaluate the association of fellow participation with adenoma and polyp detection. Results There was evidence of a higher rate of small (<5 mm) adenoma detection in colonoscopies with a fellow present (25% vs 17%, P = .001). This remained significant after multiple-testing adjustment ( P ≤ .003 considered significant). Findings were similar, although not significant for small polyps (36% vs 29%, P = .007). There was a trend toward increased adenoma detection in colonoscopies with a fellow present compared with those without (30% vs 26%, P = .11). Multivariable adjustment for potentially confounding variables did not alter these associations. Limitations The study had a retrospective design, and information regarding bowel preparation was not available for 37% of patients. Conclusion Fellow involvement was associated with increased detection rates of small adenomas, providing evidence that the presence of a fellow during colonoscopy plays a role in enhancing the effectiveness of the examination.
Background Probe-based confocal laser endomicroscopy (pCLE) is an emerging tool for in vivo imaging of the GI tract that requires the endoscopist to interpret microscopic images. The learning curve ...for interpretation of pCLE images is unknown. Objective To examine the learning curve of correctly identifying benign and neoplastic colorectal lesions by using pCLE and to evaluate the learning curve of obtaining high-quality images. Design Prospective, double-blind review of pCLE images of 76 colorectal lesions by using corresponding polypectomies as the reference standard. A training set of 20 images with known histology was first reviewed to standardize image interpretation, followed by blinded review of 76 unknown images. Setting Eleven endoscopists from 3 different endoscopy centers evaluated the images obtained by 1 endoscopist using the high-definition confocal probe. Patients Patients undergoing screening and surveillance colonoscopies. Intervention Intravenous fluorescein pCLE imaging of colorectal lesions followed by polypectomies. Main Outcome Measurements Accuracy of image interpretation with constructing learning curve for pCLE image interpretation and acquisition. Results Of the 76 colorectal lesions, 51 (67%) were neoplastic and 25 (33%) were benign, based on histopathology. Accuracy for the overall group was 63% for lesions 1 to 20, 64% for lesions 21 to 40, 79% for lesions 41 to 60, and 86% for lesions 61 to 76. The ability to obtain high-quality images was stable over the 76 cases. Limitations Small sample size and use of offline video sequences. Conclusions Accurate interpretation of pCLE images for predicting neoplastic lesions can be learned rapidly by a wide range of GI specialists. Furthermore, the ability to acquire high-quality pCLE images is also quickly learned.
Background Residual neoplasia after EMR of colorectal lesions is common. There is a critical need for imaging methods to accurately diagnose residual disease and to guide retreatment in real time. ...Objective The aim was to estimate and compare the accuracy of virtual chromoendoscopy (VCE) and probe-based confocal laser endomicroscopy (pCLE) for detection of residual neoplastic tissue at the site of prior EMR. Design Prospective, blind, pilot comparison of advanced endoscopic imaging (VCE and pCLE) by using matching histology as reference standard. Setting Three tertiary-care referral hospitals. Patients This study involved 92 participants who underwent follow-up colonoscopies for the evaluation of prior EMR sites within 1 year. Intervention The EMR scars were assessed during follow-up high-resolution colonoscopy by using VCE (narrow-band imaging/Fujinon Intelligent Color Enhancement FICE), and pCLE. Confocal videos of EMR scars were interpreted in real time and were also stored and reviewed offline, blinded to histopathology and endoscopic appearance. Tissue confirmation by biopsies or polypectomy/repeat EMR was performed in all cases. Main Outcome Measurements Sensitivity, specificity, and accuracy for VCE and pCLE alone and in combination against histopathology as the standard reference standard. Results Among 129 EMR scars, residual neoplasia was confirmed by histology in 29 sites (22%). For VCE, the sensitivity, specificity, positive predictive value (PPV), negative predictive value (NPV), and accuracy were 72%, 77%, 49%, 91%, and 77%, respectively, and were 97%, 77%, 55%, 99%, and 81% for pCLE ( P = .045 for sensitivity). When only EMR scars for which VCE and pCLE agreed on the diagnosis were analyzed (95/129 scars), the accuracy, sensitivity, specificity, PPV, and NPV of pCLE and VCE were 90%, 100%, 87%, 67%, and 100%, respectively. Limitations Small sample size, lack of power, involvement of highly experienced pCLE experts. Conclusion Confocal endomicroscopy significantly increases the sensitivity for detecting residual neoplasia after colorectal EMR compared with endoscopy alone. When confocal endomicroscopy is used in combination with VCE, the accuracy is extremely high, and sensitivity approaches that of histopathology. Together, they may reduce the need for histologic examination and allow a highly accurate on-table decision to treat again or not, thus avoiding unnecessary repeat procedures. (Clinical trial registration number: 00874263 .)
Numerous endoscopic imaging modalities have been developed and introduced into clinical practice to enhance diagnostic capabilities. In the past, detection of dysplasia and carcinoma of the esophagus ...has been dependent on biopsies taken during standard white-light endoscopy. Recent important developments in biophonotics have improved visualization of these subtle lesions sufficiently for cellular details to be seen in vivo during endoscopy. These improvements allow diagnosis to be made in gastrointestinal endoscopy units, thereby avoiding the cost, risk, and time delay involved in tissue biopsy and resection. Chromoendoscopy, narrow-band imaging, high-yield white-light endoscopy, Fujinon intelligent color enhancement, and point enhancement such as confocal laser endomicroscopy are examples of enhanced imaging technologies that are being used in daily practice. This article reviews endoscopic-based imaging techniques for the detection of esophageal dysplasia and carcinoma from the perspective of routine clinical practice.
Despite the rising burden of chronic respiratory diseases, global data for lung function are not available. We investigated global variation in lung function in healthy populations by region to ...establish whether regional factors contribute to lung function.
In an international, community-based prospective study, we enrolled individuals from communities in 17 countries between Jan 1, 2005, and Dec 31, 2009 (except for in Karnataka, India, where enrolment began on Jan 1, 2003). Trained local staff obtained data from participants with interview-based questionnaires, measured weight and height, and recorded forced expiratory volume in 1 s (FEV₁) and forced vital capacity (FVC). We analysed data from participants 130-190 cm tall and aged 34-80 years who had a 5 pack-year smoking history or less, who were not affected by specified disorders and were not pregnant, and for whom we had at least two FEV₁ and FVC measurements that did not vary by more than 200 mL. We divided the countries into seven socioeconomic and geographical regions: south Asia (India, Bangladesh, and Pakistan), east Asia (China), southeast Asia (Malaysia), sub-Saharan Africa (South Africa and Zimbabwe), South America (Argentina, Brazil, Colombia, and Chile), the Middle East (Iran, United Arab Emirates, and Turkey), and North America or Europe (Canada, Sweden, and Poland). Data were analysed with non-linear regression to model height, age, sex, and region.
153,996 individuals were enrolled from 628 communities. Data from 38,517 asymptomatic, healthy non-smokers (25,614 women; 12,903 men) were analysed. For all regions, lung function increased with height non-linearly, decreased with age, and was proportionately higher in men than women. The quantitative effect of height, age, and sex on lung function differed by region. Compared with North America or Europe, FEV1 adjusted for height, age, and sex was 31·3% (95% CI 30·8-31·8%) lower in south Asia, 24·2% (23·5-24·9%) lower in southeast Asia, 12·8% (12·4-13·4%) lower in east Asia, 20·9% (19·9-22·0%) lower in sub-Saharan Africa, 5·7% (5·1-6·4%) lower in South America, and 11·2% (10·6-11·8%) lower in the Middle East. We recorded similar but larger differences in FVC. The differences were not accounted for by variation in weight, urban versus rural location, and education level between regions.
Lung function differs substantially between regions of the world. These large differences are not explained by factors investigated in this study; the contribution of socioeconomic, genetic, and environmental factors and their interactions with lung function and lung health need further clarification.
Full funding sources listed at end of the paper (see Acknowledgments).
