在临床环境中通过非增强螺旋计算机断层扫描确定结石成分。

Determination of stone composition by noncontrast spiral computed tomography in the clinical setting.

作者信息

Nakada S Y, Hoff D G, Attai S, Heisey D, Blankenbaker D, Pozniak M

机构信息

Department of Surgery (Division of Urology), University of Wisconsin Medical School, Madison, Wisconsin 53792-3236, USA.

出版信息

Urology. 2000 Jun;55(6):816-9. doi: 10.1016/s0090-4295(00)00518-5.

DOI:10.1016/s0090-4295(00)00518-5

PMID:10840083

Abstract

OBJECTIVES

Several investigators have evaluated noncontrast computed tomography (NCCT) in predicting stone composition in vitro. We assessed NCCT in predicting stone composition in patients presenting to our emergency room with flank pain and stone disease.

METHODS

One hundred twenty-nine patients presenting to our university hospital with flank pain underwent renal colic protocol NCCT scans at the request of the emergency room physicians. A General Electric, high-speed advantage CT scanner was used at 120 kV, 200 mA, and 1.4:1 pitch, with collimation varying between 3 and 5 mm. Ninety-nine patients with predominantly (greater than 50%) calcium oxalate or uric acid composition after either stone passage or stone removal were identified. Each scan was analyzed by one of two radiologists, who determined the predominant attenuation for each stone. Stones once passed or retrieved were analyzed by Urocor Laboratories. The attenuation and attenuation/size ratio (peak attenuation/size in millimeters) were compared with the results of the stone analysis.

RESULTS

Eighty-two calculi predominantly composed of calcium oxalate and 17 calculi predominantly composed of uric acid were identified in 99 patients. The calculi ranged in size from 1 to 28 mm. A significant difference (P = 0.017, unpaired t test) was found between the Hounsfield measurement of uric acid calculi (mean 344 +/- 152 HU) and the Hounsfield measurement of calcium oxalate calculi (mean 652 +/- 490 HU). If only the Hounsfield units from stones 4 mm or larger were compared, the data were even more compelling (P = 0.002). However, using an attenuation/size ratio cutoff of greater than 80, the negative predictive value was 99% that a stone would be predominantly calcium oxalate.

CONCLUSIONS

Using peak attenuation measurements and the attenuation/size ratio of urinary calculi from NCCT, we were able to differentiate between uric acid and calcium oxalate stones.

摘要

目的

数名研究者已在体外评估了非增强计算机断层扫描（NCCT）对结石成分的预测能力。我们对因胁腹疼痛和结石病前来我院急诊室就诊的患者，评估了NCCT对结石成分的预测能力。

方法

129名因胁腹疼痛前来我院就诊的患者，应急诊室医生的要求接受了肾绞痛方案的NCCT扫描。使用通用电气公司的高速优势CT扫描仪，管电压120 kV，管电流200 mA，螺距1.4:1，准直范围在3至5 mm之间。确定了99名结石排出或取出后主要（超过50%）为草酸钙或尿酸成分的患者。每次扫描由两名放射科医生之一进行分析，他们确定每颗结石的主要衰减值。排出或取出的结石由Urocor实验室进行分析。将衰减值和衰减/大小比（峰值衰减/毫米大小）与结石分析结果进行比较。

结果

在99名患者中，发现了82颗主要由草酸钙组成的结石和17颗主要由尿酸组成的结石。结石大小范围为1至28 mm。尿酸结石的亨氏测量值（平均344±152 HU）与草酸钙结石的亨氏测量值（平均652±490 HU）之间存在显著差异（P = 0.017，独立样本t检验）。如果仅比较4 mm或更大结石的亨氏单位，数据更具说服力（P = 0.002）。然而，使用大于80的衰减/大小比临界值，结石主要为草酸钙的阴性预测值为99%。

结论

通过NCCT测量尿结石的峰值衰减值和衰减/大小比，我们能够区分尿酸结石和草酸钙结石。

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在临床环境中通过非增强螺旋计算机断层扫描确定结石成分。

Determination of stone composition by noncontrast spiral computed tomography in the clinical setting.

作者信息

机构信息

出版信息

OBJECTIVES

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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