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Objective:To investigate the typing and clinical value of posterior group renal calyces.Methods:From April 2020 to June 2021, 640 patients (320 men and 320 women) who underwent CTU examination in our hospital with kidneys on both sides and normal or only mild hydronephrosis in the collecting system were analyzed. A total of 1 280 renal CTU three-dimensional reconstructed images were counted.The patients aged 52.4±11.9 years. The patients' CTU images were reconstructed in three dimensions using the spine as a marker to rotate the collecting system images in stereoscopic space to simulate a prone position. A two-person review was taken to observe the imaging morphology of the renal calyces in the prone position, and the 640 renal calyces in the posterior group of the left and right sides were counted for staging. Based on the morphology of the renal calyces and the influence on the establishment of surgical access, the posterior group of renal calyces was divided into 3 major types. Pot-belly type: the renal pelvis is shaped like a pot-belly, and the renal pelvis is directly connected to the cup-shaped minor calyces without a distinct major renal calyces. Classically branched: 2 or more major renal calyces are branched and converge to form the renal pelvis. Elongated branched: the major calyces are branched, with at least one major calyces having an axis length ≥0.9cm and a neck width ≤0.3cm.The classic branching type is divided into three types, a, b, and c, including seven subtypes, based on the relationship of the posterior group of the minor calyces to the major calyces. Type a is derived from group 1 major calyces only, type b is derived from group 2 major calyces at the same time, and type c is derived from the upper, middle and lower groups of major calyces at the same time. Type a contains 3 subtypes.Type a1 is derived from the upper group of major calyces only, type a2 is derived from the middle group of major calyces only, and type a3 is derived from the lower group of major calyces only. Type b is also divided into 3 subtypes. Type b1 is derived from the upper and middle groups of major calyces at the same time, type b2 is derived from the middle and lower groups of major calyces at the same time, and type b3 for the upper and lower renal major calyces. Type c had no corresponding subtype.Results:Statistical findings revealed that all kidneys had posterior group calyces. The morphological typing of the posterior group of calyces was 8.83% (113/1 280) for the pot-bellied type, which had the highest occurrence of 2 minor calyces (5.63%, 72/1 280). 71.25% (912/1 280) had the classically branched type, which had the highest occurrence of 3 minor calyces (31.17%, 399/1 280). 19.92% (255/1 280) had the elongated branched type, with the highest percentage of 3 occurring in the calyces (9.92%, 127/1 280). The anatomical typing of the classical branching type occurred in 20.50% (187/912) for type a, 66.45% (606/912) for type b, and 13.05% (119 /912) for type c. The percentage of occurrence of type a1/a2/a3 was 4.06% (37/ 912), 6.14% (56/ 912), and 10.31% (94/912). b1/b2/b3 types occurred in 2.03% (21/912), 7.46% (68/912), and 56.69% (517/912), respectively.Conclusions:The posterior group of calyces is structurally complex and extremely variable. In this study, the posterior group calyces were found to be present in all patients, and the posterior group calyces were morphologically divided into 3 types, with the highest percentage of occurrence of the classical branching type and the highest percentage of 3 posterior group minor calyces. The classical branching anatomical typing was highest in type b with the highest percentage of type b3, which combined with stone distribution, made it easy to choose the puncture location. The typing of the posterior group of calyces can provide an anatomical basis for PCNL puncture from the posterior group.
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Objective:To compare the injury of renal blood vessels using different puncture pathways and access sizes.Methods:Between April 2018 and June 2019, eighty fresh pig kidneys were selected to perform percutaneous puncture and dilation, which was used to compare the injury of renal blood vessels with different puncture pathways and access sizes. The puncture pathway included the centerline of the normal renal pyramid (A), centreline of one side pyramid of the fused renal pyramid (FRP) (B), midline of the entire FRP (C) and midline of the renal column (D). The access size included F8, F12, F16, F20, F24 and F30. Histopathological methods were used to analyze the injury of renal blood vessels.Results:The puncture through paths A and B mainly caused injury to the grade Ⅴ and Ⅵ arteries in renal cortex. The puncture often directly injures the grade Ⅳ artery in path C. The puncture often simultaneously injures the grade Ⅲ-Ⅵ arteries in path D. Grade Ⅲ artery injury began to occur when paths A, B, C, and D were dilated to F30, F24, F16, and F12, respectively. The degree of arterial injury among the four different puncture pathways was significantly different in F8, F12, F16, F20, F24 and F30 ( P<0.05). Statistical differences were found between paths A and D in F12, F16, F20, F24 and F30 ( P<0.05), and between paths A and C in F16, F20 and F24 ( P<0.05). No significant difference was found between paths A and B in all access sizes ( P>0.05). Compared with F8, the degree of arterial injury of the F30 in path A and the F24 and F30 in path B were increased significantly ( P<0.05). Conclusions:Vascular injury in path D was the most serious followed by that in path C. Relatively little vascular injury can be achieved in paths A and B. The vascular injury increased when the path B was dilated to F24, while the path A needed to be dilated to F30.
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Objective@#To analyze the anatomical structure and distribution of the fused renal pyramid (FRP) in cadaveric kidney, and discuss its appearances by CT and ultrasonic examinations.@*Methods@#From June 2018 to September 2018, 108 cadaveric kidneys were proceeded for regional anatomy. The distribution and anatomical manifestations of FRP was recorded. The renal pyramid was sliced and HE stained to explore the vascular distribution in FRP. From October 2018 to January 2019, ultrasound imaging data of 112 patients with 224 kidneys were collected, including 60 males and 52 females, age (39.0±15.1), ranging from 16 to 73 years old. The renal imaging data of 89 patients and 178 patients with enhanced renal CT were collected, including 48 males and 41 females. Age (45.4±13.6), ranging from 23 to 69 years old. The imaging findings of FRP in ultrasound and enhanced CT was summarized.@*Results@#In cadaver kidneys, the proportion of FRP in upper and lower calyces was 68.6% (74/108) and 64.8% (70/108), respectively, higher than that in middle calyces 34.3% (37/108). In the middle group, the incidence of mild fusion was 39.0% (16/41) and severe fusion was 48.8% (20/41). The incidence of fusion of two renal pyramidal structures was 90.2% (37/41). HE staining showed that the boundary between the artery in FRP and the surrounding renal pyramidal was unclear, and the protection of connective tissue was lacking. In Ultrasound, the FRP presented as a large trapezoidal hypo-echoic area with red and blue color signals in doppler mode. In ultrasound, the incidence of FRP was 18.8% (42/224). In enhanced CT, the FRP presented as enhanced cord-like high density shade in large low density area in cortex phase. In enhanced CT, the incidence of FRP 27.5%(49/178).@*Conclusions@#The FRP is a common structure in human kidney. The arteries localize within the FRP and are absence of sufficient connective tissue protection which are different from normal arteries. Ultrasound and enhanced CT have recognition ability for FRP.
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Objective To analyze the anatomical structure and distribution of the fused renal pyramid (FRP) in cadaveric kidney,and discuss its appearances by CT and ultrasonic examinations.Methods From June 2018 to September 2018,108 cadaveric kidneys were proceeded for regional anatomy.The distribution and anatomical manifestations of FRP was recorded.The renal pyramid was sliced and HE stained to explore the vascular distribution in FRP.From October 2018 to January 2019,ultrasound imaging data of 112 patients with 224 kidneys were collected,including 60 males and 52 females,age (39.0 ± 15.1),ranging from 16 to 73 years old.The renal imaging data of 89 patients and 178 patients with enhanced renal CT were collected,including 48 males and 41 females.Age (45.4 ± 13.6),ranging from 23 to 69 years old.The imaging findings of FRP in ultrasound and enhanced CT was summarized.Results In cadaver kidneys,the proportion of FRP in upper and lower calyces was 68.6% (74/108) and 64.8% (70/108),respectively,higher than that in middle calyces 34.3% (37/108).In the middle group,the incidence of mild fusion was 39.0% (16/41) and severe fusion was 48.8% (20/41).The incidence of fusion of two renal pyramidal structures was 90.2% (37/41).HE staining showed that the boundary between the artery in FRP and the surrounding renal pyramidal was unclear,and the protection of connective tissue was lacking.In Ultrasound,the FRP presented as a large trapezoidal hypo-echoic area with red and blue color signals in doppler mode.In ultrasound,the incidence of FRP was 18.8% (42/224).In enhanced CT,the FRP presented as enhanced cord-like high density shade in large low density area in cortex phase.In enhanced CT,the incidence of FRP 27.5% (49/178).Conclusions The FRP is a common structure in human kidney.The arteries localize within the FRP and are absence of sufficient connective tissue protection which are different from normal arteries.Ultrasound and enhanced CT have recognition ability for FRP.
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Objective To explore the clinical significance of fused renal pyramid (FRP) structure in the establishment of percutaneous renal access.Methods From May 2017 to April 2018,10 fresh porcine kidneys were selected to cast in blood vessels for grading the kidney artery.Then another 80 isolated porcine kidueys were used to simulate percutaneous renal pu ncture and dilatation to establish F24 operative access by the same surgeon.Under the endoscope and microscope,we compared the effects of four different puncture paths on the occurrence of renal vascular injury when respectively punctured through the normal renal pyramid (group A),the side of the FRP (group B),the centre of the FRP (group C) and the renal column (group D).Results The kidney arteries can be divided into six grades,there is grade Ⅳ branchinterlobar artery walking inside the FRP.The diameter of interlobar artery in the FRP was significantly smaller than that in the renal column (0.442 ±0.012) mm vs.(0.778 ±0.037) mm,(P <0.001).Endoscopic observation and pathological tissue section showed the following results.In group A,there was no injured blood vessel distributed along the access.There were six specimens with grade Ⅴ or Ⅵ arteries injury in the cortex.Owing to the small size of the renal pyramid and the inaccurate location of the puncture,there was also injury associated with a normal grade Ⅳ artery in the renal column.In group B,there was a certain distance between the tract and the grade Ⅳ artery that distributed in the FRP,injury was still noticed in four specimens.And six specimens have grade Ⅴ/Ⅵ arterial injury.As the distance between the tract and the renal column decreased,there was a case in which a simultaneously injury occurred to the extremity of a grade Ⅲ artery and a grade Ⅳ artery.In group C,there was a white thin strip of connective tissue exposed along the puncture tract.Ectopic grade Ⅳ artery injury occurred in fourteen specimens,and grade Ⅴ/Ⅵ artery injury occurred in seven specimens.In group D,there were grade Ⅲ to Ⅵ arteries distributed along the operational access,which was cowered with white fat and connective tissue.The number of arteryinjury in grades Ⅲ,Ⅳ,and Ⅴ/Ⅵ were4,19,and 5,respectively.The mean ranks of artery injury degree in groups A (17.0),B (30.1),C (33.5) and D (41.5) gradually increased,and the difference was significant (P =0.006).There was a significant difference between group A and C (P =0.018),while no significant difference between group A and B (P =0.122),groups C and D (P =0.072).The proportion of grade Ⅳ artery injury in group A,B,and C was 5% (1/20),25% (5/20),and 70% (14/20),respectively.There was a significant difference between group A and C (P =0.029),while no significant difference between group A and B (P =0.316).There was no significant difference in the injury of grade Ⅴ and Ⅵ artery in four groups (P =0.827).Conclusions When establishing a percutaneous renal access,vascular injury caused bv puncturing through the FRP cannot be ignored.It is necessary to carefu lly identify and bypass the FRP when selecting the puncture path.If unavoidable,the puncture path shoull be on the centreline of one side pyramid of the FRP.