RU2134065C1 - Method of in-lifetime systemic computer visualization of organ vascular bed - Google Patents

Abstract

FIELD: roentgenology, angiology and angiomorphology for study of in-lifetime anatomy and topography of vascular systems of organs and one-moment systemic visualization of organ vascular beds. SUBSTANCE: method includes preparation of graphical computer files; coloring in different colors of in-lifetime images of different phases of blood flow; their graphic computer combination and processing with the help of computer programs. Method allows one-moment study of complex in-lifetime anatomy and topography of arterial, parenchymatous and venous parts of examined organ and possibility of visualization of dynamics of filling with blood of different parts and organ as a whole on the basis of obtained mixed colored image and intensity of coloring. EFFECT: higher efficiency. 4 dwg

Description

 The invention relates to medicine, in particular to radiology, angiology and angiotopomorphology, and can be used in the study of intravital anatomy and topography of the vascular system of internal organs.

 It is known that the outcomes in surgery of internal organs (brain and spinal cord, organs of the thoracic and abdominal cavity and retroperitoneal space) are determined primarily by the nature of the mechanical effect on the vascular system of the organ as a whole, and its individual parts that occur during surgical access, intraorgan and extraorgan surgical manipulations, performing resections of various volumes. In view of the above, it is necessary to know the anatomy and topography of extra- and intraorgan vessels, the state of the hemodynamics of the organ as a whole, the degree of blood supply to individual parts of the organs.

 There are various methods for studying the vascular bed of internal organs: morphological (the method of macroscopic preparation of injected and non-injected preparations of the internal organs of a human corpse; a method for studying the vascular bed on corrosive anatomical preparations of human corpses), X-ray anatomical (injection of radiopaque drugs into the vascular bed of a corpse organ followed by fixation on x-ray film), radiological (carotid, vertebral and spinal serially angiography, nuclear magnetic resonance angiography, aortography; mesentericoportal-tseliakoangiografiya; splenografiya; renografiya).

 The method of B.V. Ognev (Ognev V.V. "On the method of injection and study of blood vessels of the central and peripheral nervous system of a person", In the book: "Blood supply to the central and peripheral system of a person", 1950, p. 5-37) is based on the introduction of dyes (gelatin, mascara) of different colors into the vascular bed of the brain (separately into the arteries and veins), followed by macroscopic preparation. A similar methodology for the study of the human venous system was used by I.I. Kagan (Kagan II. "The venous system of the deep parts of the brain in normal and pathological conditions", 1968). In the method of D. B. Bekov and V.I. Shumileva (Bekov DB, Shumilyov VI "For use for injection of natural and synthetic latexes", "Archive of Anatomy", 1956, 1, pp. 81-87) instead of dyes, latex was introduced into the vascular bed of the organ. The method of D. A. Tkachenko (D. Tkachenko "Method for the manufacture of total corrosion preparations from butacryl plastic" Archive of Anatomy ", 1969, 8, pp. 77-79) is based on the introduction of rapidly hardening plastic (butacryl) into the vessels of the organ followed by passing through acids to obtain a vascular impression. D.I. Fried (D.I. Frid "Arterial blood supply to the pancreas". In the book: "Questions of surgical anatomy of the vascular-nervous system and tissue transplantation", 1958, pp. 205-215 ) used for the manufacture of corrosive preparations as hardening plas mass red sevanite (arterial vessels) and unpainted acrylate (venous vessels). The method of V.A. Votintsev (V. Votintsev "Differences in the external structure of the veins of the dura mater of the human brain and their applied value", 1963) is based on X-ray anatomical a technique for studying the vascular bed (introducing lead minium or barium sulfate into the vascular bed of a corpse, followed by registration on an x-ray).

 The disadvantages of the above methods, in our opinion, are the following points: 1) studies were performed on anatomical (cadaveric) preparations, which changes the intravital parameters of the studied structures; 2) the lack of simultaneous systemic visualization of the organ vascular bed.

 Closest to the proposed method are x-ray anatomical studies of the organ vascular bed, in particular various types of serial Seldinger angiography (carotid, vertebral, aortography, celiacography) and magnetic resonance imaging in combination with angiography. In the method Kornienko V.N. (Korinenko V.N. "Functional angiography", 1981) and M.V. Danilova (Danilov MV, Fedorov VD "Angiography in the book:" Surgery of the pancreas ", 1995, p. 203-212) in vivo study of the organ vascular bed is performed using transfemoral serial selective angiography according to Seldinger with the introduction of radiopaque preparations (verografin, ultravist, omnipack): carotid and vertebral - the brain; celiacography and upper mesentericography - the pancreas. Angiograms in the frontal and sagittal projections carry out time-discrete visualization of organ th vascular bed in the arterial, perchymatous (capillary) and venous phases of the blood flow.

 The disadvantage of the angiographic method, in our opinion, is to obtain an image of only separately the phases of the blood flow and the impossibility of simultaneous systemic visualization of the organ vascular bed.

 The novelty of the present invention is the graphic combination and processing of color images of the phases of intraorgan blood flow (arterial, parenchymal, venous) using computer programs to obtain images of the simultaneous system in vivo anatomy and topography of the vascular bed of human organs.

 Significant differences of the invention lies in the fact that they color monochrome serial images of the phases of organ blood flow with subsequent combination of graphic computer files of color images of the arterial, parenchymal and venous phases of the blood flow, where as a result of their graphic computer alignment, processing using computer programs and printing on a printer, synthesized simultaneous systemic image of the anatomy and topography of the organ vascular bed.

 The method is as follows. Monochrome images of successive phases of blood flow (arterial, parenchymal, venous) of the patient’s organ under study obtained by transfemoral serial selective intravital angiography according to Seldinger on a Multistar seriograph (Siemens, Germany) using 40% verographin and ultravist-300 in an amount of 40 -60 ml, are entered into the computer in the form of graphic files and painted in red, green and blue, respectively, angiographic phases of blood flow. Computer-aided combination of color images of the phases of blood flow. Computer processing is carried out using the following programs: AroSoft Photo Studio 1.5, CorelDro 7.0, FageMaker 6.5 or the like. The result of computer processing is a color image of the organ's vascular system printed on a printer.

 The developed method for intravital systemic visualization of the organ vascular bed was used by us to study the vessels of the brain and pancreas in patients who were examined (carotid angiography and celiacography) regarding the pathology of the above organs. As an example of using the method developed by us, we give a description of the obtained combined computer image of the vascular bed of the brain. The initial monochrome images of the arterial, parenchymal and venous phases of the cerebral blood flow in the sagittal projection (x-ray images, printer prints, photos, video images) (Fig. 1) obtained during angiographic examination of the patient are entered into the computer as graphic files and painted in red, green and blue colors, respectively, angiographic phases, resulting in color computer copies of different phases of blood circulation (Fig. 2). Subsequently, computer-aided combination of color images of the phases of blood flow was made (Fig. 3). In FIG. Figure 4 presents a one-stage systemic computer image of the vascular bed of the carotid basin of the brain (photographic prints of the arterial, parenchymal and venous phases of brain angiograms were scanned, the graphic files of which were colored red, green and blue, respectively, using the ArcSoft Photo Studio V1.5 computer program; produced the addition of image files using the program Corel Photo-Paint V7.0; the resulting image was printed using the program PageMaker 5.0), where visible at the same time but arterial vessels (1) and venous formation (2) and on the mixed color image can distinguish brain regions with fast (3) and slow blood flow (4).

 The method allows for the intravital and simultaneous synthesis of a complex picture of the anatomy and topography of the arterial, parenchymal and venous sections of the vascular bed of the organ under study, and the resulting mixed color image makes it possible to judge the dynamics of blood supply in both different departments and the organ under study as a whole.

Claims (1)

 A method of intravital systemic computer visualization of an organ vascular bed, including angiography of an organ under investigation, characterized in that monochrome serial images of phases of organ blood flow are stained with subsequent combination of graphic computer files of color images of arterial parenchymal and venous blood flow phases.

Images