Three-dimensional quantitative analysis of arterial bed and elements of pelvicalyceal system of kidneys in men

The aim of the study was to investigate the patterns of three-dimensional quantitative organization of the renal artery branches in relation to the elements of the renal pelvicalyceal system in men. The study was conducted on 58 corrosion preparations of arterial vessels and renal pelvicalyceal structures obtained from men with postmortem age intervals from 22 to 75 years. As a result of the morphological study, a spatial and quantitative characteristic was given to different variants of renal artery branching, with an emphasis on their transformation into secondary vascular branches classified as zonal arteries. Additionally, a detailed analysis of the topographic and anatomical relationship between the intraorgan arterial branches of the renal artery and the excretory segments of the kidney was carried out, which made it possible to clarify the features of their spatial organization. Knowledge of the spatial arrangement of the arterial branches of the kidney, which directly correlates with the variable features of its renal pelvicalyceal apparatus and excretory system segments, opens the way to predicting potential obstacles during surgical procedures, especially during nephrolithotomy.

1. Alyaev Yu. G., Glybochko P. V. Mochekamennaya bolezn. Sovremennyy vzglyad na problem = Urolithiasis. A modern view of the problem. Moscow: Medforum; 2016: 148 p.

2. Glybochko P. V., Alyaev Yu. G. 3D-tekhnologii pri operatsiyakh na pochke: ot khirurgii virtualnoy k realnoy = 3D technologies in kidney surgeries: from virtual to real surgery. URL: https://urologyjournal.ru/ru/archive/article/31753.

3. Kolsanov A. V., Ivanova V. D., Gelashvili O. A. Clinical anatomy of the renal arteries according to computer modeling data. Morfologiya = Morphology. 2019; 3: 28-32.

4. Murushidi M. Yu. Trekhmernoe anatomicheskoe modelirovanie pochechnykh arteriy pri planirovanii perkutannogo dostupa k pochke = Three-dimensional anatomical modeling of the renal arteries in planning percutaneous access to the kidney. Abstract of thesis of Doctor of Medical Sciences. Tyumen; 2023: 24 p.

5. Chigidinova D. C., Gavrilova N. Ye., Rudenko B. A., Shanoyan A. S., Mazaev V. P., Shukurov F. B. Endovascular treatment of VA stenosis caused by fibromuscular dysplasia. Clinical case. Kreativnaya khirurgiya i onkologiya = Creative surgery and oncology. 2019; 9 (3): 223-228.

6. Autorino S. De. R., Kim F. J. Percutaneous nephrolithotomy versus retrograde intrarenal surgery: asystematic review and meta-analysis. European Urology. 2015; 67 (1): 125-137.

7. Basin A., Ziaee A. M., Kianian H. R., Mehrabi S., Karami H., Moghaddam S. M. Ultrasonographic versus fluoroscopic access for percutaneous nephrolithotomy: a randomized clinical trial. Journal of Endourology. 2008; 22 (2): 281-284. doi: 10.1089/end.2007.0141.

8. Qigek R., Dundar G., Gokcen K., Gokce G., Gultekin E. Y. The evaluation of morphology of renal pelvica-lyceal system's and infundibulopelvic anatomy of kidney's lower pole in post-mortem series. Folia morphologica. 2021; 81 (2): 350-358. doi: 10.5603/FM.a2021.0041.

9. Huang J., Lu S., Hu Z., Huang C., Li Y , Wei Q. Three-dimensional reconstruction of human kidney based on UroMedix-3D system and its application in kidney surgery. Nan Fang Yi Ke Da Xue Xue Bao. 2019; 39 (5); 614-620.

10. Keoghane S. R., Cetti R. J., Rogers A. E., Walmsley B. H. Blood transfusion, embolisation and nephrecto­ my after percutaneous nephrolithotomy. British Journal of Urology International. 2013; 111 (4): 628-632. doi: 10.1111/j.1464-410X.2012.11394.x.

11. Rupel E., Brown R. Nephroscopy with removal of stone following nephrostomy for obstructive calculous anuria. The Journal of Urology. 1941; 47: 177-182.

12. Spek A., Strittmatter F., Graser A., Kufer P., Stief C., Staehler M. Dual energy can accurately differentiate uric acid-containing urinary calculi from calcium stones. World Journal Urology. 2016; 34 (9): 297-302. doi: 10.1007/s00345-015-1756-4.