Your search keyword '"Priester, Alan"' showing total 5 results

1. A System for Co-Registration of High-Resolution Ultrasound, Magnetic Resonance Imaging, and Whole-Mount Pathology for Prostate Cancer

Author

Pensa, Jake, primary, Brisbane, Wayne, additional, Priester, Alan, additional, Sisk, Anthony, additional, Marks, Leonard, additional, and Geoghegan, Rory, additional

Published

2021

2. Interstitial Optical Monitoring of Focal Laser Ablation.

Author

Geoghegan, Rory, Zhang, Le, Priester, Alan, Wu, Holden H., Marks, Leonard, and Natarajan, Shyam

Subjects

LASER ablation, PROSTATE, MONTE Carlo method, MAGNETIC resonance imaging, OPTICAL fiber detectors, DIAGNOSTIC imaging, HIGH-intensity focused ultrasound

Abstract

Focal laser ablation is a minimally invasive method of treating cancerous lesions in organs such as prostate, liver and brain. Oncologic control is achieved by inducing hyperthermia throughout the target while minimizing damage to surrounding tissue. Consequently, successful clinical outcomes are contingent upon achieving desired ablation volumes. Magnetic resonance thermometry is frequently used to monitor the formation of the induced thermal damage zone and inform the decision to terminate energy delivery. However, due to the associated cost and complexity there is growing interest in the development of alternative approaches. Here we investigate the utility of real-time interstitial interrogation of laser-tissue interaction as an inexpensive alternative monitoring modality that provides direct assessment of tissue coagulation without the need for organ specific calibration. The optical contrast mechanism was determined using a Monte Carlo model. Subsequently, four interstitial probe designs were manufactured and assessed in a tissue mimicking phantom under simultaneous magnetic resonance imaging. Finally, the optimal probe design was evaluated in ex vivo bovine muscle. It was found to be capable of providing sufficient feedback to achieve pre-defined ablation radii in the range 4–7 mm with a mean absolute error of 0.3 mm. This approach provides an inexpensive monitoring modality that may facilitate widespread adoption of focal laser ablation. [ABSTRACT FROM AUTHOR]

Published

2022

3. Monitoring Focal Laser Ablation with Interstitial Fluence Probes: Monte Carlo Simulation and Phantom Validation

Author

Geoghegan, Rory, primary, Priester, Alan, additional, Zhang, Le, additional, Wu, Holden, additional, Marks, Leonard, additional, and Natarajan, Shyam, additional

Published

2020

4. Registration Accuracy of Patient-Specific, Three-Dimensional-Printed Prostate Molds for Correlating Pathology With Magnetic Resonance Imaging.

Author

Priester, Alan, Wu, Holden, Khoshnoodi, Pooria, Schneider, Douglas, Zhang, Zhaohuan, Asvadi, Nazanin H., Sisk, Anthony, Raman, Steven, Reiter, Robert, Grundfest, Warren, Marks, Leonard S., and Natarajan, Shyam

Subjects

*MAGNETIC resonance imaging, *PATHOLOGY, *IMAGING phantoms, *PROSTATECTOMY, *MOLDS (Fungi)

Abstract

Objective: This investigation was performed to evaluate the registration accuracy between magnetic resonance imaging (MRI) and pathology using three-dimensional (3-D) printed molds. Methods: Tissue-mimicking prostate phantoms were manufactured with embedded fiducials. The fiducials were used to measure and compare target registration error (TRE) between phantoms that were sliced by hand versus phantoms that were sliced within 3-D-printed molds. Subsequently, ten radical prostatectomy specimens were placed inside molds, scanned with MRI, and then sliced. The ex vivo scan was used to assess the true location of whole mount (WM) slides relative to in vivo MRI. The TRE between WM and in vivo MRI was measured using anatomic landmarks. Results: Manually sliced phantoms had a 4.1-mm mean TRE, whereas mold-sliced phantoms had a 1.9-mm mean TRE. Similarly, mold-assisted slicing reduced mean angular misalignment around the left-right (LR) anatomic axis from 10.7° to 4.5°. However, ex vivo MRI revealed that excised prostates were misaligned within molds, including a mean 14° rotation about the LR axis. The mean in-plane TRE was 3.3 mm using molds alone and 2.2 mm after registration was corrected with ex vivo MRI. Conclusion: Patient-specific molds improved accuracy relative to manual slicing techniques in a phantom model. However, the registration accuracy of surgically resected specimens was limited by their imperfect fit within molds. This limitation can be overcome with the addition of ex vivo imaging. Significance: The accuracy of 3-D-printed molds was characterized, quantifying their utility for facilitating MRI-pathology registration. [ABSTRACT FROM AUTHOR]

Published

2019

5. Robotic ultrasound systems in medicine.

Author

Priester, Alan, Natarajan, Shyam, and Culjat, Martin

Subjects

*ULTRASONIC imaging, *ROBOTICS, *SCHOOLS, *MOTOR ability, *APPLICATION software, *MEDICAL imaging systems

Abstract

Robots ultrasound (RUS) can be defined as the combination of ultrasound imaging with a robotic system in medical interventions. With their potential for high precision, dexterity, and repeatability, robots are often uniquely suited for ultrasound integration. Although the field is relatively young, it has already generated a multitude of robotic systems for application in dozens of medical procedures. This paper reviews the robotic ultrasound systems that have been developed over the past two decades and describes their potential impact on modern medicine. The RUS projects reviewed include extracorporeal devices, needle guidance systems, and intraoperative systems. [ABSTRACT FROM AUTHOR]

Published

2013