Magnetic Microbubbles for Targeted Drug Release

We propose to synthesize and characterize magnetic microbubbles for examining the use of magnetic microbubbles for targeted drug delivery. Using magnetic microbubbles as carriers, we will test how well drugs can be dispersed by means of ultrasound and hyperthermia

Development of an Online Course in Research for Undergraduate Students

This Work in Progress paper will cover the development of an online course in research practices for undergraduate students. Active participation in research is an important part of experiential learning, which can help to prepare students for careers in a variety of settings including industrial R&D departments, academia, and government research labs. Undergraduate students’ research experiences may be limited in their value, however, by the learning curve students face as they begin to conduct research. The quality of their training may also be limited, with some receiving excellent training and orientation from a strong research lab or faculty mentor, and others receiving little guidance. In order to better prepare undergraduate students for research, faculty members in different departments at a midwestern STEM-focused University received an internal grant to develop a class in research for undergraduates. This class, which is designed to be offered online either for cohorts or for individual students as an independent study, contains information and resources on a diverse range of issues such as motivation for research, research ethics, planning a research project, conducting literature searches, experimental procedures, keeping lab documentation for various types of projects, data analysis, technical writing, intellectual property, and issues relevant to scoping out one’s own research project. This paper will give the background for the course development, evaluation of the required content and decisions on structure and format, and describe the various modules in the course. It will also describe the future plans for deployment, evaluation, and continuous improvement of the course, and suggest ways in which it could benefit a wide range of undergraduate students in different disciplines

High-Frequency Ultrasound M-Mode Imaging for Identifying Lesion and Bubble Activity During High-Intensity Focused Ultrasound Ablation

Effective real-time monitoring of high-intensity focused ultrasound (HIFU) ablation is important for application of HIFU technology in interventional electrophysiology. This study investigated rapid, high-frequency M-mode ultrasound imaging for monitoring spatiotemporal changes during HIFU application. HIFU (4.33 MHz, 1 kHz PRF, 50% duty cycle, 1 s, 2600 – 6100 W/cm2 ) was applied to ex-vivo porcine cardiac tissue specimens with a confocally and perpendicularly aligned high-frequency imaging system (Visualsonics Vevo 770, 55 MHz center frequency). Radiofrequency (RF) data from M-mode imaging (1 kHz PRF, 2 s × 7 mm) was acquired before, during, and after HIFU treatment (n = 12). Among several strategies, the temporal maximum integrated backscatter with a threshold of +12 dB change showed the best results for identifying final lesion width (receiver-operating characteristic curve area 0.91 ± 0.04, accuracy 85 ± 8%, as compared to macroscopic images of lesions). A criterion based on a line-to-line decorrelation coefficient is proposed for identification of transient gas bodies

Infrared thermography for noninvasive real-time monitoring of HIFU ablation

Infrared imaging for spatiotemporal temperature measurements was explored in this study for non-contact monitoring of temperature increases generated by HIFU ablation. Using ex vivo cardiac tissue specimens, we investigated the correlations between the occurrence of events during HIFU ablation (e.g., lesion formation, cavity formation) and the 2D spatiotemporal temperature of the tissue surface measured during HIFU ablation from an infrared camera. An increase in the rate of temperature rise was observed when lesions formed at or slightly beneath the tissue surface. Spatial shifts in the maximum temperature location away from the HIFU focus were often observed with continuing HIFU exposure after lesion formation, suggesting tissue dehydration and cavitationformation during ablation with excessive heating

Enhancing Cellular Uptake of Magnetic Nanoparticles for Cancer Therapy via Nanoparticle Engineering & Sonoporation

Magnetic induction heating of iron oxide nanoparticles has been proposed as a method for noninvasive cancer treatment without the side effects of chemotherapy and ionizing radiation. At Kettering University we propose to improve the uptake of nanoparticles by cells through the use of nanoparticle engineering and ultrasonic fields

High-frequency ultrasound M-mode monitoring of HIFU ablation in cardiac tissue

Effective real-time HIFU lesion detection is important for expanded use of HIFU in interventional electrophysiology (e.g., epicardial ablation of cardiac arrhythmia). The goal of this study was to investigate rapid, high-frequency M-mode ultrasound imaging for monitoring spatiotemporal changes in tissue during HIFU application. The HIFU application (4.33 MHz, 1000 Hz PRF, 50% duty cycle, 1 s exposure, 6100 W/cm2) was perpendicularly applied to porcine cardiac tissue with a high-frequency imaging system (Visualsonics Vevo 770, 55 MHz, 4.5 mm focal distance) confocally aligned. Radiofrequency (RF) M-mode data (1 kHz PRF, 4 s × 7 mm) was acquired before, during, and after HIFU treatment. Gross lesions were compared with M-mode data to correlate lesion and cavity formation. Integrated backscatter, echo-decorrelation parameters, and their cumulative extrema over time were analyzed for automatically identifying lesion width and bubble formation. Cumulative maximum integrated backscatter showed the best results for identifying the final lesion width, and a criterion based on line-to-line decorrelation was proposed for identification of transient bubble activity

High-Frequency Rapid B-Mode Ultrasound Imaging for Real-Time Monitoring of Lesion Formation and Gas Body Activity During High-Intensity Focused Ultrasound Ablation

Abstract: The goal of this study was to examine the ability of high-frame-rate, high-resolution imaging to monitor tissue necrosis and gas-body activities formed during high-intensity focused ultrasound (HIFU) application. Ex vivo porcine cardiac tissue specimens (n = 24) were treated with HIFU exposure (4.33 MHz, 77 to 130 Hz pulse repetition frequency (PRF), 25 to 50% duty cycle, 0.2 to 1 s, 2600 W/cm2). RF data from Bmode ultrasound imaging were obtained before, during, and after HIFU exposure at a frame rate ranging from 77 to 130 Hz using an ultrasound imaging system with a center frequency of 55 MHz. The time history of changes in the integrated backscatter (IBS), calibrated spectral parameters, and echo-decorrelation parameters of the RF data were assessed for lesion identification by comparison against gross sections. Temporal maximum IBS with +12 dB threshold achieved the best identification with a receiver-operating characteristic (ROC) curve area of 0.96. Frame-to-frame echo decorrelation identified and tracked transient gas-body activities. Macroscopic (millimetersized) cavities formed when the estimated initial expansion rate of gas bodies (rate of expansion in lateral-to-beam direction) crossed 0.8 mm/s. Together, these assessments provide a method for monitoring spatiotemporal evolution of lesion and gas-body activity and for predicting macroscopic cavity formation

A method for measuring the Neel relaxation time in a frozen ferrofluid

We report a novel method of determining the average Neel relaxation time and its temperature dependence by calculating derivatives of the measured time dependence of temperature for a frozen ferrofluid exposed to an alternating magnetic field. The ferrofluid, composed of dextran-coated Fe3O4 nanoparticles (diameter 13.7 nm +/- 4.7 nm), was synthesized via wet chemical precipitation and characterized by x-ray diffraction and transmission electron microscopy. An alternating magnetic field of constant amplitude (H0 = 20 kA/m) driven at frequencies of 171 kHz, 232 kHz and 343 kHz was used to determine the temperature dependent magnetic energy absorption rate in the temperature range from 160 K to 210 K. We found that the specific absorption rate of the ferrofluid decreased monotonically with temperature over this range at the given frequencies. From these measured data, we determined the temperature dependence of the Neel relaxation time and estimate a room-temperature magnetocrystalline anisotropy constant of 40 kJ/m3, in agreement with previously published results