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Non-Invasive Ultrasound Assessment of Endometrial Cancer Progression in Pax8-Directed Deletion of the Tumor Suppressors Arid1a and Pten in Mice

作者： Rachel Vistein1, Briana Winer2, Stephanie Myers1,3, Juliane Liberto4, Shun Ishiyama1,5,6, Xin Guo1, Harumi Saeki7, Tian-Li Wang4,8, Ie-Ming Shih2,4,8, Kathleen Gabrielson1,4,8 1Department of Molecular and Comparative Pathobiology,Johns Hopkins University School of Medicine, 2Department of Obstetrics and Gynecology,Johns Hopkins University School of Medicine, 3Texas Tech University School of Veterinary Medicine, 4Department of Pathology,Johns Hopkins University School of Medicine, 5Department of Surgery,Johns Hopkins University School of Medicine, 6Department of Coloproctological Surgery,Juntendo University School of Medicine, 7Department of Human Pathology,Juntendo University School of Medicine, 8Sidney Kimmel Comprehensive Cancer Center,Johns Hopkins University

简介：

Overview

This study demonstrates that manual guided ultrasound is effective for monitoring uterine pathology in an induced mouse model of endometrial cancer. The noninvasive nature of ultrasound imaging allows for longitudinal studies, capturing individual variation while reducing the number of animals needed for research.

Key Study Components

Area of Science

Neuroscience
Oncology
Imaging Techniques

Background

Endometrial cancer is a significant health concern.
Monitoring morphological changes in the uterus is crucial for understanding disease progression.
Ultrasound imaging offers a noninvasive approach for such monitoring.
This method can be applied to various models of pathology.

Purpose of Study

To develop a method for tracking morphological changes in the uterus.
To utilize ultrasound for longitudinal studies in a mouse model.
To reduce the number of animals required for research by capturing individual variations.

Methods Used

Setup of ultrasound machine with appropriate transducer range.
Selection of Mouse Small Abdomen Mode for imaging.
Monitoring of uterine pathology over time.
Correlation of ultrasound findings with gross and histological changes.

Main Results

Ultrasound imaging effectively captured the progression of uterine pathology.
Individual variations in disease progression were observed.
The method proved to be noninvasive and suitable for longitudinal studies.
Potential applications extend to other models of neoplasia and chronic diseases.

Conclusions

Manual guided ultrasound is a valuable tool for monitoring endometrial cancer.
This approach can enhance research efficiency and animal welfare.
Further studies may expand its application to other pathological models.

Frequently Asked Questions

What is the main advantage of using ultrasound in this study?

The main advantage is its noninvasive nature, allowing for longitudinal studies without harming the animals.

How does this method reduce the number of animals needed for research?

By capturing individual variations over time, fewer animals are required to achieve statistically significant results.

Can this ultrasound method be applied to other diseases?

Yes, it can be applied to monitor pathologic changes in other models, including those for neoplasia and chronic diseases.

What frequency range is recommended for the ultrasound transducer?

A transducer range of 32 to 56 megahertz is recommended for imaging the uterus or ovary.

What are the implications of this study for future research?

The study suggests that ultrasound can enhance the monitoring of disease progression, potentially improving research outcomes and animal welfare.

Is the ultrasound method suitable for other imaging applications?

Yes, it can be readily applied to various imaging applications in different biological models.

This protocol describes a method for monitoring the progression of morphological changes over time in the uterus in an inducible mouse model of endometrial cancer using ultrasound imaging with correlation to gross and histological changes.

标签: Non-invasive Ultrasound, Endometrial Cancer, Tumor Suppressors, Arid1a, Pten, Mouse Model, Ultrasound Imaging, Uterine Pathology, Longitudinal Studies, Neoplasia, Chronic Disease, Imaging Protocol, Transducer Selection, B Mode, Image Refinement, Peritoneal Injection, Anesthetized Mouse, Ultrasound Gel,