Your search keyword '"James A. McAteer"' showing total 7 results

1. Effect of the Body Wall on Lithotripter Shock Waves

Author

James A. McAteer, Guangyan Li, James C. Williams, and Zachary C. Berwick

Subjects

Shock wave, medicine.medical_specialty, Hydrophone, Field (physics), Swine, business.industry, Urology, Abdominal Wall, Sus scrofa, Time resolution, Acoustics, Symmetry (physics), Surgery, Shock (mechanics), Optics, Cardinal point, Lithotripsy, Rise time, Pressure, medicine, Animals, Experimental Endourology, business, Electromagnetic Phenomena, Computer Science::Formal Languages and Automata Theory

Abstract

Determine the influence of passage through the body wall on the properties of lithotripter shock waves (SWs) and the characteristics of the acoustic field of an electromagnetic lithotripter.Full-thickness ex vivo segments of pig abdominal wall were secured against the acoustic window of a test tank coupled to the lithotripter. A fiber-optic probe hydrophone was used to measure SW pressures, determine shock rise time, and map the acoustic field in the focal plane.Peak positive pressure on axis was attenuated roughly proportional to tissue thickness-approximately 6% per cm. Irregularities in the tissue path affected the symmetry of SW focusing, shifting the maximum peak positive pressure laterally by as much as ∼2 mm. Within the time resolution of the hydrophone (7-15 ns), shock rise time was unchanged, measuring ∼17-21 ns with and without tissue present. Mapping of the field showed no effect of the body wall on focal width, regardless of thickness of the body wall.Passage through the body wall has minimal effect on the characteristics of lithotripter SWs. Other than reducing pulse amplitude and having the potential to affect the symmetry of the focused wave, the body wall has little influence on the acoustic field. These findings help to validate laboratory assessment of lithotripter acoustic field and suggest that the properties of SWs in the body are much the same as have been measured in vitro.

Published

2014

2. Evaluation of the LithoGold LG-380 Lithotripter:In VitroAcoustic Characterization and Assessment of Renal Injury in the Pig Model

Author

Bret A. Connors, Andrew P. Evan, James C. Williams, Rajash K. Handa, Yuri A. Pishchalnikov, James A. McAteer, and James E. Lingeman

Subjects

Pathology, medicine.medical_specialty, Swine, Urology, medicine.medical_treatment, Renal function, Lithotripsy, Kidney, Focal zone, Renal injury, medicine, Animals, Experimental Endourology, Renal response, Acoustic field, business.industry, Pig model, Acoustics, Equipment Design, medicine.anatomical_structure, Models, Animal, Female, Nuclear medicine, business

Abstract

Conduct a laboratory evaluation of a novel low-pressure, broad focal zone electrohydraulic lithotripter (TRT LG-380).Mapping of the acoustic field of the LG-380, along with a Dornier HM3, a Storz Modulith SLX, and a XiXin CS2012 (XX-ES) lithotripter was performed using a fiberoptic hydrophone. A pig model was used to assess renal response to 3000 shockwaves (SW) administered by a multistep power ramping protocol at 60 SW/min, and when animals were treated at the maximum power setting at 120 SW/min. Injury to the kidney was assessed by quantitation of lesion size and routine measures of renal function.SW amplitudes for the LG-380 ranged from (P(+)/P(-)) 7/-1.8 MPa at PL-1 to 21/-4 MPa at PL-11 while focal width measured ~20 mm, wider than the HM3 (8 mm), SLX (2.6 mm), or XX-ES (18 mm). For the LG-380, there was gradual narrowing of the focal width to ~10 mm after 5000 SWs, but this had negligible effect on breakage of model stones, because stones positioned at the periphery of the focal volume (10 mm off-axis) broke nearly as well as stones at the target point. Kidney injury measured less than 0.1% FRV (functional renal volume) for pigs treated using a gradual power ramping protocol at 60 SW/min and when SWs were delivered at maximum power at 120 SW/min.The LG-380 exhibits the acoustic characteristics of a low-pressure, wide focal zone lithotripter and has the broadest focal width of any lithotripter yet reported. Although there was a gradual narrowing of focal width as the electrode aged, the efficiency of stone breakage was not affected. Because injury to the kidney was minimal when treatment followed either the recommended slow SW-rate multistep ramping protocol or when all SWs were delivered at fast SW-rate using maximum power, this appears to be a relatively safe lithotripter.

Published

2013

3. Stability of the Infection Marker Struvite in Urinary Stone Samples

Author

Takeisha L. Farmer, James E. Lingeman, Molly E. Jackson, Rachel Deal, James C. Williams, Andrew J. Sacks, Kate Englert, and James A. McAteer

Subjects

Chemical breakdown, Chromatography, Struvite, business.industry, Urology, Urinary stone, Magnesium Compounds, Struvite kidney stones, Infections, medicine.disease, Phosphates, chemistry.chemical_compound, Tomography x ray computed, chemistry, Spectroscopy, Fourier Transform Infrared, medicine, Humans, Urinary Calculi, Kidney stones, Experimental Endourology, Tomography, X-Ray Computed, business, Micro ct

Abstract

Struvite in kidney stones is an important marker for infection. In kidney stone samples, struvite is known to be prone to chemical breakdown, but no data exist on the stability of samples stored in dry form. The objective of this study was to examine stability of struvite under increasingly poor conditions of storage.Samples of struvite kidney stones were broken to obtain 38 pieces averaging 67 mg in weight, and these were randomized into four storage conditions: Airtight containers stored in the dark, open containers in the dark, open containers in ambient light, and open containers at elevated temperature (40°C). Pieces were left for 6 months, and then analyzed for changes using micro CT and Fourier transform infrared spectroscopy (FT-IR).Initial samples proved to be struvite, indicating no transformation in the large specimens that had been stored in airtight containers in the dark for more than 6 years before this study. Pieces of struvite taken from these large specimens appeared unchanged by micro CT and FT-IR after being stored in closed containers for 6 months, but 8 of 9 pieces in open containers showed the presence of newberyite in surface layers, as did 10 of 10 pieces in open containers out in ambient light. All pieces stored at 40°C showed transformation of struvite, with 60% of the pieces showing the presence of amorphous phosphates, indicating complete breakdown of struvite in the surface layers of the pieces.We conclude that struvite in dry kidney stone samples is stable when the specimens are stored in airtight containers at room temperature, even after several years.

Published

2012

4. Shockwave Lithotripsy: Anecdotes and Insights

Author

James E. Lingeman, James A. McAteer, Andrew P. Evan, Samuel C. Kim, and Ramsay L. Kuo

Subjects

medicine.medical_specialty, business.industry, Urology, medicine.medical_treatment, Equipment Design, Lithotripsy, Surgery, Tissue damage, medicine, Humans, Anesthesia, Urinary Calculi, Radiology, Ultrasonography, business, Shockwave lithotripsy

Abstract

Shockwave lithotripters have evolved considerably since the introduction of the Dornier HM3 machine 20 years ago. Although shockwave lithotripsy (SWL) remains the preferred treatment for the majority of symptomatic upper urinary-tract calculi, newer lithotripters are not as effective and may have a higher risk of side effects. Lack of progress in lithotripter evolution is attributable to inadequate understanding of how and why shockwaves produce effects on stone and tissue. Current knowledge suggests that stones fragment by the mechanisms of compression fracture, spallation, squeezing, and acoustic cavitation, while tissue damage from shockwaves is secondary to cavitation and non-cavitational forces such as sheer stress. It appears likely that most tissue damage from shockwaves is caused by cavitation. As the understanding of SWL matures, new lithotripter designs may emerge that truly represent an improvement on the original Dornier HM3 machine.

Published

2003

5. Cavitation Bubble Cluster Activity in the Breakage of Kidney Stones by Lithotripter Shockwaves

Author

Yuri A. Pishchalnikov, James A. McAteer, Lawrence A. Crum, Robin O. Cleveland, James C. Williams, Michael R. Bailey, Andrew P. Evan, Oleg A. Sapozhnikov, and Tim Colonius

Subjects

medicine.medical_specialty, Urology, medicine.medical_treatment, Bubble, In Vitro Techniques, Lithotripsy, Calcium Sulfate, Article, High-Energy Shock Waves, Kidney Calculi, Breakage, Photography, medicine, Cluster (physics), Humans, Collapse (medical), Cavitation bubble, business.industry, Mechanics, medicine.disease, Surgery, Kidney stones, medicine.symptom, business

Abstract

Background and Purpose: There is strong evidence that cavitation bubble activity contributes to stone breakage and that shockwave-bubble interactions are involved in the tissue trauma associated with shockwave lithotripsy. Cavitation control may thus be a way to improve lithotripsy. Materials and Methods: High-speed photography was used to analyze cavitation bubble activity at the surface of artificial and natural kidney stones during exposure to lithotripter shockwaves in vitro. Results: Numerous individual bubbles formed on the surfaces of stones, but these bubbles did not remain independent but rather combined to form clusters. Bubble clusters formed at the proximal and distal ends and at the sides of stones. Each cluster collapsed to a narrow point of impact. Collapse of the proximal cluster eroded the leading face of the stone, and the collapse of clusters at the sides of stones appeared to contribute to the growth of cracks. Collapse of the distal cluster caused minimal damage. Conclusion: Cavitation-mediated damage to stones is attributable, not to the action of solitary bubbles, but to the growth and collapse of bubble clusters.

Published

2003

6. Renal Injury by Extracorporeal Shock Wave Lithotripsy

Author

Lynn R. Willis, James E. Lingeman, James A. McAteer, Bret A. Connors, and Andrew P. Evan

Subjects

medicine.medical_specialty, Kidney, business.industry, Urology, medicine.medical_treatment, Renal function, Lithotripsy, Extracorporeal shock wave lithotripsy, Surgery, medicine.anatomical_structure, Blood pressure, Internal medicine, medicine, Cardiology, Risk factor, Complication, Adverse effect, business

Abstract

Numerous clinical and experimental reports indicate that shock wave lithotripsy (SWL) causes acute renal effects in a majority, if not all, treated kidneys. The induced acute renal damage may be severe, and clinical findings point to several risk factors that appear to predispose SWL patients to an increased incidence of renal trauma. In addition, compelling clinical data suggest that exposure to shock waves in therapeutic doses is associated with at least three chronic adverse effects: (1) an accelerated rise in arterial blood pressure; (2) a decrease in renal function; and (3) an increased rate of stone recurrence. These long-term complications raise concern about the potential for increased and significant patient morbidity as SWL continues to gain in popularity. Such concern is heightened by the prospect that little is known about the factors of SWL treatment that contribute to stone comminution or cause tissue injury.

Published

1991

7. Bioeffects of Extracorporeal Shock Wave Lithotripsy

Author

Stephen A. Kempson, James E. Lingeman, Andrew P. Evan, and James A. McAteer

Subjects

Acute effects, medicine.medical_specialty, Kidney, business.industry, Urology, medicine.medical_treatment, Urinary system, Extracorporeal shock wave lithotripsy, Adipose capsule of kidney, medicine.anatomical_structure, Tissue damage, medicine, business

Abstract

Extracorporeal shock wave Lithotripsy (ESWL) is an effective procedure for the noninvasive treatment of renal stones. Although ESWL has been perceived to be safe, numerous recent reports have presented evidence that ESWL causes severe acute effects and may induce chronic complications. It has been demonstrated that ESWL induces tissue damage, and several urinary and serum values are elevated 24 hours after ESWL, suggesting significant trauma to the kidney and adjacent tissues. One or more forms of morphologic renal trauma occurs in 63% to 85% of all ESWL patients. These injuries range from mild contusions to large subcapsular or perinephric hematomas. More disturbing is the suggestion that ESWL may be associated with subsequent hypertension. Only a few experimental studies have been performed in animals to document the bioeffects of shock waves. The data collected from these studies indicate a high frequency of tissue damage, particularly to the kidney, similar to the structural and functional alterations...

Published

1987