This study examined recovery over the first year following traumatic brain injury (TBI) in children 6-12 years of age. Forty-two children with severe TBI and 52 with moderate TBI were compared to 58 children with orthopedic injuries. The children and their families were evaluated at a baseline assessment and at 6- and 12-month follow-ups. Findings documented cognitive, achievement, and behavioral sequelae of TBI, with only limited evidence for recovery over the first year postinjury. Outcomes were predicted by preinjury factors, TBI severity, and measures of the postinjury family environment. Some of the sequelae of severe TBI were more marked in the context of higher compared with lower levels of family burden or dysfunction. The findings confirm the need to consider environmental contributions to outcomes of TBI in children.
Previous studies of childhood traumatic brain injury
(TBI) have emphasized injury-related variables rather than
environmental factors as predictors of recovery. We addressed
this concern using data collected during a prospective
study of children with either TBI or orthopedic injuries
(OI) and their families. Participants included 53 children
with severe TBI, 56 with moderate TBI, and 80 with OI,
all from 6 to 12 years of age at the time of injury. Measures
of the preinjury family environment were collected shortly
after the injury (baseline). Child cognitive and behavioral
outcomes were assessed at baseline and at 6- and 12-month
follow-ups. Individual growth curve analyses showed that
measures of the preinjury family environment consistently
predicted both the level of cognitive and behavioral functioning
at 12 months postinjury and the rate of intraindividual
change during the 12-month follow-up period, even after
taking into account group membership and injury severity.
In some cases, the preinjury family environment was a significant
moderator of the effect of TBI, buffering its impact in
high-functioning families and exacerbating it in low-functioning
families. Thus, preinjury environmental factors predict
recovery following TBI in children, even after accounting
for injury-related variables. (JINS, 1997, 3,
617–630.)
Recent emphasis on high resolution gradient echo studies in functional imaging has led to the conclusion that there are likely three domains of response to the blood circulation in the brain when considering field inhomogeneity effects of the venous blood pre- and during activation. The first is a coherent effect due to large or macroscopic vessels on the order of the size of the voxel (ca 200-500 microns in most studies). These can lead to very large signal changes (up to 100%). The second is at the venule level (ca 50-200 microns) and is associated with smaller parenchymal changes (usually ca 10% or less). The third is at the capillary level and is associated with much smaller signal changes at 1.5 T and even up to 4 T. The actual signal changes depend on field strength and sequence design. In this paper, we present our experience in detecting the first two domains with 2D and 3D gradient echo imaging at 1.5 T. We find that high resolution enables visualization of the larger small veins in motor cortex studies and that, on occasion, it is possible to see the venule effects as well. We suggest a simple model to explain the large signal changes based on susceptibility changes and partial volume effects. Comparisons of the functional imaging data to this model and to MR angiographic studies are also shown as evidence of the venous sources of the susceptibility changes.
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