scholarly article | Q13442814 |
P50 | author | James C. Williams | Q38319599 |
P2093 | author name string | James A McAteer | |
James E Lingeman | |||
Yuri A Pishchalnikov | |||
Tariq A Hameed | |||
Molly E Jackson | |||
Chad A Zarse | |||
P2860 | cites work | Nondestructive analysis of urinary calculi using micro computed tomography. | Q24799579 |
Stone fragility--a new therapeutic distinction | Q34049697 | ||
CT and stone fragility | Q34181154 | ||
Measurement of observer agreement | Q35159421 | ||
Progress in the use of helical CT for imaging urinary calculi | Q36084906 | ||
Stone analysis | Q36396134 | ||
Diabetes mellitus and hypertension associated with shock wave lithotripsy of renal and proximal ureteral stones at 19 years of followup | Q36442871 | ||
High resolution detection of internal structure of renal calculi by helical computerized tomography | Q43822654 | ||
The role of stress waves and cavitation in stone comminution in shock wave lithotripsy | Q44038460 | ||
Variability of renal stone fragility in shock wave lithotripsy | Q44480041 | ||
Helical CT evaluation of the chemical composition of urinary tract calculi with a discriminant analysis of CT-attenuation values and density | Q44954680 | ||
Helical CT of urinary calculi: effect of stone composition, stone size, and scan collimation | Q46049689 | ||
Determination of stone composition by noncontrast spiral computed tomography in the clinical setting | Q46678069 | ||
Ultracal-30 gypsum artificial stones for research on the mechanisms of stone breakage in shock wave lithotripsy | Q46679477 | ||
Sex- and age-related composition of 10 617 calculi analyzed by infrared spectroscopy. | Q51004880 | ||
Modeling elastic wave propagation in kidney stones with application to shock wave lithotripsy. | Q51326410 | ||
A mechanistic analysis of stone fracture in lithotripsy. | Q51920796 | ||
Role of volume and attenuation value histogram of urinary stone on noncontrast helical computed tomography as predictor of fragility by extracorporeal shock wave lithotripsy. | Q53531422 | ||
Predictions of outcomes of renal stones after extracorporeal shock wave lithotripsy from stone characteristics determined by unenhanced helical computed tomography: a multivariate analysis. | Q53589283 | ||
Hounsfield units on computerized tomography predict stone-free rates after extracorporeal shock wave lithotripsy. | Q53655242 | ||
Calcium oxalate stone morphology: fine tuning our therapeutic distinctions | Q70956601 | ||
Radiographic prognostic criteria for extracorporeal shock-wave lithotripsy: a study of 485 patients | Q71714995 | ||
Renal trauma and the risk of long-term complications in shock wave lithotripsy | Q74132965 | ||
Calcium stone fragility is predicted by helical CT attenuation values | Q74211689 | ||
Computerized tomography attenuation value of renal calculus: can it predict successful fragmentation of the calculus by extracorporeal shock wave lithotripsy? A preliminary study | Q77949434 | ||
Role of computed tomography with no contrast medium enhancement in predicting the outcome of extracorporeal shock wave lithotripsy for urinary calculi | Q81746055 | ||
Hounsfield unit density accurately predicts ESWL success | Q82473461 | ||
P433 | issue | 4 | |
P921 | main subject | calcium oxalate | Q412399 |
P304 | page(s) | 201-206 | |
P577 | publication date | 2007-06-13 | |
P1433 | published in | Urological Research | Q15746542 |
P1476 | title | CT visible internal stone structure, but not Hounsfield unit value, of calcium oxalate monohydrate (COM) calculi predicts lithotripsy fragility in vitro | |
P478 | volume | 35 |
Q90751247 | Accuracy of Ex Vivo Semiautomatic Segmentation of Urinary Stone Size in Computed Tomography Compared With Manual Size Estimation in Radiographic Correlation |
Q88912827 | Advanced non-contrasted computed tomography post-processing by CT-Calculometry (CT-CM) outperforms established predictors for the outcome of shock wave lithotripsy |
Q38545810 | Advances in CT imaging for urolithiasis |
Q37816951 | Assessment of stone composition in the management of urinary stones |
Q46927030 | Cystine calculi: correlation of CT-visible structure, CT number, and stone morphology with fragmentation by shock wave lithotripsy |
Q37665010 | Differentiation of calcium oxalate monohydrate and calcium oxalate dihydrate stones using quantitative morphological information from micro-computerized and clinical computerized tomography |
Q34292839 | Distinguishing characteristics of idiopathic calcium oxalate kidney stone formers with low amounts of Randall's plaque |
Q40106733 | Epidemiology, pathophysiology, and management of uric acid urolithiasis: A narrative review |
Q42132088 | Fragility of brushite stones in shock wave lithotripsy: absence of correlation with computerized tomography visible structure |
Q46204102 | Impact of stone density on outcomes in percutaneous nephrolithotomy (PCNL): an analysis of the clinical research office of the endourological society (CROES) pcnl global study database |
Q37802241 | Micro-computed tomography for analysis of urinary calculi |
Q64063466 | Morphological characteristics and microstructure of kidney stones using synchrotron radiation μCT reveal the mechanism of crystal growth and aggregation in mixed stones |
Q60921455 | Noncontrast Computed Tomography Parameters for Predicting Shock Wave Lithotripsy Outcome in Upper Urinary Tract Stone Cases |
Q90663335 | Predicting shockwave lithotripsy outcome for urolithiasis using clinical and stone computed tomography texture analysis variables |
Q48125540 | Predicting the mineral composition of ureteral stone using non-contrast computed tomography |
Q34030752 | Protein content of human apatite and brushite kidney stones: significant correlation with morphologic measures. |
Q46931738 | Quantitative Prediction of Stone Fragility From Routine Dual Energy CT: Ex vivo proof of Feasibility |
Q44719104 | Re: El-Assmy et al.: kidney stone size and Hounsfield units predict successful shockwave lithotripsy in children (Urology 2013;81:880-884). |
Q42321915 | Recent developments in computed tomography for urolithiasis: diagnosis and characterization |
Q87011738 | Reply by the authors |
Q57050903 | Robustness of Textural Features to Predict Stone Fragility Across Computed Tomography Acquisition and Reconstruction Parameters |
Q42175715 | Stability of the infection marker struvite in urinary stone samples |
Q34369828 | Stone clearance after extracorporeal shockwave lithotripsy in patients with solitary pure calcium oxalate stones smaller than 1.0 cm in the proximal ureter, with special reference to monohydrate and dihydrate content |
Q54237011 | Stone heterogeneity index on single-energy noncontrast computed tomography can be a positive predictor of urinary stone composition. |
Q30480601 | The acute and long-term adverse effects of shock wave lithotripsy |
Q57152169 | The interior structure of breast microcalcifications assessed with micro computed tomography |
Q39119052 | Urolithiasis: evaluation, dietary factors, and medical management: an update of the 2014 SIU-ICUD international consultation on stone disease. |
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