Intracranial Penetration During Temporal Soft Tissue Filler Injection-Is It Possible?

BACKGROUND Treating temporal volume loss for aesthetic and reconstructive purposes can be achieved by superficial or deep injections of soft tissue fillers into the temples. The latter is performed with bone contact that can lead to intracranial penetration when the bone is accidentally penetrated. OBJECTIVE Based on a clinical case, the potential risk of accidental intracranial penetration was investigated. MATERIALS AND METHODS Twenty fresh-frozen hemi-faces (all Caucasian ethnicity, 10 women, 10 men, mean age 72.8 +/- 11.2 years) were investigated. Shape of pterion and bone-stability parameters of the temporal fossa were investigated. Bone stability was tested using uniaxial mechanical indentation (18-G, 1.25-mm diameter, 15-mm length blunt-tip device) until intracranial perforation occurred. RESULTS Variations in the shape of the pterion, bone thickness, and density correlates were detected, however, without statistical significant differences in side symmetry. Minimum force necessary to penetrate intracranially was 40.4 N. Maximum force generated by an 18-g, 70-mm length blunt-tip cannula was 32.1 +/- 4.2 N in 70 mm length and 75.3 +/- 10.2 N in 15 mm length. CONCLUSION Based on the results of this investigation, it can be concluded that there is a risk for intracranial penetration performing the deep temple injection technique with direct pressure on the bone

A human glomerular SAGE transcriptome database

Background: To facilitate in the identification of gene products important in regulating renal glomerular structure and function, we have produced an annotated transcriptome database for normal human glomeruli using the SAGE approach. Description: The database contains 22,907 unique SAGE tag sequences, with a total tag count of 48,905. For each SAGE tag, the ratio of its frequency in glomeruli relative to that in 115 non-glomerular tissues or cells, a measure of transcript enrichment in glomeruli, was calculated. A total of 133 SAGE tags representing well-characterized transcripts were enriched 10-fold or more in glomeruli compared to other tissues. Comparison of data from this study with a previous human glomerular Sau3A-anchored SAGE library reveals that 47 of the highly enriched transcripts are common to both libraries. Among these are the SAGE tags representing many podocyte-predominant transcripts like WT-1, podocin and synaptopodin. Enrichment of podocyte transcript tags SAGE library indicates that other SAGE tags observed at much higher frequencies in this glomerular compared to non-glomerular SAGE libraries are likely to be glomerulus-predominant. A higher level of mRNA expression for 19 transcripts represented by glomerulus-enriched SAGE tags was verified by RT-PCR comparing glomeruli to lung, liver and spleen. Conclusions: The database can be retrieved from, or interrogated online at http://cgap.nci.nih.gov/SAGE. The annotated database is also provided as an additional file with gene identification for 9,022, and matches to the human genome or transcript homologs in other species for 1,433 tags. It should be a useful tool for in silico mining of glomerular gene expression