Apparent diffusion coefficient map of a case of extramedullary plasmacytoma.

Plasmacytomas are rare tumors, which arise from the monoclonal proliferation of malignant plasma cells. They may affect either the bony skeleton or rarely the soft tissues, the latter being referred to as extramedullary or extraosseous. We report a case of an extramedullary plasmacytoma that presented as a soft tissue mass involving the muscles of the left leg, in a patient who was previously treated for multiple myeloma. We describe the MR Imaging characteristics of the tumor and highlight the usefulness of diffusion-weighted imaging with apparent diffusion coefficient mapping.

Microdensitometric and microarchitectural alterations in irradiated mandibular fracture repair.

Head and neck cancer most often requires a multimodality approach to treatment that includes the use of radiotherapy. Unfortunately, radiation treatment can cause significant locoregional adverse effects with the particularly debilitating sequelae of late pathologic fracture. We aimed to define comprehensive metrics that will allow us to evaluate the efficacy of therapies aimed at assuaging the damaging effects of radiation on fracture healing.Six male rats (XRT/Fx) received a 36-Gy preoperative radiation dose delivered in 10 fractions over 10 days to their left hemimandible, whereas 6 other rats were not irradiated (Fx). After a recovery period, a unilateral osteotomy was performed with external distractor placement set to a 2.1-mm fracture gap on all the animals. Following a 28-day consolidation interval, mandibles were harvested and scanned via micro-computed tomography. Radiomorphometrics were extracted and analyzed with significance at P < 0.05.A quantifiable decrease in bone volume fraction (73.9% vs 78.6%; P < 0.05) was observed in XRT/Fx compared with Fx, without significant change in bone mineral density. Microarchitectural metrics were significantly altered in XRT/Fx compared with Fx, specifically trabecular thickness (0.37 vs 0.30 µm; P = 0.01), trabecular number (2.18 vs 2.45 N/mm; P = 0.04), and bone surface-bone volume ratio (5.50 vs 6.70; P = 0.01).We found that the irradiated and fractured bone demonstrated a significant diminution in bone quality and strength. We have established predictable and reliable radiographic measures that quantitatively demonstrate the degradative effects of radiation on fracture repair. We can now utilize these comprehensive metrics to evaluate the benefits of therapeutic interventions to remediate the damaging effects of radiation on fracture healing.

Quantitative histomorphometric assessment of regenerate cellularity and bone quality in mandibular distraction osteogenesis after radiation therapy.

BACKGROUND: The use of mandibular distraction osteogenesis (MDO) for tissue replacement after oncologic resection in head and neck cancer could have immense therapeutic ramifications. We have previously demonstrated significantly decreased mechanical and microdensitomeric metrics of our MDO regenerate after 36-Gy radiation. Quantitative histomorphometry, a third metric, would permit objective investigation of the effects of radiation on tissue and cellular composition. Our hypothesis is that radiation-induced cellular depletion and diminution in function impair optimal bone regeneration. METHODS: Five rats received radiation to the left mandible; 5 received none. All animals underwent surgical placement of external fixators, creation of mandibular osteotomies, distraction to a 5.1-mm gap width, and consolidation. Point counting and color thresholding were performed. RESULTS: There was a significant increase in empty lacunae and a corresponding diminution in osteocytes after radiation. Whereas the volume fraction of mineralized, mature bone was not different, that of nonmineralized, immature osteoid was significantly increased in the radiated group compared with that in the nonradiated group. CONCLUSIONS: Our findings confirm our prior 2 metrics. Actually, all 3 diverse metrics--microdensitometry, biomechanical analysis, and histomorphometry--corroborate our hypothesis of cellular depletion and diminution of function as the potential mechanism of radiation-induced attenuation in the distracted regenerate. Furthermore, our findings of tissue and cellular changes in the irradiated regenerate elucidate the pathophysiology of decreased bone quality when amalgamated with our previous results. Therapeutic agents may now be introduced, and their effects on the irradiated regenerate critically measured, so that MDO may be used as a viable reconstructive option in patients with head and neck cancer.