1,818 research outputs found
The Impact of Body Image on Women in Later Life: Effects on Quality of Life and Body Perception
Physical, mental, and emotional changes can occur throughout the aging process, making it important to treat different age groups as separate populations when researching body image. Yet, very few instruments have been validated for middle-aged and older adults. An online survey was used to perform a validation of the Body Image Quality of Life Inventory (BIQLI) and examine demographic relationships, with a sample of 947 women, ages 40-79, from across the United States. A principal component analysis (PCA) and convergent validity supported the use of the BIQLI for women ages 40 to 79. A one-factor model was validated for comparing BIQLI scores across decades. A two-factor model provided useful information about potential subscales within the BIQLI for women of certain decades. Two- and three-factor models had different patterns for each decade, making the one-factor model the only solution for comparing across age groups. The strongest demographic relationship existed between total BIQLI score and body mass index, though the relationship weakened as age increased. Income level and relationship status had small associations with BIQLI score only for the women in their 60s. Results indicate that the 60s may be a time of transition for body image and warrants continued research. Race also played a distinct role with Caucasians having lower scores than the sample with all races combined. Combining races may skew findings and lead to incorrect assumptions, especially when Caucasians are included in a sample
Neuroconductor: an R platform for medical imaging analysis
Neuroconductor (https://neuroconductor.org) is an open-source platform for rapid testing and dissemination of reproducible computational imaging software. The goals of the project are to: (i) provide a centralized repository of R software dedicated to image analysis, (ii) disseminate software updates quickly, (iii) train a large, diverse community of scientists using detailed tutorials and short courses, (iv) increase software quality via automatic and manual quality controls, and (v) promote reproducibility of image data analysis. Based on the programming language R (https://www.r-project.org/), Neuroconductor starts with 51 inter-operable packages that cover multiple areas of imaging including visualization, data processing and storage, and statistical inference. Neuroconductor accepts new R package submissions, which are subject to a formal review and continuous automated testing. We provide a description of the purpose of Neuroconductor and the user and developer experience
A novel recruiting and surveying method: Participatory research during a Pacific Islander community’s traditional cultural event
Little is known about the health status of Marshallese, a Pacific Islander subpopulation living in the United States. The Marshallese have established a growing community in Northwest Arkansas, providing a unique opportunity for increasing knowledge regarding the health of this minority group. This article describes how a community-based participatory research process was used by a community and university coalition to identify and refine questionnaires and recruit study participants. Questionnaires were self-administered on computers during a one-week traditional cultural event. A total of 874 Marshallese from Arkansas completed the questionnaire, exceeding the goal of 600 respondents. Lessons learned, including the level and timing of involvement of both the leadership and the community at large, are discussed in detail. This approach enhanced communication and collaboration between the Marshallese community, service providers and researchers, resulting in higher participation and interest among the Marshallese community.Keywords: participatory research, minority populations, community health assessment, community coalition, Marshalles
Multi-start Method with Prior Learning for Image Registration
We propose an efficient image registration strategy that is based on learned prior distributions of transformation parameters. These priors are used to constrain a finite- time multi-start optimization method. Motivation for this approach comes from the fact that standard affine brain image registration methods, especially those based on gradient descent optimization alone, are affected by the initial search position. While global optimization methods can resolve this problem, they are are often very time consuming. Our goal is to build an explicit prior model of the gap between a typical registration solution and the solution gained by a global optimization method. We use this learned prior model to restrict randomized search in the relevant parameter space surrounding the initial solution. Global optimization in this restricted parameter space provides, in finite time, results that are superior to both gradient descent and the general multi-start strategy. The performance of our method is illustrated on a data set of 67 elderly and neurodegenerative brains. Our novel learning strategy and the associated registration method are shown to outperform other approaches. Theoretical, synthetic and real-world examples illustrate this improvement
Fiber Orientation Estimation Guided by a Deep Network
Diffusion magnetic resonance imaging (dMRI) is currently the only tool for
noninvasively imaging the brain's white matter tracts. The fiber orientation
(FO) is a key feature computed from dMRI for fiber tract reconstruction.
Because the number of FOs in a voxel is usually small, dictionary-based sparse
reconstruction has been used to estimate FOs with a relatively small number of
diffusion gradients. However, accurate FO estimation in regions with complex FO
configurations in the presence of noise can still be challenging. In this work
we explore the use of a deep network for FO estimation in a dictionary-based
framework and propose an algorithm named Fiber Orientation Reconstruction
guided by a Deep Network (FORDN). FORDN consists of two steps. First, we use a
smaller dictionary encoding coarse basis FOs to represent the diffusion
signals. To estimate the mixture fractions of the dictionary atoms (and thus
coarse FOs), a deep network is designed specifically for solving the sparse
reconstruction problem. Here, the smaller dictionary is used to reduce the
computational cost of training. Second, the coarse FOs inform the final FO
estimation, where a larger dictionary encoding dense basis FOs is used and a
weighted l1-norm regularized least squares problem is solved to encourage FOs
that are consistent with the network output. FORDN was evaluated and compared
with state-of-the-art algorithms that estimate FOs using sparse reconstruction
on simulated and real dMRI data, and the results demonstrate the benefit of
using a deep network for FO estimation.Comment: A shorter version is accepted by MICCAI 201
Anatomically Constrained Video-CT Registration via the V-IMLOP Algorithm
Functional endoscopic sinus surgery (FESS) is a surgical procedure used to
treat acute cases of sinusitis and other sinus diseases. FESS is fast becoming
the preferred choice of treatment due to its minimally invasive nature.
However, due to the limited field of view of the endoscope, surgeons rely on
navigation systems to guide them within the nasal cavity. State of the art
navigation systems report registration accuracy of over 1mm, which is large
compared to the size of the nasal airways. We present an anatomically
constrained video-CT registration algorithm that incorporates multiple video
features. Our algorithm is robust in the presence of outliers. We also test our
algorithm on simulated and in-vivo data, and test its accuracy against
degrading initializations.Comment: 8 pages, 4 figures, MICCA
Multivariate MR Biomarkers Better Predict Cognitive Dysfunction in Mouse Models of Alzheimers Disease
To understand multifactorial conditions such as Alzheimers disease (AD) we
need brain signatures that predict the impact of multiple pathologies and their
interactions. To help uncover the relationships between brain circuits and
cognitive markers we have used mouse models that represent, at least in part,
the complex interactions altered in AD. In particular, we aimed to understand
the relationship between vulnerable brain circuits and memory deficits measured
in the Morris water maze, and we tested several predictive modeling approaches.
We used in vivo manganese enhanced MRI voxel based analyses to reveal regional
differences in volume (morphometry), signal intensity (activity), and magnetic
susceptibility (iron deposition, demyelination). These regions included the
hippocampus, olfactory areas, entorhinal cortex and cerebellum. The image based
properties of these regions were used to predict spatial memory. We next used
eigenanatomy, which reduces dimensionality to produce sets of regions that
explain the variance in the data. For each imaging marker, eigenanatomy
revealed networks underpinning a range of cognitive functions including memory,
motor function, and associative learning. Finally, the integration of
multivariate markers in a supervised sparse canonical correlation approach
outperformed single predictor models and had significant correlates to spatial
memory. Among a priori selected regions, the fornix also provided good
predictors, raising the possibility of investigating how disease propagation
within brain networks leads to cognitive deterioration. Our results support
that modeling approaches integrating multivariate imaging markers provide
sensitive predictors of AD-like behaviors. Such strategies for mapping brain
circuits responsible for behaviors may help in the future predict disease
progression, or response to interventions.Comment: 23 pages, 3 Tables, 6 Figures; submitted for publicatio
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