Your search keyword '"Servati, Mahsa"' showing total 12 results

1. Mapping Whole Exome Sequencing to In Vivo Imaging with Stereotactic Localization and Deep Learning

Author

Servati, Mahsa, Vaccaro, Courtney N., Diller, Emily E., Da Silva, Renata Pellegrino, Mafra, Fernanda, Cao, Sha, Stanley, Katherine B., Cohen-Gadol, Aaron, and Parker, Jason G.

Subjects

Physics - Medical Physics, Quantitative Biology - Quantitative Methods

Abstract

This study presents a multi-faceted approach combining stereotactic biopsy with standard clinical open-craniotomy for sample collection, voxel-wise analysis of MR images, regression-based Generalized Additive Models (GAM), & whole-exome sequencing. This work aims to demonstrate the potential of machine learning algorithms to predict variations in cellular & molecular tumor characteristics. This retrospective study enrolled ten treatment-naive patients with radiologically confirmed glioma (5 WHO grade II, 5 WHO grade IV). Each patient underwent a multiparametric MR scan (T1W, T1W-CE, T2W, T2W-FLAIR, DWI) prior to surgery (27.9+/-34.0 days). During standard craniotomy procedure, at least 1 stereotactic biopsy was collected from each patient, with screenshots of the sample locations saved for spatial registration to pre-surgical MR data. Whole-exome sequencing was performed on flash-frozen tumor samples, prioritizing the signatures of five glioma-related genes: IDH1, TP53, EGFR, PIK3CA, & NF1. Regression was implemented with a GAM using a univariate shape function for each predictor. Standard receiver operating characteristic analyses were used to evaluate detection, with AUC (area under curve) calculated for each gene target & MR contrast combination. The mean AUC for the five gene targets & 31 MR contrast combinations was 0.75+/-0.11; individual AUCs were as high as 0.96 for both IDH1 & TP53 with T2W-FLAIR & ADC & 0.99 for EGFR with T2W & ADC. An average AUC of 0.85 across the five mutations was achieved using the combination of T1W, T2W-FLAIR, & ADC. These results suggest the possibility of predicting exome-wide mutation events from non-invasive, in vivo imaging by combining stereotactic localization of glioma samples & a semi-parametric deep learning method. This approach holds potential for refining targeted therapy by better addressing the genomic heterogeneity of glioma tumors., Comment: Keywords: multiparametric MRI, intra-tumoral heterogeneity, machine learning, brain tumor, stereotactic biopsy. Note: A portion of this study was presented as a talk in RSNA (Radiological Society of North America) 2021 and was awarded the RSNA Chynn Award for Neuroradiology Research

Published

2024

2. In Vivo Renal Lipid Quantification by Accelerated Magnetic Resonance Spectroscopic Imaging at 3T: Feasibility and Reliability Study

Author

Alhulail, Ahmad A, Servati, Mahsa, Ooms, Nathan, Akin, Oguz, Dincer, Alp, Thomas, M Albert, Dydak, Ulrike, and Emir, Uzay E

Subjects

Analytical Chemistry, Biomedical and Clinical Sciences, Chemical Sciences, Biomedical Imaging, Clinical Research, kidney, renal, lipid, fast MRSI, Biochemistry and Cell Biology, Clinical Sciences, Biochemistry and cell biology, Medical biochemistry and metabolomics, Analytical chemistry

Abstract

A reliable and practical renal-lipid quantification and imaging method is needed. Here, the feasibility of an accelerated MRSI method to map renal fat fractions (FF) at 3T and its repeatability were investigated. A 2D density-weighted concentric-ring-trajectory MRSI was used for accelerating the acquisition of 48 × 48 voxels (each of 0.25 mL spatial resolution) without respiratory navigation implementations. The data were collected over 512 complex-FID timepoints with a 1250 Hz spectral bandwidth. The MRSI sequence was designed with a metabolite-cycling technique for lipid-water separation. The in vivo repeatability performance of the sequence was assessed by conducting a test-reposition-retest study within healthy subjects. The coefficient of variation (CV) in the estimated FF from the test-retest measurements showed a high degree of repeatability of MRSI-FF (CV = 4.3 ± 2.5%). Additionally, the matching level of the spectral signature within the same anatomical region was also investigated, and their intrasubject repeatability was also high, with a small standard deviation (8.1 ± 6.4%). The MRSI acquisition duration was ~3 min only. The proposed MRSI technique can be a reliable technique to quantify and map renal metabolites within a clinically acceptable scan time at 3T that supports the future application of this technique for the non-invasive characterization of heterogeneous renal diseases and tumors.

Published

2022

3. Metabolic Insight into Glioma Heterogeneity: Mapping Whole Exome Sequencing to In Vivo Imaging with Stereotactic Localization and Deep Learning.

Author

Servati, Mahsa, Vaccaro, Courtney N., Diller, Emily E., Pellegrino Da Silva, Renata, Mafra, Fernanda, Cao, Sha, Stanley, Katherine B., Cohen-Gadol, Aaron A., and Parker, Jason G.

Subjects

DEEP learning, GLIOMAS, MACHINE learning, RECEIVER operating characteristic curves, HETEROGENEITY, MULTISPECTRAL imaging, NANOMEDICINE

Abstract

Intratumoral heterogeneity (ITH) complicates the diagnosis and treatment of glioma, partly due to the diverse metabolic profiles driven by underlying genomic alterations. While multiparametric imaging enhances the characterization of ITH by capturing both spatial and functional variations, it falls short in directly assessing the metabolic activities that underpin these phenotypic differences. This gap stems from the challenge of integrating easily accessible, colocated pathology and detailed genomic data with metabolic insights. This study presents a multifaceted approach combining stereotactic biopsy with standard clinical open-craniotomy for sample collection, voxel-wise analysis of MR images, regression-based GAM, and whole-exome sequencing. This work aims to demonstrate the potential of machine learning algorithms to predict variations in cellular and molecular tumor characteristics. This retrospective study enrolled ten treatment-naïve patients with radiologically confirmed glioma. Each patient underwent a multiparametric MR scan (T1W, T1W-CE, T2W, T2W-FLAIR, DWI) prior to surgery. During standard craniotomy, at least 1 stereotactic biopsy was collected from each patient, with screenshots of the sample locations saved for spatial registration to pre-surgical MR data. Whole-exome sequencing was performed on flash-frozen tumor samples, prioritizing the signatures of five glioma-related genes: IDH1, TP53, EGFR, PIK3CA, and NF1. Regression was implemented with a GAM using a univariate shape function for each predictor. Standard receiver operating characteristic (ROC) analyses were used to evaluate detection, with AUC (area under curve) calculated for each gene target and MR contrast combination. Mean AUC for five gene targets and 31 MR contrast combinations was 0.75 ± 0.11; individual AUCs were as high as 0.96 for both IDH1 and TP53 with T2W-FLAIR and ADC, and 0.99 for EGFR with T2W and ADC. These results suggest the possibility of predicting exome-wide mutation events from noninvasive, in vivo imaging by combining stereotactic localization of glioma samples and a semi-parametric deep learning method. The genomic alterations identified, particularly in IDH1, TP53, EGFR, PIK3CA, and NF1, are known to play pivotal roles in metabolic pathways driving glioma heterogeneity. Our methodology, therefore, indirectly sheds light on the metabolic landscape of glioma through the lens of these critical genomic markers, suggesting a complex interplay between tumor genomics and metabolism. This approach holds potential for refining targeted therapy by better addressing the genomic heterogeneity of glioma tumors. [ABSTRACT FROM AUTHOR]

Published

2024

4. Targeting intra‐tumoral heterogeneity of human brain tumors with in vivo imaging: A roadmap for imaging genomics from multiparametric MR signals

Author

Parker, Jason G., primary, Servati, Mahsa, additional, Diller, Emily E., additional, Cao, Sha, additional, Ho, Chang, additional, Lober, Robert, additional, and Cohen‐Gadol, Aaron, additional

Published

2022

5. Targeting intra-tumoral heterogeneity of human brain tumors with in vivo imaging: A roadmap for imaging genomics from multiparametric MR signals.

Author

Parker, Jason G., Servati, Mahsa, Diller, Emily E., Sha Cao, Chang Ho, Lober, Robert, and Cohen-Gadol, Aaron

Subjects

*BRAIN tumors, *DEEP learning, *GENOMICS, *CANCER stem cells, *COMPUTATIONAL neuroscience, *HETEROGENEITY, *GENE mapping

Abstract

Resistance of high grade tumors to treatment involves cancer stem cell features, deregulated cell division, acceleration of genomic errors, and emergence of cellular variants that rely upon diverse signaling pathways. This heterogeneous tumor landscape limits the utility of the focal sampling provided by invasive biopsy when designing strategies for targeted therapies. In this roadmap review paper, we propose and develop methods for enabling mapping of cellular and molecular features in vivo to inform and optimize cancer treatment strategies in the brain. This approach leverages (1) the spatial and temporal advantages of in vivo imaging compared with surgical biopsy, (2) the rapid expansion of meaningful anatomical and functional magnetic resonance signals, (3) widespread access to cellular and molecular information enabled by next-generation sequencing, and (4) the enhanced accuracy and computational efficiency of deep learning techniques. As multiple cellular variants may be present within volumes below the resolution of imaging, we describe a mapping process to decode micro- and even nano-scale properties from the macro-scale data by simultaneously utilizing complimentary multiparametric image signals acquired in routine clinical practice. We outline design protocols for future research efforts that marry revolutionary bioinformation technologies, growing access to increased computational capability, and powerful statistical classification techniques to guide rational treatment selection. [ABSTRACT FROM AUTHOR]

Published

2023

6. In Vivo Renal Lipid Quantification by Accelerated Magnetic Resonance Spectroscopic Imaging at 3 T: Feasibility and Reliability Study

Author

Alhulail, Ahmad A., primary, Servati, Mahsa, additional, Ooms, Nathan, additional, Akin, Oguz, additional, Dincer, Alp, additional, Thomas, M. Albert, additional, Dydak, Ulrike, additional, and Emir, Uzay E., additional

Published

2022

7. The Role of Interface Vibrational Modes in Thermal Boundary Resistance

Author

Stanley, Christopher M., primary, Rader, Benjamin K., additional, Laster, Braxton H. D., additional, Servati, Mahsa, additional, and Estreicher, Stefan K., additional

Published

2021

8. Mechanical feedback and robustness of apical constrictions in Drosophila embryo ventral furrow formation

Author

Holcomb, Michael C., primary, Gao, Guo-Jie Jason, additional, Servati, Mahsa, additional, Schneider, Dylan, additional, McNeely, Presley K., additional, Thomas, Jeffrey H., additional, and Blawzdziewicz, Jerzy, additional

Published

2021

9. Mechanical feedback and robustness of apical constrictions in Drosophila embryo ventral furrow formation

Author

Holcomb Michael C., Gao Guo-Jie Jason, Servati Mahsa, Schneider Dylan, McNeely Presley K., Thomas Jeffrey H., Blawzdziewicz Jerzy, Holcomb Michael C., Gao Guo-Jie Jason, Servati Mahsa, Schneider Dylan, McNeely Presley K., Thomas Jeffrey H., and Blawzdziewicz Jerzy

Abstract

publisher

Published

2021

10. Mechanical feedback and robustness of apical constrictions in Drosophila embryo ventral furrow formation

Author

Holcomb, Michael C., Gao, Guo-Jie Jason, Servati, Mahsa, Schneider, Dylan, McNeely, Presley K., Thomas, Jeffrey H., Blawzdziewicz, Jerzy, Holcomb, Michael C., Gao, Guo-Jie Jason, Servati, Mahsa, Schneider, Dylan, McNeely, Presley K., Thomas, Jeffrey H., and Blawzdziewicz, Jerzy

Published

2021

11. Imaging Drosophila embryo gastrulation to identify stress fields and biomechanical feedback

Author

Servati, Mahsa, Thomas, Jeffery H., Sanati, Mahdi, and Blawzdziewicz, Jerzy

Subjects

Drosophila, Confocal imaging, Soft condensed matter, Apical constriction

Abstract

Several potential mechanisms of mechanical coordination of the constriction of the cell apices in groups of cells have been proposed. Our previous computational studies have shown a connection between tensile mechanical feedback and Cellular Constriction Chains (CCCs) that propagate during the first phase of Ventral Furrow Formation (VFF) in the Drosophila melanogaster embryo. Detailed imaging of the underside of the embryo allows us to analyze how morphological aspects of cell clusters change over time. We have used confocal microscopy to take high-resolution time-lapsed images of living Spider GFP embryos, mutants that have Green Fluorescence Protein (GFP) embedded in their cell membranes. Monitoring the progression of individual cell shapes through image analysis, we have explored nature of mechanical coordination responsible and established a method for evaluating the underlying cause of cellular group formations.

Published

2018

12. Mechanical feedback and robustness of apical constrictions inDrosophilaembryo ventral furrow formation

Author

Holcomb, Michael C., primary, Gao, Guo-Jie Jason, additional, Servati, Mahsa, additional, Schneider, Dylan, additional, McNeely, Presley K., additional, Thomas, Jeffrey H., additional, and Blawzdziewicz, Jerzy, additional

Published

2019