Extensive (8 to 12 cm2) noncircumferential endoscopic mucosal resection for early esophageal cancer.

Background: Endoscopic mucosal resection (EMR) is an appealing method for treating intramucosal esophageal cancer but must comply with the following stringent requirements: proper preoperative staging, complete resection of the lesion, obtaining a resected specimen for histologic analysis of safety margins, and squamous reepithelialization without stricture formation. Methods: A rigid esophagoscope was created to resect up to 12 cm(2) of esophageal mucosa in a single specimen and at a constant depth through the submucosa. Under visual control, the esophageal mucosa is sucked into a transparent window and resected with a thin diathermy wire loop in 10 seconds. After extensive preclinical studies in a sheep model, this article reports our early experience in humans. Results: Twenty-one hemi-circumferential EMRs were performed for 11 dysplastic Barrett's esophagi and 10 early squamous cell carcinomas with no perforation, one hemorrhage controlled by embolization of the left gastric artery, and one incomplete resection. Deep safety margins were clear in 19 of 21 resected specimens (2 patients, unfit for operations, had submucosal invasion of squamous cell carcinoma and adenocarcinoma, respectively). Lateral margins were not clear by definition in 7 circumferential Barrett's esophagi, but were clear in 4 incomplete Barrett's esophagi and 10 early squamous cell carcinomas. Conclusions: Large EMRs of 12 cm(2) can safely be performed at the submucosal level in the esophagus. Although feasible in one session, circumferential EMR in humans is not yet advisable because of the risk of stricture formation during the healing phase. The rate of complications of this series of 21 EMRs in humans is acceptable. (Ann Thorac Surg 2010; 89: S2151-5) (C) 2010 by The Society of Thoracic Surgeons

Health consultation : Exposure to fluff material from the Shine Brothers and noise concerns -- Spencer, Iowa (2011)

This letter has been prepared as a consultation to determine some potential health concerns raised by a resident of Spencer from exposure to wire shredder fluff material emitted by Shine Brothers metal salvaging facility in Spencer, Iowa on July 10, 2011 and, a concern regarding the health impacts from the level of noise measured by a resident near the metal salvaging facility.

Large gypsum nodules in the Paleogene and Neogene evaporites of Spain: distribution and palaeogeographic significance

Sabkha and deep burial set tings are the most com mon sites where diagenetic anhydrite forms. In a sabkha setting, displacive facies (iso lated nodules, bed ded nodules, enterolithic levels) of early diagenetic or primary anhydrite are generated (Shearman, 1966; Hardie, 1967). These anhydrite facies are commonly foundat the top of shoal ing cycles representing the evolution from subaqueous depositional conditions at the base (carbonates, lutites) to exposure conditions at the top where in ter stitially-grown gypsum/anhydrite de velops ( sabkha cy cles). In a deep burial setting, gypsum transforms to tally to anhydrite with in creas ing temperature and lithostatic pressure (Murray, 1964). Al though this mineral transformation usually preserves the depositional gypsum facies, a significant textural change is in volved in other cases, resulting in replacive anhydrite with a nodular-mosaic or"chicken-wire" fabric (Warren, 2006). In the two settings, how ever, the size of the individual anhydrite nodules is relatively small, rarely reaching some tens of centimetres across. More over, bedding is preserved or little disturbed, al though minor de formation is caused by the displacive sabkha nodules.

Gefäßchirurgische Ausbildung in endovaskulärer Technik in Lausanne

Between 1995 and 2005, the number of aortic aneurysms treated annually using endovascular techniques (EVAR) increased from 0 to 50, including all aortic stages. Our organization includes a large team of surgeons, a stock of three complete families of endoprostheses (straight, conical and bifurcated), a mobile trolley with accessories (arterial introducer/introducer sheath, guide wire, catheters, balloons, etc.) and an appliance on wheels for intravascular ultrasound examination (IVUS). This appliance, together with a mobile fluoroscopy device (c-arm), allows endovascular aneurysms analysis of every operating room in our institution, usually without angiography or the use of contrast medium. In general, we are therefore not depending on substantial preoperative imaging in order to identify candidates for endovascular aneurysms repair and can treat abdominal and thoracic aortic ruptures without delay. For endovascular aortic aneurysms repair we distinguish between process steps on the one hand (determining indications, imaging of the access vessels, measurement using IVUS and road mapping via fluoroscopy, selection of implant, implant insertion, positioning, setting the implant, determining success, reconstruction of the access vessel and follow-up) and the level of competence on the other (assistant, senior and directing physicians). Our ultrasound supported technique for endovascular aneurysms repair has been successfully brought to other hospitals using an IVUS transporter and telementoring.