Prolonged culture of human islets induces ER stress.

Type 2 diabetes (T2D) is characterized by islet dysfunction and beta-cell deficiency caused by apoptosis. One mechanism underlying induction of beta-cell apoptosis is stress in the endoplasmic reticulum (ER). Isolated human islets are a frequently used model to examine islet pathophysiology in T2D. Therefore it is important to establish how function and beta-cell turnover of human islets change in culture. Islets from four organ donors were cultured over four weeks. At 0, 1, 2, 3 and 4 weeks aliquots of islets were used for analysis of a) islet-cell turnover (replication by Ki-67 and apoptosis by TUNEL staining), b) the ER stress level (CHOP and phospho-eIF2alpha staining), c) fractional beta-cell content (insulin staining) and d) islet function (2 h static incubation). Culture duration positively correlated to replication (p=0.03) and negatively correlated to apoptosis (p=0.003). In comparison to islets in situ islet cell turnover is accelerated (>10-fold). The ER stress level was stable during the first three weeks, but showed a sharp increase (p<0.05) at four weeks. The fractional beta-cell content increased from 29+/-2% to 41+/-2% (p=0.0004). Islet function improved (p<0.0001). In conclusion, isolated human islets may be used for in vitro experiments for up to three weeks. During this time islet function and islet-cell turnover are stable. If islet culture is extended beyond three weeks ER stress may impair islet viability. Studies analyzing the pathophysiology of human T2D at the level of the endocrine pancreas need to confirm results obtained with isolated human islets by analysis of primary human pancreatic tissue.

Image guided respiratory gated hypofractionated Stereotactic Body Radiation Therapy (H-SBRT) for liver and lung tumors: Initial experience.

To evaluate our initial experience with image guided respiratory gated H-SBRT for liver and lung tumors. The system combines a stereoscopic x-ray imaging system (ExacTrac X-Ray 6D) with a dedicated conformal stereotactic radiosurgery and radiotherapy linear accelerator (Novalis) and ExacTrac Adaptive Gating for dynamic adaptive treatment. Moving targets are located and tracked by x-ray imaging of implanted fiducial markers defined in the treatment planning computed tomography (CT). The marker position is compared with the position in verification stereoscopic x-ray images, using fully automated marker detection software. The required shift for a correct, gated set-up is calculated and automatically applied. We present our acceptance testing and initial experience in patients with liver and lung tumors. For treatment planning CT and Fluorodeoxyglucose-Positron Emission Tomography (FDG-PET) as well as magnetic resonance imaging (MRI) taken at free breathing and expiration breath hold with internal and external fiducials present were used. Patients were treated with 8-11 consecutive fractions to a dose of 74.8-79.2 Gy. Phantom tests demonstrated targeting accuracy with a moving target to within +/-1 mm. Inter- and intrafractional patient set-up displacements, as corrected by the gated set-up and not detectable by a conventional set-up, were up to 30 mm. Verification imaging to determine target location during treatment showed an average marker position deviation from the expected position of up to 4 mm on real patients. This initial evaluation shows the accuracy of the system and feasibility of image guided real-time respiratory gated H-SBRT for liver and lung tumors.