Common normal variants of pediatric vertebral development that mimic fractures: a pictorial review from a national longitudinal bone health study.

Children with glucocorticoid-treated illnesses are at risk for osteoporotic vertebral fractures, and growing awareness of this has led to increased monitoring for these fractures. However scant literature describes developmental changes in vertebral morphology that can mimic fractures. The goal of this paper is to aid in distinguishing between normal variants and fractures. We illustrate differences using lateral spine radiographs obtained annually from children recruited to the Canada-wide STeroid-Associated Osteoporosis in the Pediatric Population (STOPP) observational study, in which 400 children with glucocorticoid-treated leukemia, rheumatic disorders, and nephrotic syndrome were enrolled near glucocorticoid initiation and followed prospectively for 6 years. Normal variants mimicking fractures exist in all regions of the spine and fall into two groups. The first group comprises variants mimicking pathological vertebral height loss, including not-yet-ossified vertebral apophyses superiorly and inferiorly, which can lead to a vertebral shape easily over-interpreted as anterior wedge fracture, physiological beaking, or spondylolisthesis associated with shortened posterior vertebral height. The second group includes variants mimicking other radiologic signs of fractures: anterior vertebral artery groove resembling an anterior buckle fracture, Cupid's bow balloon disk morphology, Schmorl nodes mimicking concave endplate fractures, and parallax artifact resembling endplate interruption or biconcavity. If an unexpected vertebral body contour is detected, careful attention to its location, detailed morphology, and (if available) serial changes over time may clarify whether it is a fracture requiring change in management or simply a normal variant. Awareness of the variants described in this paper can improve accuracy in the diagnosis of pediatric vertebral fractures.

Effect of voice recognition on radiologist reporting time.

OBJECTIVE: To study the effect that voice recognition (VR) has on radiologist reporting efficiency in a clinical setting and to identify variables associated with faster reporting time. METHODS: Five radiologists were observed during the routine reporting of 402 plain radiograph studies using either VR (n = 217)or conventional dictation (CD) (n = 185). Two radiologists were observed reporting 66 computed tomography (CT) studies using either VR (n = 39) or CD (n = 27). The time spent per reporting cycle, defined as the radiologist's time spent on a study from report finalization to the subsequent report finalization, was compared. As well, characteristics about the radiologist and their reporting style were collected and correlated against reporting time. RESULTS: For plain radiographs, radiologists took 13.4% (P= 0.048) more time to produce reports using VR, but there was significant variability between radiologists. Significant association with faster reporting times using VR included: English as a first language (r = -0.24), use of a template (r = -0.34), use of a headset microphone (r = -0.46), and increased experience with VR (r= -0.43). Experience as a staff radiologist and having a previous study for comparison did not correlate with reporting time. For CT, there was no significant difference in reporting time identified between VR and CD (P = 0.61). CONCLUSIONS: Overall, VR slightly decreases the reporting efficiency of radiologists. However, efficiency may be improved if English is a first language, a headset microphone, and macros and templates are used.

Delivery of recombinant gene product to canine brain with the use of microencapsulation.

An alternative approach to somatic gene therapy is to deliver a therapeutic protein by implanting "universal" recombinant cells that are immunologically protected from graft rejection with alginate microcapsules. This strategy has proved successful in reversing pathologic conditions in several rodent models of human disease (dwarfism, lysosomal storage disease, hemophilia, cancer). In particular, neurologic disease and behavioral deficit in the mouse model of a neurodegenerative disease (mucopolysaccharidosis [MPS] VII) were significantly improved through the intraventricular implantation of the recombinant encapsulated cells. Here we report the feasibility of delivering recombinant gene products to the central nervous systems (CNSs) of dogs, first using human growth hormone as a marker for delivery in normal dogs and then using alpha-iduronidase as a therapeutic product for delivery in the MPS I dog that is genetically deficient in this lysosomal enzyme. Madin-Darby canine kidney cells were genetically modified to express either human growth hormone or canine alpha-iduronidase, then enclosed in alginate-poly-l-lysine-alginate microcapsules of about 500 microm in diameter. The encapsulated cells were implanted into the brain under steoreotaxic guidance. The brains were monitored with computed tomographic scans before and after surgery and examined biochemically and histologically. Delivery of gene products, as measured in the plasma and cerebrospinal fluid sampled periodically through 21 days or in various regions of the brain after death showed that the delivery of both gene products was extremely low but detectable. However, we noted extensive inflammatory reactions, both at the sites of implantation and in the immediate vicinity of the implanted microcapsules. Hence for this technology to be applicable to the CNSs of larger animals and human beings, a more accurate and less invasive neurosurgical procedure, more biocompatible microcapsule-recombinant cell combinations, and higher output of recombinant products must be developed.