A quality initiative of postoperative radiographic imaging performed on mastectomy specimens to reduce histology cost and pathology report turnaround time.

Breast pathology relies on gross dissection for accurate diagnostic work, but challenges can necessitate submission of high tissue volumes resulting in excess labor, laboratory costs, and delays. To address these issues, a quality initiative was created through implementation of the Faxitron PathVision specimen radiography system as part of the breast gross dissection protocol; this report documents its impact on workflow and clinical care. Retrospective data from 459 patients who underwent simple or modified radical mastectomy at our institution between May 2012 and December 2014 were collected. Comparison was made between the mastectomy specimen control group before radiography use (233 patients, 340 breasts) and Faxitron group that underwent postoperative radiography (226 patients, 338 breasts). We observed a statistically significant decrease in mean number of blocks between control and Faxitron groups (47.0 vs 39.7 blocks; P<.0001), for calculated cost savings of US $146 per mastectomy. A statistically significant decrease in pathology report turnaround time was also observed (4.2 vs 3.8days; P=.038). Postoperative mastectomy specimen radiography has increased workflow efficiency and decreased histology costs and pathology report turnaround time. These findings may underestimate actual benefits and highlight the importance of quality improvement projects in anatomical pathology.

A system for evaluating magnetic resonance imaging of prostate cancer using patient-specific 3D printed molds.

We have developed a system for evaluating magnetic resonance imaging of prostate cancer, using patient-specific 3D printed molds to facilitate MR-histology correlation. Prior to radical prostatectomy a patient receives a multiparametric MRI, which an expert genitourinary radiologist uses to identify and contour regions suspicious for disease. The same MR series is used to generate a prostate contour, which is the basis for design of a patient-specific mold. The 3D printed mold contains a series of evenly spaced parallel slits, each of which corresponds to a known MRI slice. After surgery, the patient's specimen is enclosed within the mold, and all whole-mount levels are obtained simultaneously through use of a multi-bladed slicing device. The levels are then formalin fixed, processed, and delivered to an expert pathologist, who identifies and grades all lesions within the slides. Finally, the lesion contours are loaded into custom software, which elastically warps them to fit the MR prostate contour. The suspicious regions on MR can then be directly compared to lesions on histology. Furthermore, the false-negative and false-positive regions on MR can be retrospectively examined, with the ultimate goal of developing methods for improving the predictive accuracy of MRI. This work presents the details of our analysis method, following a patient from diagnosis through the MR-histology correlation process. For this patient MRI successfully predicted the presence of cancer, but true lesion volume and extent were underestimated. Most cancer-positive regions missed on MR were observed to have patterns of low T2 signal, suggesting that there is potential to improve sensitivity.