Your search keyword '"Simon, Julianna C."' showing total 10 results

1. Dynamics of crevice microbubbles that cause the twinkling artifact

Author

Rokni, Eric, Kitur, Eusila C., and Simon, Julianna C.

Published

2024

2. Histotripsy Bubble Dynamics in Elastic, Anisotropic Tissue-Mimicking Phantoms.

Author

Elliott, Jake and Simon, Julianna C.

Subjects

*BUBBLE dynamics, *FLEXOR tendons, *SPEED of sound, *HIGH-speed photography, *OSCILLATIONS, *FIBRIN

Abstract

Elastic, anisotropic tissue such as tendon has proven resistant to mechanical fractionation by histotripsy, a subset of focused ultrasound that uses the creation, oscillation and collapse of cavitation bubbles to fractionate tissue. Our objective was to fabricate an optically transparent hydrogel that mimics tendon for evaluation of histotripsy bubble dynamics. Ex vivo bovine deep digital flexor tendons were obtained (n = 4), and varying formulations of polyacrylamide (PA), collagen and fibrin hydrogels (n = 3 each) were fabricated. Axial sound speeds were measured at 1 MHz for calculation of anisotropy. All samples were treated with a 1.5-MHz focused ultrasound transducer with 10-ms pulses repeated at 1 Hz (p + = 127 MPa, p - = 35 MPa); treatments were monitored with passive cavitation imaging and high-speed photography. Dehydrated fibrin gels were found to be the most similar to tendon in cavitation emission energy (fibrin = 0.69 ± 0.24, tendon = 0.64 ± 0.19 [× 1010 V2]) and anisotropy (fibrin = 3.16 ± 1.12, tendon = 19.4). Bubble cloud area in dehydrated fibrin (0.79 ± 0.14 mm2) was significantly smaller than most other tested hydrogels. Finally, anisotropy was found to have moderately strong linear relationships with cavitation energy and bubble cloud size (r = –0.65 and –0.80, respectively). Dehydrated fibrin shows potential as a repeatable, transparent, tissue-mimicking hydrogel for evaluation of histotripsy bubble dynamics in elastic, anisotropic tissues. [ABSTRACT FROM AUTHOR]

Published

2023

3. Evidence of Microbubbles on Kidney Stones in Humans.

Author

Simon, Julianna C., Holm, James R., Thiel, Jeffrey, Dunmire, Barbrina, Cunitz, Bryan W., and Bailey, Michael R.

Subjects

*KIDNEY stones, *DOPPLER ultrasonography, *DECOMPRESSION sickness, *MICROBUBBLE diagnosis, *MICROBUBBLES, *HUMAN beings, *LEGAL evidence

Abstract

The color Doppler ultrasound twinkling artifact has been found to improve detection of kidney stones with ultrasound; however, it appears on only ∼60% of stones. Evidence from ex vivo kidney stones suggests twinkling arises from microbubbles stabilized in crevices on the stone surface. Yet it is unknown whether these bubbles are present on stones in humans. Here, we used a research ultrasound system to quantify twinkling in humans with kidney stones in a hyperbaric chamber. Eight human patients with non-obstructive kidney stones previously observed to twinkle were exposed to a maximum pressure of 4 atmospheres absolute (ATA) while breathing air, except during the 10-min pause at 1.6 ATA and while the pressure decreased to 1 ATA, during which patients breathed oxygen to minimize the risk of decompression sickness. A paired one-way t-test was used to compare the mean twinkle power at each pressure pause with baseline twinkling, with p < 0.05 considered to indicate significance. Results revealed that exposure to 3 and 4 ATA of pressure significantly reduced twinkle power by averages of 35% and 39%, respectively, in 7 patients (p = 0.04); data from the eighth patient were excluded because of corruption. This study supports the theory that microbubbles are present on kidney stones in humans. [ABSTRACT FROM AUTHOR]

Published

2020

4. Effect of Carbon Dioxide on the Twinkling Artifact in Ultrasound Imaging of Kidney Stones: A Pilot Study.

Author

Simon, Julianna C., Wang, Yak-Nam, Cunitz, Bryan W., Thiel, Jeffrey, Starr, Frank, Liu, Ziyue, and Bailey, Michael R.

Subjects

*KIDNEY stones diagnosis, *ULTRASONIC imaging, *PHYSIOLOGICAL effects of carbon dioxide, *MICROBUBBLE diagnosis, *PILOT projects, *ANIMAL experimentation, *BIOLOGICAL models, *CARBON dioxide, *KIDNEY stones, *RESEARCH funding, *SWINE, *MEDICAL artifacts

Abstract

Bone demineralization, dehydration and stasis put astronauts at increased risk of forming kidney stones in space. The color-Doppler ultrasound "twinkling artifact," which highlights kidney stones with color, can make stones readily detectable with ultrasound; however, our previous results suggest twinkling is caused by microbubbles on the stone surface which could be affected by the elevated levels of carbon dioxide found on space vehicles. Four pigs were implanted with kidney stones and imaged with ultrasound while the anesthetic carrier gas oscillated between oxygen and air containing 0.8% carbon dioxide. On exposure of the pigs to 0.8% carbon dioxide, twinkling was significantly reduced after 9-25 min and recovered when the carrier gas returned to oxygen. These trends repeated when pigs were again exposed to 0.8% carbon dioxide followed by oxygen. The reduction of twinkling caused by exposure to elevated carbon dioxide may make kidney stone detection with twinkling difficult in current space vehicles. [ABSTRACT FROM AUTHOR]

Published

2017

5. Investigation into the Mechanisms of Tissue Atomization by High-Intensity Focused Ultrasound.

Author

Simon, Julianna C., Sapozhnikov, Oleg A., Wang, Yak-Nam, Khokhlova, Vera A., Crum, Lawrence A., and Bailey, Michael R.

Subjects

*ATOMIZATION, *DIAGNOSTIC ultrasonic imaging, *DOSE fractionation, *DROPLETS, *STATIC pressure

Abstract

Ultrasonic atomization, or the emission of a fog of droplets, was recently proposed to explain tissue fractionation in boiling histotripsy. However, even though liquid atomization has been studied extensively, the mechanisms underlying tissue atomization remain unclear. In the work described here, high-speed photography and overpressure were used to evaluate the role of bubbles in tissue atomization. As static pressure increased, the degree of fractionation decreased, and the ex vivo tissue became thermally denatured. The effect of surface wetness on atomization was also evaluated in vivo and in tissue-mimicking gels, where surface wetness was found to enhance atomization by forming surface instabilities that augment cavitation. In addition, experimental results indicated that wetting collagenous tissues, such as the liver capsule, allowed atomization to breach such barriers. These results highlight the importance of bubbles and surface instabilities in atomization and could be used to enhance boiling histotripsy for transition to clinical use. [ABSTRACT FROM AUTHOR]

Published

2015

6. Evaluation of Stone Features That Cause the Color Doppler Ultrasound Twinkling Artifact.

Author

Rokni, Eric, Zinck, Scott, and Simon, Julianna C.

Subjects

*MICROBUBBLE diagnosis, *DOPPLER ultrasonography, *KIDNEY stones, *DIAGNOSTIC ultrasonic imaging, *STATIC pressure, *SCANNING electron microscopy, *RESEARCH, *COLOR Doppler ultrasonography, *RESEARCH methodology, *MEDICAL cooperation, *EVALUATION research, *COMPARATIVE studies, *RESEARCH funding, *MEDICAL artifacts

Abstract

The color Doppler ultrasound twinkling artifact is a rapid color shift that appears on 43%-96% of kidney stones. Surface microbubbles on kidney stones are theorized to cause twinkling as exposure to elevated static pressures of 0.41-1.13 MPa (approximately 0.5-1 times diagnostic ultrasound pressure and 5-10 times ambient pressure) reduced twinkling. However, it is unclear what external and internal stone features support bubbles. Thirteen ex vivo kidney stones were scanned with color Doppler ultrasound at 2.5, 5 and 18.5 MHz. Select stones were imaged with environmental scanning electron microscopy or underwater micro-computed tomography to evaluate features that may cause twinkling. Results revealed that the lower frequencies produced larger volumes of twinkling. Condensation first occurred in the smallest (∼1 µm diameter) surface pores and may be indicative of where bubbles form. Gas pockets were seen inside two of three tested stones that may contribute to twinkling. Overall, these results provide evidence of cavity structures both externally and internally and their correlation to the twinkling artifact. This indicates that microbubbles may be present on and within kidney stones and may contribute to the twinkling artifact. [ABSTRACT FROM AUTHOR]

Published

2021

7. Pulsed Focused Ultrasound Treatment of Muscle Mitigates Paralysis-Induced Bone Loss in the Adjacent Bone: A Study in a Mouse Model.

Author

Poliachik, Sandra L., Khokhlova, Tatiana D., Wang, Yak-Nam, Simon, Julianna C., and Bailey, Michael R.

Subjects

*PARALYSIS treatment, *SPINAL cord injuries, *THERAPEUTICS, *BED rest, *SPACE flight, *COMPUTED tomography, *ULTRASONIC imaging, *LABORATORY mice

Abstract

Bone loss can result from bed rest, space flight, spinal cord injury or age-related hormonal changes. Current bone loss mitigation techniques include pharmaceutical interventions, exercise, pulsed ultrasound targeted to bone and whole body vibration. In this study, we attempted to mitigate paralysis-induced bone loss by applying focused ultrasound to the midbelly of a paralyzed muscle. We employed a mouse model of disuse that uses onabotulinumtoxinA-induced paralysis, which causes rapid bone loss in 5 d. A focused 2 MHz transducer applied pulsed exposures with pulse repetition frequency mimicking that of motor neuron firing during walking (80 Hz), standing (20 Hz), or the standard pulsed ultrasound frequency used in fracture healing (1 kHz). Exposures were applied daily to calf muscle for 4 consecutive d. Trabecular bone changes were characterized using micro-computed tomography. Our results indicated that application of certain focused pulsed ultrasound parameters was able to mitigate some of the paralysis-induced bone loss. [ABSTRACT FROM AUTHOR]

Published

2014

8. Preclinical Safety and Effectiveness Studies of Ultrasonic Propulsion of Kidney Stones.

Author

Harper, Jonathan D., Dunmire, Barbrina, Yak-Nam Wang, Simon, Julianna C., Liggitt, Denny, Paun, Marla, Cunitz, Bryan W., Starr, Frank, Bailey, Michael R., Penniston, Kristina L., Lee, Franklin C., Hsi, Ryan S., and Sorensen, Mathew D.

Subjects

*KIDNEY stones diagnosis, *TREATMENT of calculi, *ULTRASONIC imaging, *PROPULSION systems, *TREATMENT effectiveness, *CALCIUM oxalate

Abstract

Objective To provide an update on a research device to ultrasonically reposition kidney stones transcutaneously. This article reports preclinical safety and effectiveness studies, survival data, modifications of the system, and testing in a stone-forming porcine model. These data formed the basis for regulatory approval to test the device in humans. Materials and Methods The ultrasound burst was shortened to 50 ms from previous investigations with 1-s bursts. Focused ultrasound was used to expel 2- to 5-mm calcium oxalate monohydrate stones placed ureteroscopically in 5 pigs. Additionally, de novo stones were imaged and repositioned in a stone-forming porcine model. Acute safety studies were performed targeting 2 kidneys (6 sites) and 3 pancreases (8 sites). Survival studies followed 10 animals for 1 week after simulated treatment. Serum and urine analyses were performed, and tissues were evaluated histologically. Results All ureteroscopically implanted stones (6/6) were repositioned out of the kidney in 14 ± 8 minutes with 13 ± 6 bursts. On average, 3 bursts moved a stone more than 4 mm and collectively accounted for the majority of relocation. Stones (3 mm) were detected and repositioned in the 200-kg stone-forming model. No injury was detected in the acute or survival studies. Conclusion Ultrasonic propulsion is safe and effective in the porcine model. Stones were expelled from the kidney. De novo stones formed in a large porcine model were repositioned. No adverse effects were identified with the acute studies directly targeting kidney or pancreatic tissue or during the survival studies indicating no evidence of delayed tissue injury. [ABSTRACT FROM AUTHOR]

Published

2014

9. Effects of focused ultrasound and dry needling on tendon mechanical properties.

Author

Khandare, Sujata, Smallcomb, Molly, Butt, Ali A., Elliott, Jacob, Simon, Julianna C., and Vidt, Meghan E.

Subjects

*SUPRASPINATUS muscles, *TENDONS, *ACHILLES tendon, *ULTRASONIC imaging, *TENDON rupture, *TENDON injuries, *PAIN management

Abstract

Tendon injuries are extremely common, resulting in mechanically weaker tendons that could lead to tendon rupture. Dry needling (DN) is widely used to manage pain and function after injury. However, DN is invasive and high inter-practitioner variability has led to mixed success rates. Focused ultrasound (fUS) is a non-invasive medical technology that directs ultrasound energy into a well-defined focal volume. fUS can induce thermal ablation or mechanical fractionation, with bioeffect type controlled through ultrasound parameters. Tendons must withstand high physiological loads, thus treatments maintaining tendon mechanical properties while promoting healing are needed. Our objective was to evaluate mechanical effects of DN and 3 fUS parameter sets, chosen to prioritize mechanical fractionation, on Achilles and supraspinatus tendons. Ex vivo rat Achilles and supraspinatus tendons (50 each) were divided into sham, DN, fUS-1, fUS-2, and fUS-3 (n = 10/group). Following treatment, tendons were mechanically tested. Elastic modulus of supraspinatus tendons treated with DN (126.64 ± 28.1 MPa) was lower than sham (153.02 ± 29.3 MPa; p = 0.0280). Stiffness and percent relaxation of tendons treated with DN (Achilles: 114.40 ± 31.6 N/mm; 49.10 ± 6.1%; supraspinatus: 109.53 ± 30.8 N/mm; 50.17 ± 7.6%) were lower (all p < 0.0334) than sham (Achilles: 141.34 ± 20.9 N/mm; 60.30 ± 7.7%; supraspinatus: 135.14 ± 30.2 N/mm; 60.85 ± 15.4%). Modulus of Achilles and supraspinatus tendons treated with fUS-1 (159.88 ± 25.7 MPa; 150.12 ± 22.0 MPa, respectively) were similar to sham (156.35 ± 23.0 MPa; 153.02 ± 29.3 MPa, respectively). These results suggest that fUS preserves mechanical properties better than DN, with fUS-1 performing better than fUS-2 and fUS-3. fUS should be studied further to fully understand its mechanical and healing effects to help evaluate fUS as an alternative, non-invasive treatment for tendon injuries. [ABSTRACT FROM AUTHOR]

Published

2022

10. Comparison between dry needling and focused ultrasound on the mechanical properties of the rat Achilles tendon: A pilot study.

Author

Khandare, Sujata, Smallcomb, Molly, Klein, Bailey, Geary, Colby, Simon, Julianna C., and Vidt, Meghan E.

Subjects

*ACHILLES tendon, *CELLULAR mechanics, *ULTRASONIC imaging, *TENDON injuries, *LIGAMENT injuries, *PILOT projects

Abstract

In the U.S., approximately 14 million tendon and ligament injuries are reported each year. Dry needling (DN) is a conservative treatment introduced to alleviate pain and restore function; however, it is invasive and has mixed success. Focused ultrasound (fUS) is a non-invasive technology that directs ultrasound energy into a well-defined focal volume. fUS induces thermal and/or mechanical bioeffects which can be controlled by the choice of ultrasound parameters. fUS could be an alternative to DN for treatment of tendon injuries, but the bioeffects must be established. Thus, the purpose of this pilot study was to compare the effect of DN and fUS on the mechanical properties and cell morphology of 30 ex vivo rat Achilles tendons. Tendons were randomly assigned to sham, DN, or fUS, with 10 tendons per group. Within each group, 5 tendons were evaluated mechanically, and 5 tendons were analyzed histologically. Elastic modulus in the DN (74.05 ± 15.0 MPa) group was significantly lower than sham (149.84 ± 59.1 MPa; p = 0.0094) and fUS (128.84 ± 28.3 MPa; p = 0.0453) groups. Stiffness in DN (329.05 ± 236.8 N/mm; p = 0.0034) and fUS (315.26 ± 68.9 N/mm; p = 0.0027) groups were significantly lower than sham (786.10 ± 238.7 N/mm) group. Histologically, localized necrosis was observed in 3 out of 5 tendons exposed to fUS, with surrounding tissue unharmed; no evidence of cellular injury was observed in DN or sham groups. These results suggest that fUS preserves the mechanical properties of tendon better than DN. Further studies are needed to evaluate fUS as an alternative, noninvasive treatment modality for tendon injuries. [ABSTRACT FROM AUTHOR]

Published

2021