3D Printed Biomimetic Rabbit Airway Simulation Model for Nasotracheal Intubation Training.

Rabbit inhalation anesthesia by endotracheal intubation involves a higher risk among small animals owing to several anatomical and physiological features, which is pathognomonic to this species of lagomorphs. Rabbit-specific airway devices have been designed to prevent misguided intubation attempts. However, it is believed that expert anesthetic training could be a boon in limiting the aftermaths of this procedure. Our research is aimed to develop a novel biomimetic 3D printed rabbit airway model with representative biomechanical material behavior and radiodensity. Imaging data were collected for two sacrificed rabbit heads using micro-computed tomography (µCT) and micro-magnetic resonance imaging for the first head and cone beam computed tomography (CBCT) for the second head. Imaging-based life-size musculoskeletal airway models were printed using polyjet technology with a combination of hard and soft materials in replicates of three. The models were evaluated quantitatively for dimensional accuracy and radiodensity and qualitatively using digital microscopy and endoscopy for technical, tactic, and visual realism. The results displayed that simulation models printed with polyjet technology have an overall surface representation of 93% for µCT-based images and 97% for CBCT-based images within a range of 0.0-2.5 mm, with µCT showing a more detailed reproduction of the nasotracheal anatomy. Dimensional discrepancies can be caused due to inadequate support material removal and due to the limited reconstruction of microstructures from the imaging on the 3D printed model. The model showed a significant difference in radiodensities in hard and soft tissue regions. Endoscopic evaluation provided good visual and tactile feedback, comparable to the real animal. Overall, the model, being a practical low-cost simulator, comprehensively accelerates the learning curve of veterinary nasotracheal intubation and paves the way for 3D simulation-based image-guided interventional procedures.

[Evaluation of the performance of a gamma camera equipped with a 5/8" versus 1" thick NaI detector]. / Vergleich der Abbildungseigenschaften einer Gammakamera mit 5/8" (15 mm) NaI-Szintillationskristall und 1" (25 mm)-Kristall.

The upgrade of a gamma camera from a 5/8" to a 1" thick crystal, the latter with StarBrite technology, prompted to the investigation of changes in performance parameters for planar scintigraphy and SPECT as well as for PET in coincidence mode. For planar and SPECT parameters, the performance was measured according to NEMA Standard Protocol NU1-2001. No changes were found in terms of intrinsic uniformity, intrinsic spatial resolution, linearity, energy resolution, system resolution, and tomographic system resolution. The only change was an increase of system sensitivity for higher energy gamma rays. For the PET scanner in coincidence mode, the image quality of the camera was determined according to NEMA NU2-2001. Visually and in terms of contrast values there was a significant improvement of image quality. Changes in image quality relevant for clinical use were tested by evaluation of planar patient scans acquired within a short time with two gamma cameras of the same type, different only in crystal thickness (5/8" and 1"). No statistically significant difference was found between corresponding scans. For planar and SPECT imaging, the gamma camera with 1" thick detector and StarBrite technology demonstrated the same performance of a camera with a 5/8" crystal. For PET in coincidence mode the new detector proved clearly superior.

Multiple window spatial registration error of a gamma camera: 133Ba point source as a replacement of the NEMA procedure.

BACKGROUND: The accuracy of multiple window spatial resolution characterises the performance of a gamma camera for dual isotope imaging. In the present study we investigate an alternative method to the standard NEMA procedure for measuring this performance parameter. METHODS: A long-lived 133Ba point source with gamma energies close to 67Ga and a single bore lead collimator were used to measure the multiple window spatial registration error. Calculation of the positions of the point source in the images used the NEMA algorithm. The results were validated against the values obtained by the standard NEMA procedure which uses a liquid 67Ga source with collimation. RESULTS: Of the source-collimator configurations under investigation an optimum collimator geometry, consisting of a 5 mm thick lead disk with a diameter of 46 mm and a 5 mm central bore, was selected. The multiple window spatial registration errors obtained by the 133Ba method showed excellent reproducibility (standard deviation < 0.07 mm). The values were compared with the results from the NEMA procedure obtained at the same locations and showed small differences with a correlation coefficient of 0.51 (p < 0.05). In addition, the 133Ba point source method proved to be much easier to use. A Bland-Altman analysis showed that the 133Ba and the 67Ga Method can be used interchangeably. CONCLUSION: The 133Ba point source method measures the multiple window spatial registration error with essentially the same accuracy as the NEMA-recommended procedure, but is easier and safer to use and has the potential to replace the current standard procedure.