Your search keyword '"Kathryn E. Kirchoff"' showing total 4 results

1. Computer Vision Analysis of Specimen Mammography to Predict Margin Status

Author

Kevin A Chen, Kathryn E Kirchoff, Logan R Butler, Alexa D Holloway, Muneera R Kapadia, Kristalyn K Gallagher, and Shawn M Gomez

Abstract

Intra-operative specimen mammography is a valuable tool in breast cancer surgery, providing immediate assessment of margins for a resected tumor. However, the accuracy of specimen mammography in detecting microscopic margin positivity is low. We sought to develop a deep learning-based model to predict the pathologic margin status of resected breast tumors using specimen mammography. A dataset of specimen mammography images matched with pathology reports describing margin status was collected. Models pre-trained on radiologic images were developed and compared with models pre-trained on non-medical images. Model performance was assessed using sensitivity, specificity, and area under the receiver operating characteristic curve (AUROC). The dataset included 821 images and 53% had positive margins. For three out of four model architectures tested, models pre-trained on radiologic images outperformed domain-agnostic models. The highest performing model, InceptionV3, showed a sensitivity of 84%, a specificity of 42%, and AUROC of 0.71. These results compare favorably with the published literature on surgeon and radiologist interpretation of specimen mammography. With further development, these models could assist clinicians with identifying positive margins intra-operatively and decrease the rate of positive margins and re-operation in breast-conserving surgery.

Published

2023

2. Whole Genome Sequencing and Progress Toward Full Inbreeding of the Mouse Collaborative Cross Population

Author

Martin T. Ferris, Darla R. Miller, Kathryn E. Kirchoff, Colton L. Linnertz, Pablo Hock, Maya L. Najarian, Matthew Blanchard, Anwica Kashfeen, John R. Shorter, Leonard McMillan, Timothy A. Bell, J. Sebastian Sigmon, and Fernando Pardo-Manuel de Villena

Subjects

Collaborative Cross Mice, MPP, Genotype, Population, Multiparent Populations, inbreeding, Mice, Inbred Strains, QH426-470, Biology, Genome, Loss of heterozygosity, Animals, Genetically Modified, 03 medical and health sciences, Mice, 0302 clinical medicine, Gene Frequency, Genetic resources, Multiparental Populations, Genetics, Animals, heterozygosity, Shared data resources, Genetics(clinical), education, Genotyping, Molecular Biology, Genetics (clinical), Alleles, Crosses, Genetic, 030304 developmental biology, Whole genome sequencing, 0303 health sciences, education.field_of_study, Whole Genome Sequencing, Strain (biology), whole genome sequence, Chromosome Mapping, Genetics, Population, GenPred, Genomic Prediction, Inbreeding, 030217 neurology & neurosurgery

Abstract

Two key features of recombinant inbred panels are well-characterized genomes and reproducibility. Here we report on the sequenced genomes of six additional Collaborative Cross (CC) strains and on inbreeding progress of 72 CC strains. We have previously reported on the sequences of 69 CC strains that were publicly available, bringing the total of CC strains with whole genome sequence up to 75. The sequencing of these six CC strains updates the efforts toward inbreeding undertaken by the UNC Systems Genetics Core. The timing reflects our competing mandates to release to the public as many CC strains as possible while achieving an acceptable level of inbreeding. The new six strains have a higher than average founder contribution from non-domesticus strains than the previously released CC strains. Five of the six strains also have high residual heterozygosity (>14%), which may be related to non-domesticus founder contributions. Finally, we report on updated estimates on residual heterozygosity across the entire CC population using a novel, simple and cost effective genotyping platform on three mice from each strain. We observe a reduction in residual heterozygosity across all previously released CC strains. We discuss the optimal use of different genetic resources available for the CC population.

Published

2019

3. EMBER: Multi-label prediction of kinase-substrate phosphorylation events through deep learning

Author

Kathryn E. Kirchoff and Shawn M. Gomez

Subjects

chemistry.chemical_classification, 0303 health sciences, Cell signaling, Kinase, business.industry, Computer science, Deep learning, Cell, Peptide, Computational biology, Cell cycle, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, chemistry, Apoptosis, 030220 oncology & carcinogenesis, medicine, Phosphorylation, Embedding, Kinome, Artificial intelligence, Signal transduction, business, 030304 developmental biology

Abstract

Kinase-catalyzed phosphorylation of proteins forms the back-bone of signal transduction within the cell, enabling the coordination of numerous processes such as the cell cycle, apoptosis, and differentiation. While on the order of 105 phosphorylation events have been described, we know the specific kinase performing these functions for less than 5% of cases. The ability to predict which kinases initiate specific individual phosphorylation events has the potential to greatly enhance the design of downstream experimental studies, while simultaneously creating a preliminary map of the broader phosphorylation network that controls cellular signaling. To this end, we describe EMBER, a deep learning method that integrates kinase-phylogeny information and motif-dissimilarity information into a multi-label classification model for the prediction of kinase-motif phosphorylation events. Unlike previous deep learning methods that perform single-label classification, we restate the task of kinase-motif phosphorylation prediction as a multi-label problem, allowing us to train a single unified model rather than a separate model for each of the 134 kinase families. We utilize a Siamese network to generate novel vector representations, or an embedding, of motif sequences, and we compare our novel embedding to a previously proposed peptide embedding. Our motif vector representations are used, along with one-hot encoded motif sequences, as input to a classification network while also leveraging kinase phylogenetic relationships into our model via a kinase phylogeny-weighted loss function. Results suggest that this approach holds significant promise for improving our map of phosphorylation relations that underlie kinome signaling.Availabilityhttps://github.com/gomezlab/EMBER

Published

2020

4. Cadherin-2 Is Required Cell Autonomously for Collective Migration of Facial Branchiomotor Neurons

Author

Gregory S. Walsh, Kathryn E. Kirchoff, and Jane K. Rebman

Subjects

0301 basic medicine, Embryology, Cell, lcsh:Medicine, Collective migration, Animals, Genetically Modified, Nerve Fibers, Cell Movement, Animal Cells, Medicine and Health Sciences, Promoter Regions, Genetic, lcsh:Science, Zebrafish, Motor Neurons, Neurons, Multidisciplinary, Fishes, Cell Polarity, Brain, Signal transducing adaptor protein, Animal Models, Anatomy, Cadherins, Facial Nerve, Cell Motility, medicine.anatomical_structure, Osteichthyes, Vertebrates, Efferent Neurons, Cellular Types, Research Article, Rhombomere, Hindbrain, Cell Migration, Biology, Research and Analysis Methods, 03 medical and health sciences, Model Organisms, Cell Adhesion, medicine, Animals, Directionality, Neuron Migration, Adaptor Proteins, Signal Transducing, Cadherin, Embryos, lcsh:R, Organisms, Biology and Life Sciences, Cell Biology, Zebrafish Proteins, biology.organism_classification, Axons, Rhombencephalon, 030104 developmental biology, Cellular Neuroscience, lcsh:Q, Neuroscience, Developmental Biology

Abstract

Collective migration depends on cell-cell interactions between neighbors that contribute to their overall directionality, yet the mechanisms that control the coordinated migration of neurons remains to be elucidated. During hindbrain development, facial branchiomotor neurons (FBMNs) undergo a stereotypic tangential caudal migration from their place of birth in rhombomere (r)4 to their final location in r6/7. FBMNs engage in collective cell migration that depends on neuron-to-neuron interactions to facilitate caudal directionality. Here, we demonstrate that Cadherin-2-mediated neuron-to-neuron adhesion is necessary for directional and collective migration of FBMNs. We generated stable transgenic zebrafish expressing dominant-negative Cadherin-2 (Cdh2ΔEC) driven by the islet1 promoter. Cell-autonomous inactivation of Cadherin-2 function led to non-directional migration of FBMNs and a defect in caudal tangential migration. Additionally, mosaic analysis revealed that Cdh2ΔEC-expressing FBMNs are not influenced to migrate caudally by neighboring wild-type FBMNs due to a defect in collective cell migration. Taken together, our data suggest that Cadherin-2 plays an essential cell-autonomous role in mediating the collective migration of FBMNs.

Published

2016