24 research outputs found
NISF: Neural Implicit Segmentation Functions
Segmentation of anatomical shapes from medical images has taken an important
role in the automation of clinical measurements. While typical deep-learning
segmentation approaches are performed on discrete voxels, the underlying
objects being analysed exist in a real-valued continuous space. Approaches that
rely on convolutional neural networks (CNNs) are limited to grid-like inputs
and not easily applicable to sparse or partial measurements. We propose a novel
family of image segmentation models that tackle many of CNNs' shortcomings:
Neural Implicit Segmentation Functions (NISF). Our framework takes inspiration
from the field of neural implicit functions where a network learns a mapping
from a real-valued coordinate-space to a shape representation. NISFs have the
ability to segment anatomical shapes in high-dimensional continuous spaces.
Training is not limited to voxelized grids, and covers applications with sparse
and partial data. Interpolation between observations is learnt naturally in the
training procedure and requires no post-processing. Furthermore, NISFs allow
the leveraging of learnt shape priors to make predictions for regions outside
of the original image plane. We go on to show the framework achieves dice
scores of 0.87 0.045 on a (3D+t) short-axis cardiac segmentation task
using the UK Biobank dataset. We also provide a qualitative analysis on our
frameworks ability to perform segmentation and image interpolation on unseen
regions of an image volume at arbitrary resolutions
Global k-Space Interpolation for Dynamic MRI Reconstruction using Masked Image Modeling
In dynamic Magnetic Resonance Imaging (MRI), k-space is typically
undersampled due to limited scan time, resulting in aliasing artifacts in the
image domain. Hence, dynamic MR reconstruction requires not only modeling
spatial frequency components in the x and y directions of k-space but also
considering temporal redundancy. Most previous works rely on image-domain
regularizers (priors) to conduct MR reconstruction. In contrast, we focus on
interpolating the undersampled k-space before obtaining images with Fourier
transform. In this work, we connect masked image modeling with k-space
interpolation and propose a novel Transformer-based k-space Global
Interpolation Network, termed k-GIN. Our k-GIN learns global dependencies among
low- and high-frequency components of 2D+t k-space and uses it to interpolate
unsampled data. Further, we propose a novel k-space Iterative Refinement Module
(k-IRM) to enhance the high-frequency components learning. We evaluate our
approach on 92 in-house 2D+t cardiac MR subjects and compare it to MR
reconstruction methods with image-domain regularizers. Experiments show that
our proposed k-space interpolation method quantitatively and qualitatively
outperforms baseline methods. Importantly, the proposed approach achieves
substantially higher robustness and generalizability in cases of
highly-undersampled MR data
Relationformer: A Unified Framework for Image-to-Graph Generation
A comprehensive representation of an image requires understanding objects and their mutual relationship, especially in image-to-graph generation, e.g., road network extraction, blood-vessel network extraction, or scene graph generation. Traditionally, image-to-graph generation is addressed with a two-stage approach consisting of object detection followed by a separate relation prediction, which prevents simultaneous object-relation interaction. This work proposes a unified one-stage transformer-based framework, namely Relationformer, that jointly predicts objects and their relations. We leverage direct set-based object prediction and incorporate the interaction among the objects to learn an object-relation representation jointly. In addition to existing [obj]-tokens, we propose a novel learnable token, namely [rln]-token. Together with [obj]-tokens, [rln]-token exploits local and global semantic reasoning in an image through a series of mutual associations. In combination with the pair-wise [obj]-token, the [rln]-token contributes to a computationally efficient relation prediction. We achieve state-of-the-art performance on multiple, diverse and multi-domain datasets that demonstrate our approach's effectiveness and generalizability
Multi-contrast MRI Super-resolution via Implicit Neural Representations
Clinical routine and retrospective cohorts commonly include multi-parametric
Magnetic Resonance Imaging; however, they are mostly acquired in different
anisotropic 2D views due to signal-to-noise-ratio and scan-time constraints.
Thus acquired views suffer from poor out-of-plane resolution and affect
downstream volumetric image analysis that typically requires isotropic 3D
scans. Combining different views of multi-contrast scans into high-resolution
isotropic 3D scans is challenging due to the lack of a large training cohort,
which calls for a subject-specific framework.This work proposes a novel
solution to this problem leveraging Implicit Neural Representations (INR). Our
proposed INR jointly learns two different contrasts of complementary views in a
continuous spatial function and benefits from exchanging anatomical information
between them. Trained within minutes on a single commodity GPU, our model
provides realistic super-resolution across different pairs of contrasts in our
experiments with three datasets. Using Mutual Information (MI) as a metric, we
find that our model converges to an optimum MI amongst sequences, achieving
anatomically faithful reconstruction. Code is available at:
https://github.com/jqmcginnis/multi_contrast_inr
Mechanism of Action of Lonicera caerulea Berry Polyphenols in Regulating Intestinal Microecology in Immunosuppressive Mice
Objective: In order to explore the effects of Lonicera caerulea berry polyphenols (LCBP) on immunity and intestinal flora in immunosuppressive mice. Methods: Thirty-two mice were randomly divided into a blank control group, a model group, a low-dose LCBP group and a high-dose LCBP group. Cyclophosphamide at 80 mg/(kg mb路d) was injected intraperitoneally after 17, 19 and 21 d of oral administration. Immune organ indices, routine blood biochemical indexes, intestinal microbial diversity and distribution, and the level of short chain fatty acids in colonic contents were investigated and colonic histopathology was examined by hematoxylin-eosin (HE) staining. Results: Compared with the model group, spleen and thymus indexes in the high-dose LCBP group significantly increased (P < 0.01). Also, the number of white blood cells, lymphocytes and platelets increased (P < 0.05), and so did the number of red blood cells and neutrophils (P < 0.01). LCBP increased the relative abundance of Firmicutes, Epsilonbacteraeota, Proteobacteria, Patescibacteria, Actinobacteria and Cyanobacteria in the intestinal tract of immunosuppressive mice and the concentrations of fecal short-chain fatty acids (SCFAs). Conclusion: LCBP can increase the type of intestinal flora, regulate the structural distribution of intestinal flora, alleviate intestinal injury and enhance immune function in immunosuppressive mice
Effect of solidification modes on the shape memory effect of cast Fe-Mn-Si-Cr-Ni shape memory alloys
We investigated the microstructures and shape memory effect (SME) of cast Fe-Mn-Si-Cr-Ni alloys with four solidification modes, i.e., austenitic, austenitic-ferritic, ferritic-austenitic, and ferritic modes. Ferritic-austenitic and ferritic modes introduced more stacking faults than austenitic and austenitic-ferritic ones, reducing stress-induced critical martensite stress. Thus, the former solidification modes displayed better SME than the latter solidification modes
Neural Implicit k-Space for Binning-free Non-Cartesian Cardiac MR Imaging
In this work, we propose a novel image reconstruction framework that directly
learns a neural implicit representation in k-space for ECG-triggered
non-Cartesian Cardiac Magnetic Resonance Imaging (CMR). While existing methods
bin acquired data from neighboring time points to reconstruct one phase of the
cardiac motion, our framework allows for a continuous, binning-free, and
subject-specific k-space representation.We assign a unique coordinate that
consists of time, coil index, and frequency domain location to each sampled
k-space point. We then learn the subject-specific mapping from these unique
coordinates to k-space intensities using a multi-layer perceptron with
frequency domain regularization. During inference, we obtain a complete k-space
for Cartesian coordinates and an arbitrary temporal resolution. A simple
inverse Fourier transform recovers the image, eliminating the need for density
compensation and costly non-uniform Fourier transforms for non-Cartesian data.
This novel imaging framework was tested on 42 radially sampled datasets from 6
subjects. The proposed method outperforms other techniques qualitatively and
quantitatively using data from four and one heartbeat(s) and 30 cardiac phases.
Our results for one heartbeat reconstruction of 50 cardiac phases show improved
artifact removal and spatio-temporal resolution, leveraging the potential for
real-time CMR
Characteristics of Radio Frequency Dielectric Barrier Discharge Using Argon Doped with Nitrogen at Atmospheric Pressure
In order to study the characteristics of radio frequency dielectric barrier discharge (RF-DBD) using argon doped with nitrogen at atmospheric pressure, electrical and optical diagnoses of the discharge with different nitrogen ratios from 1% to 100% were carried out, and the self-organizing form of the filamentous plasma was studied through a transparent water electrode. At the same time, an ICCD camera was used to study the spatiotemporal evolution filamentous discharge during one cycle. Different from discharge using pure argon, using argon doped with nitrogen made the discharge change from glow discharge to filamentous discharge when the voltage increased to a certain value, and a higher nitrogen ratio made the filaments thicker and more sparsely arranged. Under different input power and nitrogen content conditions, several forms of glow discharge, hexagonal/irregularly arranged filamentous discharge and local filamentous discharge were obtained, all of which have potential applications to reduce the high cost of using inert gases
LAPNet:Non-rigid Registration derived in k-space for Magnetic Resonance Imaging
Physiological motion, such as cardiac and respiratory motion, during Magnetic
Resonance (MR) image acquisition can cause image artifacts. Motion correction
techniques have been proposed to compensate for these types of motion during
thoracic scans, relying on accurate motion estimation from undersampled
motion-resolved reconstruction. A particular interest and challenge lie in the
derivation of reliable non-rigid motion fields from the undersampled
motion-resolved data. Motion estimation is usually formulated in image space
via diffusion, parametric-spline, or optical flow methods. However, image-based
registration can be impaired by remaining aliasing artifacts due to the
undersampled motion-resolved reconstruction. In this work, we describe a
formalism to perform non-rigid registration directly in the sampled Fourier
space, i.e. k-space. We propose a deep-learning based approach to perform fast
and accurate non-rigid registration from the undersampled k-space data. The
basic working principle originates from the Local All-Pass (LAP) technique, a
recently introduced optical flow-based registration. The proposed LAPNet is
compared against traditional and deep learning image-based registrations and
tested on fully-sampled and highly-accelerated (with two undersampling
strategies) 3D respiratory motion-resolved MR images in a cohort of 40 patients
with suspected liver or lung metastases and 25 healthy subjects. The proposed
LAPNet provided consistent and superior performance to image-based approaches
throughout different sampling trajectories and acceleration factors