Your search keyword '"Kazerouni, Anum S."' showing total 7 results

1. Multimodal prediction of neoadjuvant treatment outcome by serial FDG PET and MRI in women with locally advanced breast cancer.

Author

Kazerouni, Anum S., Peterson, Lanell M., Jenkins, Isaac, Novakova-Jiresova, Alena, Linden, Hannah M., Gralow, Julie R., Hockenbery, David M., Mankoff, David A., Porter, Peggy L., Partridge, Savannah C., and Specht, Jennifer M.

Subjects

CONTRAST-enhanced magnetic resonance imaging, METASTATIC breast cancer, NEOADJUVANT chemotherapy, TREATMENT effectiveness, MAGNETIC resonance imaging, BREAST cancer

Abstract

Purpose: To investigate combined MRI and 18F-FDG PET for assessing breast tumor metabolism/perfusion mismatch and predicting pathological response and recurrence-free survival (RFS) in women treated for breast cancer. Methods: Patients undergoing neoadjuvant chemotherapy (NAC) for locally-advanced breast cancer were imaged at three timepoints (pre, mid, and post-NAC), prior to surgery. Imaging included diffusion-weighted and dynamic contrast-enhanced (DCE-) MRI and quantitative 18F-FDG PET. Tumor imaging measures included apparent diffusion coefficient, peak percent enhancement (PE), peak signal enhancement ratio (SER), functional tumor volume, and washout volume on MRI and standardized uptake value (SUVmax), glucose delivery (K1) and FDG metabolic rate (MRFDG) on PET, with percentage changes from baseline calculated at mid- and post-NAC. Associations of imaging measures with pathological response (residual cancer burden [RCB] 0/I vs. II/III) and RFS were evaluated. Results: Thirty-five patients with stage II/III invasive breast cancer were enrolled in the prospective study (median age: 43, range: 31–66 years, RCB 0/I: N = 11/35, 31%). Baseline imaging metrics were not significantly associated with pathologic response or RFS (p > 0.05). Greater mid-treatment decreases in peak PE, along with greater post-treatment decreases in several DCE-MRI and 18F-FDG PET measures were associated with RCB 0/I after NAC (p < 0.05). Additionally, greater mid- and post-treatment decreases in DCE-MRI (peak SER, washout volume) and 18F-FDG PET (K1) were predictive of prolonged RFS. Mid-treatment decreases in metabolism/perfusion ratios (MRFDG/peak PE, MRFDG/peak SER) were associated with improved RFS. Conclusion: Mid-treatment changes in both PET and MRI measures were predictive of RCB status and RFS following NAC. Specifically, our results indicate a complementary relationship between DCE-MRI and 18F-FDG PET metrics and potential value of metabolism/perfusion mismatch as a marker of patient outcome. [ABSTRACT FROM AUTHOR]

Published

2023

2. Associations of Multiparametric Breast MRI Features, Tumor-Infiltrating Lymphocytes, and Immune Gene Signature Scores Following a Single Dose of Trastuzumab in HER2-Positive Early-Stage Breast Cancer.

Author

Kennedy, Laura C., Kazerouni, Anum S., Chau, Bonny, Biswas, Debosmita, Alvarez, Rebeca, Durenberger, Grace, Dintzis, Suzanne M., Stanton, Sasha E., Partridge, Savannah C., and Gadi, Vijayakrishna

Subjects

*RNA analysis, *PILOT projects, *TRASTUZUMAB, *ONCOGENES, *MAGNETIC resonance imaging, *TUMOR classification, *PRE-tests & post-tests, *GENE expression profiling, *RESEARCH funding, *T cells, *TUMOR markers, *BREAST tumors, *IMMUNOTHERAPY

Abstract

Simple Summary: Imaging biomarkers that permit non-invasive, real-time monitoring of the tumor microenvironment could serve a critical role to facilitate treatment personalization, particularly in the context of new immunotherapies. The aim of this prospective pilot study was to investigate the value of breast magnetic resonance imaging (MRI) features as early markers of treatment-induced immune response after a single dose of trastuzumab in early HER2+ breast cancer. Our findings showed measures of change in peak percent enhancement on dynamic contrast-enhanced MRI and pre-treatment apparent diffusion coefficient on diffusion-weighted MRI to correlate with immune response as defined by tumor-infiltrating lymphocytes and immune-active gene signature scores. MRI measures hold potential to serve as biomarkers of tumor microenvironment alterations to guide treatment decisions in early breast cancer. Dynamic biomarkers that permit the real-time monitoring of the tumor microenvironment response to therapy are an unmet need in breast cancer. Breast magnetic resonance imaging (MRI) has demonstrated value as a predictor of pathologic complete response and may reflect immune cell changes in the tumor microenvironment. The purpose of this pilot study was to investigate the value of breast MRI features as early markers of treatment-induced immune response. Fourteen patients with early HER2+ breast cancer were enrolled in a window-of-opportunity study where a single dose of trastuzumab was administered and both tissue and MRIs were obtained at the pre- and post-treatment stages. Functional diffusion-weighted and dynamic contrast-enhanced MRI tumor measures were compared with tumor-infiltrating lymphocytes (TILs) and RNA immune signature scores. Both the pre-treatment apparent diffusion coefficient (ADC) and the change in peak percent enhancement (DPE) were associated with increased tumor-infiltrating lymphocytes with trastuzumab therapy (r = −0.67 and -0.69, p < 0.01 and p < 0.01, respectively). Low pre-treatment ADC and a greater decrease in PE in response to treatment were also associated with immune-activated tumor microenvironments as defined by RNA immune signatures. Breast MRI features hold promise as biomarkers of early immune response to treatment in HER2+ breast cancer. [ABSTRACT FROM AUTHOR]

Published

2023

3. Analysis of simplicial complexes to determine when to sample for quantitative DCE MRI of the breast.

Author

DiCarlo, Julie C., Jarrett, Angela M., Kazerouni, Anum S., Virostko, John, Sorace, Anna, Slavkova, Kalina P., Woodard, Stefanie, Avery, Sarah, Patt, Debra, Goodgame, Boone, and Yankeelov, Thomas E.

Subjects

FIX-point estimation, BREAST cancer, CONTRAST media, BREAST exams, MAGNETIC resonance imaging

Abstract

Purpose: A method is presented to select the optimal time points at which to measure DCE‐MRI signal intensities, leaving time in the MR exam for high‐spatial resolution image acquisition. Theory: Simplicial complexes are generated from the Kety‐Tofts model pharmacokinetic parameters Ktrans and ve. A geometric search selects optimal time points for accurate estimation of perfusion parameters. Methods: The DCE‐MRI data acquired in women with invasive breast cancer (N = 27) were used to retrospectively compare parameter maps fit to full and subsampled time courses. Simplicial complexes were generated for a fixed range of Kety‐Tofts model parameters and for the parameter ranges weighted by estimates from the fully sampled data. The largest‐area manifolds determined the optimal three time points for each case. Simulations were performed along with retrospectively subsampled data fits. The agreement was computed between the model parameters fit to three points and those fit to all points. Results: The optimal three‐point sample times were from the data‐informed simplicial complex analysis and determined to be 65, 204, and 393 s after arrival of the contrast agent to breast tissue. In the patient data, tumor‐median parameter values fit using all points and the three selected time points agreed with concordance correlation coefficients of 0.97 for Ktrans and 0.67 for ve. Conclusion: It is possible to accurately estimate pharmacokinetic parameters from three properly selected time points inserted into a clinical DCE‐MRI breast exam. This technique can provide guidance on when to capture images for quantitative data between high‐spatial‐resolution DCE‐MRI images. [ABSTRACT FROM AUTHOR]

Published

2023

4. Longitudinal FRET Imaging of Glucose and Lactate Dynamics and Response to Therapy in Breast Cancer Cells.

Author

Yang, Jianchen, Davis, Tessa, Kazerouni, Anum S., Chen, Yuan-I., Bloom, Meghan J., Yeh, Hsin-Chih, Yankeelov, Thomas E., and Virostko, John

Subjects

GLUCOSE, BREAST cancer, TREATMENT effectiveness, INTRACELLULAR tracking, LACTATES, CANCER cells, CANCER treatment, MONOCARBOXYLATE transporters, GLUCOSE metabolism, ANALYSIS of variance, MICROSCOPY, DIAGNOSTIC imaging, T-test (Statistics), DESCRIPTIVE statistics, CELL lines, STATISTICAL correlation, DATA analysis software, BREAST tumors, HYPOXEMIA, LIGANDS (Biochemistry)

Abstract

Purpose: The reprogramming of cellular metabolism is a hallmark of cancer. The ability to noninvasively assay glucose and lactate concentrations in cancer cells would improve our understanding of the dynamic changes in metabolic activity accompanying tumor initiation, progression, and response to therapy. Unfortunately, common approaches for measuring these nutrient levels are invasive or interrupt cell growth. This study transfected FRET reporters quantifying glucose and lactate concentration into breast cancer cell lines to study nutrient dynamics and response to therapy. Procedures: Two FRET reporters, one assaying glucose concentration and one assaying lactate concentration, were stably transfected into the MDA-MB-231 breast cancer cell line. Correlation between FRET measurements and ligand concentration were measured using a confocal microscope and a cell imaging plate reader. Longitudinal changes in glucose and lactate concentration were measured in response to treatment with CoCl2, cytochalasin B, and phloretin which, respectively, induce hypoxia, block glucose uptake, and block glucose and lactate transport. Results: The FRET ratio from the glucose and lactate reporters increased with increasing concentration of the corresponding ligand (p < 0.005 and p < 0.05, respectively). The FRET ratio from both reporters was found to decrease over time for high initial concentrations of the ligand (p < 0.01). Significant differences in the FRET ratio corresponding to metabolic inhibition were found when cells were treated with glucose/lactate transporter inhibitors. Conclusions: FRET reporters can track intracellular glucose and lactate dynamics in cancer cells, providing insight into tumor metabolism and response to therapy over time. [ABSTRACT FROM AUTHOR]

Published

2022

5. Characterizing Errors in Pharmacokinetic Parameters from Analyzing Quantitative Abbreviated DCE-MRI Data in Breast Cancer.

Author

Slavkova, Kalina P., DiCarlo, Julie C., Kazerouni, Anum S., Virostko, John, Sorace, Anna G., Patt, Debra, Goodgame, Boone, and Yankeelov, Thomas E.

Subjects

BREAST cancer, PHARMACOKINETICS, MAGNETIC resonance mammography, SIMULATION methods & models, DATA analysis

Abstract

This study characterizes the error that results when performing quantitative analysis of abbreviated dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI) data of the breast with the Standard Kety-Tofts (SKT) model and its Patlak variant. More specifically, we used simulations and patient data to determine the accuracy with which abbreviated time course data could reproduce the pharmacokinetic parameters, Ktrans (volume transfer constant) and ve (extravascular/extracellular volume fraction), when compared to the full time course data. SKT analysis of simulated abbreviated time courses (ATCs) based on the imaging parameters from two available datasets (collected with a 3T MRI scanner) at a temporal resolution of 15 s (N = 15) and 7.23 s (N = 15) found a concordance correlation coefficient (CCC) greater than 0.80 for ATCs of length 3.0 and 2.5 min, respectively, for the Ktrans parameter. Analysis of the experimental data found that at least 90% of patients met this CCC cut-off of 0.80 for the ATCs of the aforementioned lengths. Patlak analysis of experimental data found that 80% of patients from the 15 s resolution dataset and 90% of patients from the 7.27 s resolution dataset met the 0.80 CCC cut-off for ATC lengths of 1.25 and 1.09 min, respectively. This study provides evidence for both the feasibility and potential utility of performing a quantitative analysis of abbreviated breast DCE-MRI in conjunction with acquisition of current standard-of-care high resolution scans without significant loss of information in the community setting. [ABSTRACT FROM AUTHOR]

Published

2021

6. Correction to: Longitudinal FRET Imaging of Glucose and Lactate Dynamics and Response to Therapy in Breast Cancer Cells.

Author

Yang, Jianchen, Davis, Tessa, Kazerouni, Anum S., Chen, Yuan-I., Bloom, Meghan J., Yeh, Hsin-Chih, Yankeelov, Thomas E., and Virostko, John

Subjects

BREAST cancer, TREATMENT effectiveness, CANCER cells, CANCER treatment, GLUCOSE, LACTATES, CELL lines

Abstract

Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. The online version of the original article can be found at https://doi.org/10.1007/s11307-021-01639-4 B Correction to: Mol Imaging Biol b https://doi.org/10.1007/s11307-021-01639-4 This article was updated to correct the Funding information. [Extracted from the article]

Published

2022

7. Evaluating patient-specific neoadjuvant regimens for breast cancer via a mathematical model constrained by quantitative magnetic resonance imaging data.

Author

Jarrett, Angela M., Hormuth II, David A., Wu, Chengyue, Kazerouni, Anum S., Ekrut, David A., Virostko, John, Sorace, Anna G., DiCarlo, Julie C., Kowalski, Jeanne, Patt, Debra, Goodgame, Boone, Avery, Sarah, and Yankeelov, Thomas E.

Subjects

*CONTRAST-enhanced magnetic resonance imaging, *BREAST cancer, *EXPERIMENTAL design, *MATHEMATICAL models, *ACQUISITION of data

Abstract

The ability to accurately predict response and then rigorously optimize a therapeutic regimen on a patient-specific basis, would transform oncology. Toward this end, we have developed an experimental-mathematical framework that integrates quantitative magnetic resonance imaging (MRI) data into a biophysical model to predict patient-specific treatment response of locally advanced breast cancer to neoadjuvant therapy. Diffusion-weighted and dynamic contrast-enhanced MRI data is collected prior to therapy, after 1 cycle of therapy, and at the completion of the first therapeutic regimen. The model is initialized and calibrated with the first 2 patient-specific MRI data sets to predict response at the third, which is then compared to patient outcomes (N = 18). The model's predictions for total cellularity, total volume, and the longest axis at the completion of the regimen are significant within expected measurement precision (P < 0.05) and strongly correlated with measured response (P < 0.01). Further, we use the model to investigate, in silico , a range of (practical) alternative treatment plans to achieve the greatest possible tumor control for each individual in a subgroup of patients (N = 13). The model identifies alternative dosing strategies predicted to achieve greater tumor control compared to the standard of care for 12 of 13 patients (P < 0.01). In summary, a predictive, mechanism-based mathematical model has demonstrated the ability to identify alternative treatment regimens that are forecasted to outperform the therapeutic regimens the patients clinically. This has important implications for clinical trial design with the opportunity to alter oncology care in the future. [ABSTRACT FROM AUTHOR]

Published

2020