1,492 research outputs found
Taking Chances: The Effect of Growing Up on Welfare on the Risky Behavior of Young People
We analyze the effect of growing up on welfare on young people's involvement in a variety of social and health risks. Young people in welfare families are much more likely to take both social and health risks. Much of the apparent link between family welfare history and risk taking disappears, however, once we account for family structure and mothers' decisions regarding their own risk taking and investment in their children. Interestingly, we find no significant effect of socio-economic status per se. Overall, we find no evidence that growing up on welfare causes young people to engage in risky behavior.youths, welfare, risky behavior, socio-economic disadvantage
A Couples-Based Approach to the Problem of Workless Families
The goal of this paper is to evaluate a ?couples-based? policy intervention designed to reduce the number of Australian families without work. In 2000 and 2001, the Australian Government piloted a new counseling initiative targeted towards couple-headed families with dependent children in which neither partner was in paid employment. Selected women on family benefits
(who were partnered with men receiving unemployment benefits) were randomly invited to participate in an interview process designed to identify strategies for increasing economic and social participation. While some women were interviewed on their own, others participated in a joint interview with their partners. Our results indicate that the overall effect of the interview process led to lower hours of work among family benefit recipients in the
intervention group than the control group, but to greater participation and hours in job search and in study or training for work-related reasons. At the same time, there are few significant differences in the effect of the interview process on the economic and social activity of women interviewed with and without their unemployed partners
Spherical convolutional neural networks can improve brain microstructure estimation from diffusion MRI data
Diffusion magnetic resonance imaging is sensitive to the microstructural
properties of brain tissue. However, estimating clinically and scientifically
relevant microstructural properties from the measured signals remains a highly
challenging inverse problem that machine learning may help solve. This study
investigated if recently developed rotationally invariant spherical
convolutional neural networks can improve microstructural parameter estimation.
We trained a spherical convolutional neural network to predict the ground-truth
parameter values from efficiently simulated noisy data and applied the trained
network to imaging data acquired in a clinical setting to generate
microstructural parameter maps. Our network performed better than the spherical
mean technique and multi-layer perceptron, achieving higher prediction accuracy
than the spherical mean technique with less rotational variance than the
multi-layer perceptron. Although we focused on a constrained two-compartment
model of neuronal tissue, the network and training pipeline are generalizable
and can be used to estimate the parameters of any Gaussian compartment model.
To highlight this, we also trained the network to predict the parameters of a
three-compartment model that enables the estimation of apparent neural soma
density using tensor-valued diffusion encoding
Optic radiation structure and anatomy in the normally developing brain determined using diffusion MRI and tractography
The optic radiation (OR) is a component of the visual system known to be myelin mature very early in life. Diffusion tensor imaging (DTI) and its unique ability to reconstruct the OR in vivo were used to study structural maturation through analysis of DTI metrics in a cohort of 90 children aged 5â18 years. As the OR is at risk of damage during epilepsy surgery, we measured its position relative to characteristic anatomical landmarks. Anatomical distances, DTI metrics and volume of the OR were investigated for age, gender and hemisphere effects. We observed changes in DTI metrics with age comparable to known trajectories in other white matter tracts. Left lateralization of DTI metrics was observed that showed a gender effect in lateralization. Sexual dimorphism of DTI metrics in the right hemisphere was also found. With respect to OR dimensions, volume was shown to be right lateralised and sexual dimorphism demonstrated for the extent of the left OR. The anatomical results presented for the OR have potentially important applications for neurosurgical planning
Fibre tract segmentation for intraoperative diffusion MRI in neurosurgical patients using tract-specific orientation atlas and tumour deformation modelling
Purpose:: Intraoperative diffusion MRI could provide a means of visualising brain fibre tracts near a neurosurgical target after preoperative images have been invalidated by brain shift. We propose an atlas-based intraoperative tract segmentation method, as the standard preoperative method, streamline tractography, is unsuitable for intraoperative implementation. Methods:: A tract-specific voxel-wise fibre orientation atlas is constructed from healthy training data. After registration with a target image, a radial tumour deformation model is applied to the orientation atlas to account for displacement caused by lesions. The final tract map is obtained from the inner product of the atlas and target image fibre orientation data derived from intraoperative diffusion MRI. Results:: The simple tumour model takes only seconds to effectively deform the atlas into alignment with the target image. With minimal processing time and operator effort, maps of surgically relevant tracts can be achieved that are visually and qualitatively comparable with results obtained from streamline tractography. Conclusion:: Preliminary results demonstrate feasibility of intraoperative streamline-free tract segmentation in challenging neurosurgical cases. Demonstrated results in a small number of representative sample subjects are realistic despite the simplicity of the tumour deformation model employed. Following this proof of concept, future studies will focus on achieving robustness in a wide range of tumour types and clinical scenarios, as well as quantitative validation of segmentations
Markov Chain Monte Carlo Random Effects Modeling in Magnetic Resonance Image Processing Using the BRugs Interface to WinBUGS
A common feature of many magnetic resonance image (MRI) data processing methods is the voxel-by-voxel (a voxel is a volume element) manner in which the processing is performed. In general, however, MRI data are expected to exhibit some level of spatial correlation, rendering an independent-voxels treatment inefficient in its use of the data. Bayesian random effect models are expected to be more efficient owing to their information-borrowing behaviour.
To illustrate the Bayesian random effects approach, this paper outlines a Markov chain Monte Carlo (MCMC) analysis of a perfusion MRI dataset, implemented in R using the BRugs package. BRugs provides an interface to WinBUGS and its GeoBUGS add-on. WinBUGS is a widely used programme for performing MCMC analyses, with a focus on Bayesian random effect models. A simultaneous modeling of both voxels (restricted to a region of interest) and multiple subjects is demonstrated. Despite the low signal-to-noise ratio in the magnetic resonance signal intensity data, useful model signal intensity profiles are obtained. The merits of random effects modeling are discussed in comparison with the alternative approaches based on region-of-interest averaging and repeated independent voxels analysis.
This paper focuses on perfusion MRI for the purpose of illustration, the main proposition being that random effects modeling is expected to be beneficial in many other MRI applications in which the signal-to-noise ratio is a limiting factor
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