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Implementation of Minimally Invasive Brain Tumor Resection in Rodents for High Viability Tissue Collection

作者： Safwan Alomari1, Jayanidhi Kedda1, Adarsha P. Malla2,3, Victor Pacis1, Pavlos Anastasiadis2,3, Su Xu4, Emylee McFarland2,3, Lilia Sukhon1, Bruno Gallo5, Jordina Rincon-Torroella1, Netanel Ben-Shalom1, Heather M. Ames3,6, Henry Brem1,7, Graeme F. Woodworth2,3, Betty Tyler1 1Department of Neurosurgery,Johns Hopkins University School of Medicine, 2Department of Neurosurgery,University of Maryland School of Medicine, 3Marlene and Stewart Greenebaum Comprehensive Cancer Center,University of Maryland School of Medicine, 4Diagnostic Radiology and Nuclear Medicine,University of Maryland School of Medicine, 5Pontifical Catholic University of Parana, 6Department of Pathology,University of Maryland School of Medicine, 7Departments of Ophthalmology, Oncology and Biomedical Engineering,Johns Hopkins University School of Medicine

简介：

Overview

This protocol outlines a standardized method for resecting brain tumors in rodents using a minimally invasive approach integrated with a tissue preservation system. This technique enhances the accuracy of preclinical research by allowing for the survival of animals post-surgery, facilitating the study of disease progression and therapeutic effects.

Key Study Components

Area of Science

Neuroscience
Preclinical Research
Oncology

Background

Brain tumor research is critical for developing effective therapies.
Standardized surgical techniques improve reproducibility in studies.
Minimally invasive approaches reduce recovery time and complications.
Tissue preservation is essential for subsequent analyses.

Purpose of Study

To establish a reliable method for brain tumor resection in rodent models.
To enable longitudinal studies on tumor biology and treatment responses.
To support drug discovery efforts through improved experimental design.

Methods Used

Minimally invasive surgical techniques for tumor resection.
Automated tissue preservation systems to maintain sample integrity.
Post-operative monitoring to assess animal recovery.
Sequential therapeutic applications to evaluate treatment efficacy.

Main Results

The protocol allows for successful tumor resection with minimal complications.
Animals demonstrate good recovery and can be used for follow-up studies.
Facilitates the assessment of therapeutic interventions over time.
Provides a framework for future research in brain tumor therapeutics.

Conclusions

This technique represents a significant advancement in preclinical brain tumor research.
It enhances the ability to study disease dynamics and treatment outcomes.
Future applications may lead to improved therapeutic strategies for brain tumors.

Frequently Asked Questions

What is the significance of this protocol?

It allows for standardized brain tumor resections in rodents, improving the reliability of preclinical studies.

How does the tissue preservation system work?

The system maintains the integrity of the tissue samples post-surgery, enabling further analysis.

Can this method be applied to other animal models?

Yes, the principles can be adapted for use in various animal models in neuroscience research.

What are the benefits of a minimally invasive approach?

It reduces recovery time and complications, allowing for better animal welfare and study outcomes.

How does this protocol aid in drug discovery?

It enables longitudinal studies that can assess the efficacy of new therapeutics over time.

Is this technique widely used in research?

While it is a novel approach, its standardized nature may encourage broader adoption in the field.

The present protocol describes a standardized resection of brain tumors in rodents through a minimally invasive approach with an integrated tissue preservation system. This technique has implications for accurately mirroring the standard of care in rodent and other animal models.

标签: Minimally Invasive Brain Tumor Resection, Preclinical Research, Animal Surgery, Drug Discovery, Novel Therapeutics, Standardized Resection, Stereotactic Frame, MIRS Machine Setup, Aspiration System, Therapeutic Applications, Disease Biology Examination,