Development and evaluation of a vancomycin dosing nomogram to achieve the target area under the concentration-time curve. A retrospective study.

Although the superiority of vancomycin dosing based on area under the concentration-time curve (AUC0-24) over that based on trough concentration has been reported, a dosing strategy to achieve the target AUC0-24 has yet to be developed. The objective of this study was to develop a convenient useable nomogram for vancomycin dosing to obtain the target AUC0-24 (400 µg h/mL). The nomogram was pharmacokinetically developed in a retrospective manner. The number of enrolled patients and concentrations was 166 and 309 for development of the nomogram, 99 and 181 for evaluation of the nomogram, respectively. The nomogram was developed as doses per personal body weight corresponding to each range of estimated glomerular filtration rate (eGFR), which was identified to be the covariate for vancomycin clearance by non-linear mixed effect modeling. The nomogram described the surrogate trough concentration for the target AUC0-24 was calculatedly different for each eGFR range (9.3-15.0 µg/mL). The rate of attainment of therapeutic range using surrogate trough concentration to obtain the target AUC0-24 was 63.8% in the evaluation period. We have developed and evaluated the first convenient useable nomogram of vancomycin dosing to obtain the target AUC0-24.

Reconstruction of an inner layer defect of the upper eyelid with avulsion of the superior levator palpebrae muscle and orbital fat.

The authors report a successful reconstruction of the total upper eyelid in conjunction with the gliding surface of the extraocular muscles. A 21-year-old woman sustained an inner layer defect of her right upper eyelid together with avulsions of the superior levator palpebrae muscle and the superior orbital fat. Her right superior rectus muscle was exposed, and no orbital fat was seen in the space between the muscle and the orbital roof. To preserve eye movement, a gliding surface between the superior rectus muscle and the orbital roof had to be reconstructed. Total upper lid reconstruction was performed using a radial forearm flap with a hard palate mucosal graft. The gliding surface was reconstructed with an adipofascial flap obtained from the forearm. Despite lack of levator function, the patient could raise her eyelid approximately 5 mm by using only the superior rectus muscle without frontalis suspension.

Correction of nonuniform attenuation and image fusion in SPECT imaging by means of separate X-ray CT.

Improvements in image quality and quantitation measurement, and the addition of detailed anatomical structures are important topics for single-photon emission tomography (SPECT). The goal of this study was to develop a practical system enabling both nonuniform attenuation correction and image fusion of SPECT images by means of high-performance X-ray computed tomography (CT). A SPECT system and a helical X-ray CT system were placed next to each other and linked with Ethernet. To avoid positional differences between the SPECT and X-ray CT studies, identical flat patient tables were used for both scans; body distortion was minimized with laser beams from the upper and lateral directions to detect the position of the skin surface. For the raw projection data of SPECT, a scatter correction was performed with the triple energy window method. Image fusion of the X-ray CT and SPECT images was performed automatically by auto-registration of fiducial markers attached to the skin surface. After registration of the X-ray CT and SPECT images, an X-ray CT-derived attenuation map was created with the calibration curve for 99mTc. The SPECT images were then reconstructed with scatter and attenuation correction by means of a maximum likelihood expectation maximization algorithm. This system was evaluated in torso and cylindlical phantoms and in 4 patients referred for myocardial SPECT imaging with Tc-99m tetrofosmin. In the torso phantom study, the SPECT and X-ray CT images overlapped exactly on the computer display. After scatter and attenuation correction, the artifactual activity reduction in the inferior wall of the myocardium improved. Conversely, the incresed activity around the torso surface and the lungs was reduced. In the abdomen, the liver activity, which was originally uniform, had recovered after scatter and attenuation correction processing. The clinical study also showed good overlapping of cardiac and skin surface outlines on the fused SPECT and X-ray CT images. The effectiveness of the scatter and attenuation correction process was similar to that observed in the phantom study. Because the total time required for computer processing was less than 10 minutes, this method of attenuation correction and image fusion for SPECT images is expected to become popular in clinical practice.