CASE OF SUCCESSFUL APPLICATION OF METHOD FOR 3D VISUALIZATION AND MODELING IN THORACIC ONCOLOGY

Aim. The application of method of 3D-visualization and modeling in thoracic oncology is described.

Materials and methods. The block diagram of system of 3D-visualization and modeling consisting of six stages is shown. The reconstructions of anatomic computer 3D-models of rib cage and tumor were performed for the patient with cancer (plasma cell myeloma). The tumor size and its topographic anatomy relatively to neighboring organs, bones and soft tissues were identified.

Results.The obtained data had been used to plan surgical intervention, which was successfully conducted at Thoracic surgery department ofTomskRegionalClinicalHospital. 

1. Atlas operacij pri zlokachestvennykh opukholjakh legkogo, trakhei i sredostenija [Surgery Atlas in cases of malignant tumors of the lung, trachea and mediastinum]. A.Kh. Trakhtenberg; pod red. V.I. Chissova, A.Kh. Trakhtenberga, A.D. Kaprina. M.: Prakticheskaja medicina Publ. 2014. 184 p. (in Russian).

2. Vishnevskij A.A., Rudakov S.S., Milanov N.O. Khirurgija grudnoj stenki: Rukovodstvo [Thoracic cage surgery: Guidance]. M., Izdatel‘skij dom Vidar-M Publ. 2005, 312 p. (in Russian).

3. Teplyakov V.V., Karpenko V.Ju., Iljushin A.L. i dr. Khirurgicheskoe lechenie zlokachestvennykh opukholej grudnoj stenki [Surgical treatment of malignant tu mors in thoracic cage]. Khirurgija, 2010, no. 9, pp. 36–41 (in Russian).

4. Topolnitskiy E.B., Dambaev G.Ts., Gunter V.E. Zameshchenie postrezektsionnykh defektov anatomicheskikh struktur grudnoy kletki tkanevym implantatom na osnove nanostrukturnoy nikelid-titanovoy niti [Replacement of post-resection defects of anatomical structures of the chest with the tissue implant based on nanostructured titanium nickel alloy thread]. Khirurgija, 2011, no. 10, pp. 47–53 (in Russian).

5. Khirurgija daleko zashedshikh i oslozhnennykh form raka legkogo [Surgical treatment of complicated forms of lung cancer] / pod red. L.N. Bisenkova. St-Peterburg, DEAN Publ. 2006, p. 432 (in Russian).

6. Deschamps C., Tirnaksiz B.M., Darbandi R. et al. Early and long-term results of prosthetic chest wall reconstruction // The Journal of Thoracic and Cardiovascular Surgery. 1999. V. 117(3). P. 588–592.

7. Weyant M.J., Bains M.S., Venkatraman E. et al. Results of chest all resection and reconstruction with and without rigid prosthesis // Ann. Thorac. Surg. 2006. V. 81. P. 279–285.

8. Litschko P., Henning T., Beinemann J., Fried W., Linss W. Method for generating patient-specific implants. United States patent US 6,932,842. 2005.

9. Polinski M.J., Berg P.M. Integrated Production of Patient-Specific Implants and Instrumentation. United States patent application US 12/712,827. 2010.

10. Metzger R., Uthgenannt B.A., Fox D.A., May B.M. Patient-Specific Implants. United States patent US 20,110,046,735. 2011.

11. Pianykh O.S. Digital imaging and communications in medicine (DICOM): a practical introduction and survival guide. Springer Science & Business Media, 2009. 417 p.

12. Mildenberger P., Eichelberg M., Martin E. Introduction to the DICOM standard // European radiology. 2002. V. 12(4). P. 920–927.

13. Graham R.N., Perriss R.W., Scarsbrook A.F. DICOM demystified: a review of digital file formats and their use in radiological practice // Clinical radiology. 2005. V. 60(11). P. 1133-1140.

14. Russ J.C. The Image Processing Handbook, Seventh Edition. CRC Press, 2016. P. 1035.

15. Jahne В. Practical Handbook on Image Processing for Scientific and Technical Applications, Second Edition. CRC Press, 2004. P. 610.

16. Bankman I. Handbook of Medical Image Processing and Analysis. Academic Press, 2008. P. 1000.

17. Dougherty G., Medical Image Processing: Techniques and Applications. Springer Science & Business Media, 2011. P. 380.

18. Pieper S., Halle M., Kikinis R. 3D Slicer // Biomedical Imaging: Nano to Macro. 2004. IEEE International Symposium. P. 632–635.