Ultrasonographic images and correspondence with real color sectioned images of the upper limb.

PURPOSE: For basic training in ultrasonography (US), medical students and residents must learn cross-sectional anatomy. However, the present educational material is not sufficient to learn the sectional anatomy for US. This study aimed to provide a criterion for reading ambiguous structures on US images of upper limb through the sectioned images of Visible Korean. METHODS: US images of the right arm of a volunteer were scanned (28 planes). For comparison with US images, the sectioned images of the right upper limb (24 bits color, 0.5 mm intervals, 0.06 mm × 0.06 mm sized pixel) were used. After the volume model was constructed from the sectioned images using MRIcroGL, new sectioned images of 28 planes corresponding to the US images of 28 planes were created by adjusting the slope of the volume model. In all images, the anatomical terms of 59 structures from the shoulder to the fingers were annotated. RESULTS: In the atlas, which consists of 28 sets of US images and sectioned images of various slope planes, 59 structures of the shoulder, arm, elbow, wrist, palm, and fingers were observed in detail. CONCLUSION: We were able to interpret the ambiguous structures on the US images using the sectioned images with high resolution and actual color. Therefore, to learn the cross-sectional anatomy for US, the sectioned images from the Visible Korean project were deemed to be the suitable data because they contained all human gross anatomical information.

Visible Korean based on true color sectioned images for making realistic digital human, twenty years' record: a review.

PURPOSE: Visible Korean (VK) consists of two-dimensional (2D) images and three-dimensional (3D) models. The VK is used in various educational tools and research sources for anatomy. In this paper, we report on the records of the VK over 20 years. METHODS: Research papers related to Visible Korean were reviewed. RESULTS: Through this report of VK records, we highlighted the essential points for making true color and ultra-high-resolution sectioned images of human and animal bodies, for making various 2D and 3D applications from the sectioned images, and for good use of the sectioned images and their applications. CONCLUSION: In this metaverse age that various virtual environments are required in medical education and research, the VK dataset meets the reality of virtual human models as fundamental data owing to the actual color and high resolution of the VK dataset.

Lymph Node Stations of Pancreas Which Are Identified in Real Color Sectioned Images of a Cadaver With Pancreatic Cancer.

BACKGROUND: In pancreatic cancer surgery, anatomical understanding of lymph node metastases is required. Distinguishing lymph nodes in computed tomography or magnetic resonance imaging is challenging for novice doctors and medical students because of their small size and similar color to surrounding tissues. This study aimed to enhance our understanding of the clinical anatomy of lymph node stations relevant to pancreatic cancer using newly sectioned images of a cadaver with true color and high resolution and their three-dimensional (3D) models. METHODS: An 88-year-old female cadaver who died of pancreatic cancer was serially sectioned. Among the sectioned images of the whole body (0.05 mm-sized pixel, 48 bits color), images of the abdomen were selected, and examined to identify lymph nodes and nearby structures. 34 structures (9 in digestive system; 1 in urinary system; 2 in cardiovascular system; 22 in lymphatic system) were segmented on the sectioned images. Based on the sectioned and segmented images, volume and surface models were produced. RESULTS: Among the known 28 lymph node stations, 21 stations were identified through location, size, and color of normal and abnormal structures in the sectioned images and 3D models. Two near the splenic artery could not be separated from the cancer tissue, and the remaining five were not clearly identified. In the surface models, the shape and location of lymph node stations could be confirmed with nearby structures. CONCLUSION: The lymph node stations relevant to pancreatic cancer can be anatomically understood by using the sectioned images and 3D models which contain true color and high resolution.

A Novel Human Brainstem Map Based on True-Color Sectioned Images.

BACKGROUND: Existing atlases for the human brainstem were generated from magnetic resonance images or traditional histologically stained slides, but both are insufficient for the identification of detailed brainstem structures at uniform intervals. METHODS: A total of 319 sectioned images of the brainstem were selected from whole-body axial sectioned images, then coronal and sagittal sectioned images were reconstructed from the horizontal images. The fine and detailed structures were annotated in PowerPoint slides, then the volume model was produced and some white matter fibers were traced using MRIcroGL. RESULTS: In this study, a novel brainstem atlas based on sectioned images was generated that shows the true color and shape, as well as the accurate location of the nuclei and tracts; it reveals the striking contrast between gray and white matter, as well as fine structures. In total, 212 structures, including nuclei and tracts, were annotated in axial, coronal, and sagittal plane views of sectioned images (48-bit true color; 0.2 mm intervals, 0.06 mm × 0.06 mm pixel size). To verify the accuracy of the annotations, a volume model of the brainstem was constructed for independent observations of the three planes. CONCLUSION: In this paper, we describe several interesting structures included in the atlas. By depicting the fine structures of the human brainstem in detail, this atlas allows comprehensive understanding of the complicated topographies of the brainstem. As such, it will be of value for neuroanatomy education and research, in addition to enriching the literature on the human brain.

Advanced-sectioned images obtained by microsectioning of the entire male body.

Realistic two-dimensional (2D) and three-dimensional (3D) applications for anatomical studies are being developed from true-colored sectioned images. We generated advanced-sectioned images of the entire male body and verified that anatomical structures of both normal and abnormal shapes could be visualized in them. The cadaver was serially sectioned at constant intervals using a cryomacrotome. The sectioned surfaces were photographed using a digital camera to generate horizontal advanced-sectioned images in which normal and abnormal structures were classified. Advanced-sectioned images of the entire male body were generated. The image resolution was 3.3 × 3.3 fold better than that of the first sectioned images obtained in 2002. In the advanced-sectioned images, normal and abnormal structures ranging from microscopic (≥0.06 mm × 0.06 mm; pixel size) to macroscopic (≤473.1 mm × 202 mm; body size) could be identified. Furthermore, the real shapes and actual sites of lung cancer and lymph node enlargement were ascertained in them. Such images will be useful because of their true color and high resolution in digital 2D and 3D applications for gross anatomy and clinical anatomy. In future, we plan to generate new advanced-sectioned images of abnormal cadavers with different diseases for clinical anatomy studies.

Movable surface models of hand joints using visible korean / Modelos de superficies móviles de articulaciones de manos utilizando visible Korean

SUMMARY: The human hand can make precise movements utilizing several joints of various articular types. To understand hand movements more accurately, it is essential to view the actual movements of bones and muscles considering the X, Y, and Z axes in the joints. This study aimed to investigate the joint movements in a hand using movable surface models, including these axes. These movable surface models of the hand will improve medical students' understanding of hand movements around the joints. To achieve this aim, 70 surface models were adopted from a Visible Korean model. Using Maya software, 20 virtual joints with X, Y, and Z axes included nine distal and proximal interphalangeal joints, five metacarpophalangeal joints, five carpometacarpal joints, and one wrist joint were created. Bone surface models were elaborately polished to maintain their original shape during movement. Muscle surface models were also processed to display the deformation of the muscle shape during movement. The surface models of the hand joints were moved by virtual control of the joints. We saved 87 movable surface models of the hand, including bones, muscles, and joint axes in stereolithography format, and compiled a Portable Document Format (PDF) file. Using the PDF file, the joint movements in a hand could be observed considering the X, Y, and Z axes alongside the stereoscopic shapes of the bones and muscles. These movable surface models of the hand will improve medical students' understanding of hand movements around the joints.

RESUMEN: La mano humana puede realizar movimientos precisos utilizando varias articulaciones de diferentes tipos articulares. Para comprender los movimientos de las manos con mayor precisión, es esencial ver los movimientos reales de los huesos y los músculos considerando los ejes X, Y y Z de las articulaciones. Este estudio tuvo como objetivo investigar los movimientos articulares en una mano utilizando modelos de superficies móviles, incluidos estos ejes. Estos modelos de superficie móvil de la mano mejorarán la comprensión de los estudiantes de medicina de los movimientos de la mano alrededor de las articulaciones. Para lograr este objetivo, se adoptaron 70 modelos de superficie de un modelo coreano visible. Con el software Maya, se crearon 20 articulaciones virtuales con ejes X, Y y Z que incluyeron nueve articulaciones interfalángicas distales y proximales, cinco articulaciones metacarpofalángicas, cinco articulaciones carpometacarpianas y una articulación de muñeca. Los modelos de superficie ósea se pulieron minuciosamente para mantener su forma original durante el movimiento. También se procesaron modelos de superficie muscular para mostrar la deformación de la forma del músculo durante el movimiento. Los modelos de superficie de las articulaciones de las manos se movieron mediante el control virtual de las articulaciones. Guardamos 87 modelos de superficies móviles de la mano, incluidos huesos, músculos y ejes articulares en formato de estereolitografía, y compilamos un archivo en formato de documento portátil (PDF). Usando el archivo PDF, los movimientos de las articulaciones en una mano se pueden observar considerando los ejes X, Y y Z junto con las formas estereoscópicas de los huesos y músculos. Estos modelos de superficie móvil de la mano mejorarán la comprensión de los estudiantes de medicina sobre los movimientos de la mano alrededor de las articulaciones.

Real color volume model of cadaver for learning cardiac computed tomographs and echocardiographs.

PURPOSE: It is difficult for medical students and novice clinicians to interpret cardiac computed tomographs and echocardiographs. This study was intended to help familiarize them with the clinical images of the heart by providing software to browse the various planes of a heart's volume model with real color and high resolution. METHODS: On the sectioned images of a male cadaver, the heart and adjacent structures were segmented to obtain color-filled images. Volume models of the sectioned images and color-filled images were reconstructed and sectioned to obtain three orthogonal planes and five standard oblique planes. The planes were inputted into lab-made browsing software, which was then distributed free of charge. RESULTS: Users of the software would hopefully progress as follows. After experiencing the real color and high resolution, they would become familiar with the grayscale and low resolution. After experiencing the automatic annotation of the basic heart structures, they would become familiar with the detailed structures. After experiencing the designated planes, they would become familiar with the arbitrary planes. After experiencing the still heart, they would become familiar with the moving heart during echocardiography. CONCLUSION: The software, with a user-friendly interface and realistic features, is expected to properly orient medical novices to cardiac computed tomography and echocardiography images.

Peeled images and sectioned images from real-color volume models of foot.

PURPOSE: In all educational materials, the foot cannot be peeled from skin to the bone at constant intervals, like as real dissection. The aim of this study was to produce the peeled images which the foot structures can be peeled gradually along a skin-curved surface in real color, like a real dissection. In addition, the sectioned images of typical and atypical planes are presented in real color and high resolution. METHODS: From the sectioned images of real color, foot volume models were made using Photoshop, Matlab, and MRIcroGL. Peeled images and sectioned images of the typical planes were produced from the volume models. All images were placed into the browsing software. An atypical plane could be shown in a real-time using the volume models of the foot. RESULTS: Using the peeled images, in which the foot can be rotated at 5-degree intervals and stripped gradually at 0-30 mm depth, the foot anatomy could be learned precisely and efficiently. The sectional anatomy of the foot for radiology and orthopedic surgery could also be learned easily using the sectioned images of typical (horizontal, coronal, and sagittal) and atypical planes. CONCLUSION: The most significant merit of the volume models is that all outcomes can be displayed with proper colors of the body structures on any plane. By virtue of these merits, the volume models are useful for learning medical education, research, and clinical practice.

Sectioned and segmented images of the male whole body, female whole body, male head, and female pelvis from the Visible Korean.

In the Visible Korean, serially sectioned images with real color and high resolution have been prepared from four cadaveric subjects: male whole body, female whole body, male head, and female pelvis. Recently, segmented images of the female whole body were manufactured, permitting the distribution of the complete four data sets. The purpose of this report was to promote the applications of sectioned and segmented images from the Visible Korean by announcing them. Reduced image data were loaded to self-developed browsing software; using the browsing software, the contents could be quickly grasped and evaluated by other investigators. The four data sets were compared to disclose the individual merits and demerits. The sectioned and segmented images showed the possibility to be used to reconstruct the stereoscopic volume and surface models of body structures. The Visible Korean is expected to contribute to the interactive simulation of medical learning and clinical practice.

Portable Document Format File Containing the Schematics and Operable Surface Models of the Head Structures.

BACKGROUND: A book entitled "Visually Memorable Regional Anatomy (VMRA)" consists of extremely schematic figures as well as concise anatomic knowledge. On the other hand, in the Visible Korean (VK) project, three-dimensional surface models of 297 head structures have been reconstructed. The study's objective was to verify how the coexistence of the schematic figures and realistic surface models affected anatomy learning. METHODS: In the portable document format (PDF) file of VMRA, 19 pages of the surface models of the head from the PDF file of VK were embedded. The resultant PDF file was utilized as a learning tool of the medical students in two universities. RESULTS: The PDF file could be downloaded free of charge from anatomy.co.kr. The PDF file has been accessed by users from multiple countries including Korea, United States, and Hungary. In the PDF file, the surface models could be selected in any combinations, magnified, freely rotated, and compared to the corresponding schematics. The number of hours that the PDF file was used by medical students and the scores of written examination on the PDF file showed a low positive correlation in a university. The students replied that the combined PDF file was helpful for understanding anatomy and for doing cadaver dissection. They were also satisfied with the convenience of comparing the surface models and schematics. CONCLUSION: The freely obtainable PDF file would be a beneficial tool to help students learn anatomy easily, interactively, and accurately.

Dawn of the Visible Monkey: Segmentation of the Rhesus Monkey for 2D and 3D Applications.

BACKGROUND: To properly utilize the sectioned images in a Visible Monkey dataset, it is essential to segment the images into distinct structures. This segmentation allows the sectioned images to be compiled into two-dimensional or three-dimensional software packages to facilitate anatomy and radiology education, and allows them to be used in experiments involving electromagnetic radiation. The purpose of the present study was to demonstrate the potential of the sectioned images using the segmented images. METHODS: Using sectioned images of a monkey's entire body, 167 structures were segmented using Adobe Photoshop. The segmented images and sectioned images were packaged into the browsing software. Surface models were made from the segmented images using Mimics. Volume models were made from the sectioned images and segmented images using MRIcroGL. RESULTS: In total, 839 segmented images of 167 structures in the entire body of a monkey were produced at 0.5-mm intervals (pixel size, 0.024 mm; resolution, 8,688 × 5,792; color depth, 24-bit color; BMP format). Using the browsing software, the sectioned images and segmented images were able to be observed continuously and magnified along with the names of the structures. The surface models of PDF file were able to be handled freely using Adobe Reader. In the surface models, the space information of all segmented structures was able to be identified using Sim4Life. On MRIcroGL, the volume model was able to be browsed and sectioned at any angle with real color. CONCLUSION: Browsing software, surface models, and volume models are able to be produced based on the segmentation of the sectioned images. These will be helpful for students and researchers studying monkey anatomy and radiology, as well as for biophysicists examining the effects of electromagnetic radiation.

Whole course of pallidothalamic tracts identified on the sectioned images and surface models.

The anatomy of the pallidothalamic tracts, including the ansa lenticularis, lenticular fasciculus, and thalamic fasciculus (field H1 of Forel), should be elucidated by neurosurgeons and neuroscientists who study deep brain stimulation. In this study, serially sectioned images of a human cadaver head were employed to overcome the limitations of existing methods to observe the pallidothalamic tracts. Owing to the high resolution and real color of the sectioned images, 28 structures, including the pallidothalamic tracts and mammillothalamic fasciculus, were identified. The structures were segmented and made into surface models, which are helpful in improving the stereoscopic understanding. Observing the sectioned images and surface models may help in understanding the detailed anatomy of the pallidothalamic tracts. The new findings, such as the spatial relationship of the tracts, were summarized in a schematic figure. Moreover, to elucidate the anatomical structures along the course of deep brain stimulation, virtual electrodes were inserted into the surface models. The sectioned images and surface models of this study are expected to enhance the understanding of the pallidothalamic tract anatomy. A portable document format file containing the surface models and the sectioned images can be freely downloaded from the authors' homepage. Clin. Anat. 32:66-76, 2019. © 2019 Wiley Periodicals, Inc.

Four learning tools of the Visible Korean contributing to virtual anatomy.

PURPOSE: The sectioned images of a male's whole body were used for making the four learning tools: the first tool to show the sectioned and color-filled images; the second tool to show surface models of individual structures; the third tool to show a volume model that was continuously peeled; the fourth tool to show a volume model that was freely sectioned. This study was intended to propose the possible learning effects of the four tools. METHODS: The fourth tool that was recently developed to facilitate oblique sectioning and rotation of the volume model in real time. RESULTS: The four learning tools had their own characteristics, so that they could be separately used for specific achievements. Further, the combination of the tools based on the same raw data may result in a synergic effect. All the tools can be downloaded from the Visible Korean homepage (anatomy.co.kr) gratis. CONCLUSIONS: With the four learning tools, students may experience virtual dissection simulation regardless of the place, time, or economic status. Such free learning tools and commercial learning tools need to be improved to compensate and compete with each other.

Peeled volume models of a whole body to enhance comprehension of anthropological bone landmarks.

BACKGROUND: In physical anthropology, bone landmarks are palpated in living humans for the identification of corresponding skin landmarks and exact biometry. The purpose of this study is to help comprehend the locations and depths of representative bone landmarks all over the body. MATERIALS AND METHODS: The sectioned images of a male cadaver's whole body were used to build a volume model, which was continuously peeled at 1 mm thicknesses to disclose 27 selected landmarks in the anterior, lateral, or posterior views. RESULTS: The captured views of peeled volume models along with the labels of the bone landmarks were loaded to browsing software that was distributed for free. The browsing software containing the peeled volume models will enhance convenient studying of the bone landmarks. CONCLUSIONS: With the knowledge of bone landmarks, investigators would be able to attain more accurate measurements between skin landmarks.

Real-Color Volume Models Made from Real-Color Sectioned Images of Visible Korean.

BACKGROUND: Volume models made from magnetic resonance images on computed tomographs can produce horizontal, coronal, sagittal, and oblique planes that are used widely in clinics, although detailed structures cannot be identified. Existing real color volume models are mostly commercial and their production methods have not been released. The aim of this study was to distribute free of charge, real-color volume models produced from sectioned images with the production method. METHODS: The original voxel size of sectioned images was increased appropriately so that the volume model could be handled by typical personal computers. By using Dicom Browser and MRIcroGL, the sectioned images were processed to become the volume models. RESULTS: On the MRIcroGL, the resultant volume model with the voxel size of 0.5 × 0.5 × 0.5 mm3 could be displayed and freely rotated. By adjusting variables of the software, desired oblique planes could be produced instantly. With overlay function, a model of segmented structure can be overlapped to the entire volume models. The sectioned images with high quality and the segmentation data of Visible Korean enabled the identification of detailed anatomical structures on the planes. CONCLUSION: The volume models can be used by medical students and doctors for learning sectional anatomy. Other researchers can utilize the method of this study to produce volume models from their own sectioned images.

New Viewpoint of Surface Anatomy Using the Curved Sectional Planes of a Male Cadaver.

BACKGROUND: The curved sectional planes of the human body can provide a new approach of surface anatomy that the classical horizontal, coronal, and sagittal planes cannot do. The purpose of this study was to verify whether the curved sectional planes contribute to the morphological comprehension of anatomical structures. METHODS: By stacking the sectioned images of a male cadaver, a volume model of the right half body was produced (voxel size 1 mm). The sectioned images with the segmentation data were also used to build another volume model. The volume models were peeled and rotated to be screen captured. The captured images were loaded on user-friendly browsing software that had been made in the laboratory. RESULTS: The browsing software was downloadable from the authors' homepage (anatomy.co.kr). On the software, the volume model was peeled at 1 mm thicknesses and rotated at 30 degrees. Since the volume models were made from the cadaveric images, actual colors of the structures were displayed in high resolution. Thanks to the segmentation data, the structures on the volume model could be automatically annotated. Using the software, the sternocleidomastoid muscle and the internal jugular vein in the neck region, the cubital fossa in the upper limb region, and the femoral triangle in the lower limb region were observed to be described. CONCLUSION: For the students learning various medical procedures, the software presents the needed graphic information of the human body. The curved sectional planes are expected to be a tool for disciplinary convergence of the sectional anatomy and surface anatomy.

New Viewpoint of Surface Anatomy Using the Curved Sectional Planes of a Male Cadaver

BACKGROUND: The curved sectional planes of the human body can provide a new approach of surface anatomy that the classical horizontal, coronal, and sagittal planes cannot do. The purpose of this study was to verify whether the curved sectional planes contribute to the morphological comprehension of anatomical structures. METHODS: By stacking the sectioned images of a male cadaver, a volume model of the right half body was produced (voxel size 1 mm). The sectioned images with the segmentation data were also used to build another volume model. The volume models were peeled and rotated to be screen captured. The captured images were loaded on user-friendly browsing software that had been made in the laboratory. RESULTS: The browsing software was downloadable from the authors' homepage (anatomy.co.kr). On the software, the volume model was peeled at 1 mm thicknesses and rotated at 30 degrees. Since the volume models were made from the cadaveric images, actual colors of the structures were displayed in high resolution. Thanks to the segmentation data, the structures on the volume model could be automatically annotated. Using the software, the sternocleidomastoid muscle and the internal jugular vein in the neck region, the cubital fossa in the upper limb region, and the femoral triangle in the lower limb region were observed to be described. CONCLUSION: For the students learning various medical procedures, the software presents the needed graphic information of the human body. The curved sectional planes are expected to be a tool for disciplinary convergence of the sectional anatomy and surface anatomy.

Real-Color Volume Models Made from Real-Color Sectioned Images of Visible Korean

BACKGROUND: Volume models made from magnetic resonance images on computed tomographs can produce horizontal, coronal, sagittal, and oblique planes that are used widely in clinics, although detailed structures cannot be identified. Existing real color volume models are mostly commercial and their production methods have not been released. The aim of this study was to distribute free of charge, real-color volume models produced from sectioned images with the production method. METHODS: The original voxel size of sectioned images was increased appropriately so that the volume model could be handled by typical personal computers. By using Dicom Browser and MRIcroGL, the sectioned images were processed to become the volume models. RESULTS: On the MRIcroGL, the resultant volume model with the voxel size of 0.5 × 0.5 × 0.5 mm3 could be displayed and freely rotated. By adjusting variables of the software, desired oblique planes could be produced instantly. With overlay function, a model of segmented structure can be overlapped to the entire volume models. The sectioned images with high quality and the segmentation data of Visible Korean enabled the identification of detailed anatomical structures on the planes. CONCLUSION: The volume models can be used by medical students and doctors for learning sectional anatomy. Other researchers can utilize the method of this study to produce volume models from their own sectioned images.

Automatic 3D modeling of liver segments including segmental branches of portal triad and hepatic vein based on the sectioned-images / Modelado 3D automático de segmentos hepáticos, con las ramas segmentarias de la tríada portal y la vena hepática basadas en las imágenes seccionadas

SUMMARY: The liver dimensional (3D) models, consists of eight segments including portal triad (portal vein, hepatic artery, and bile duct), are necessary because it is difficult to dissect a liver and its inner structures. But it is difficult to produce 3D models from high resolution and color sectioned-images. This study presents automatic and accurate methods for producing liver 3D models from the sectionedimages. Based on the sectioned-images and color-filled-images of the liver, a 3D model including both the portal triad and hepatic vein was made. Referring to the 3D model, 3D models of liver's eight segments including the segmental branches of the portal triad and hepatic vein were completed and saved as STL format. All STL files were combined and saved as Liver-3D in PDF format for the common user. By functional subdivision of liver, the Liver-3D was divided into left (segments II, III, and, IV) and right (segments V, VI, VII, and VIII) liver in bookmark window of the PDF file. In addition, in Liver-3D, the primary to tertiary segmental branches of the portal triad could be shown in different colors. Owing to the difficulty of 3D modeling of liver including eight segments and segmental branches of the portal triad and hepatic, we started this research to find automatic methods for producing 3D models. The methods for producing liver 3D models will assist in 2D selection and 3D modeling of other complicated structures.

RESUMEN: Los modelos hepáticos dimensionales (3D) consisten en ocho segmentos que incluyen la tríada portal (vena porta, arteria hepática y conducto biliar), y son necesarios ya que es difícil disecar un hígado y sus estructuras internas. Sin embargo, es difícil producir modelos 3D a partir de imágenes en alta resolución e imágenes seccionadas en color. Este estudio presenta métodos automáticos y precisos para producir modelos 3D de hígado a partir de las imágenes seccionadas. Sobre la base de las imágenes seccionadas y las imágenes del hígado llenas de color, se realizó un modelo 3D que incluía tanto la tríada portal como la vena hepática. En referencia al modelo 3D, se completaron modelos 3D de los ocho segmentos del hígado que incluían las ramas segmentarias de la tríada portal y la vena hepática y se guardaron como formato STL. Todos los archivos STL fueron combinados y guardados como Liver-3D en formato PDF para el usuario común. Por subdivisión funcional del hígado, el hígado-3D se dividió en hígado izquierdo (segmentos II, III y IV) y derecho (segmentos V, VI, VII y VIII) en la ventana de marcador del archivo PDF. Además, en Liver-3D, las ramas segmentarias primarias a terciarias de la tríada portal podrían mostrarse en diferentes colores. Debido a la dificultad del modelado 3D del hígado, incluidos ocho segmentos y ramas segmentarias de la tríada portal y hepática, comenzamos esta investigación para encontrar métodos automáticos para producir modelos 3D. Los métodos para producir modelos 3D de hígado ayudarán en la selección 2D y el modelado 3D de otras estructuras complicadas.

Sectioned images of a cat head to contribute to learning of its sectional anatomy / Imágenes seccionadas de una cabeza de gato para contribuir al conocimiento de su anatomía seccional

The sectional anatomy of a cat head is essential when interpreting CTs and MRIs of the region. In learning the sectional anatomy, sectioned images of a cat could be quite effective data. The main objective was to assist veterinary physicians who learn the sectional anatomy of a cat head by presenting high-quality sectioned images. A short-haired female cat was frozen and sectioned frontally using a cryomacrotome. Every sectioned surface in real body color was photographed with a digital camera. The frontal planes were stacked to produce dorsal and sagittal planes. High-quality sectioned images of a cat head allowed the identification of small, complicated structures. The notable structures were as follows: each bone of the cranium, structures of the brain, tympanic cavity (larger than human), oval window (larger than human), vestibular nerve, cochlear nerve, ear ossicles, six extraocular muscles, pupil (larger than human), retractor bulbi muscle (not found in human), optic nerve, olfactory bulb (considerably large), vomeronasal organ duct (not found in human), infraorbital gland (not found in human), masticatory muscles (larger than human), maxillary nerve (larger than human), and mandibular nerve. This pacesetting report describes the detailed head structures of a cat from the viewpoint of sectional anatomy. The sectioned images will be given to other interested researchers free of charge.

El conocimiento de la anatomía seccional de cabeza de gato es esencial para interpretar estudios por tomografía computada y resonancia magnética de la región. En el conocimiento de esta anatomía seccional, las imágenes seccionadas de un gato podrían aportar datos bastante efectivos. El objetivo principal consistió en ayudar a los médicos veterinarios para que aprendan la anatomía seccional de una cabeza de gato mediante la presentación de imágenes seccionadas de alta calidad. Una gata de pelo corto fue congelada y seccionada frontalmente usando un criomicrótomo. Cada sección, con el color real del cuerpo, fue fotografiada con una cámara digital. Los planos frontales se apilaron para producir planos dorsales y sagitales. Las imágenes seccionadas de alta calidad de una cabeza de gato permitieron la identificación de estructuras pequeñas y de dificil visualización. Las estructuras destacadas fueron las siguientes: cada hueso del cráneo, las estructuras del cerebro, la cavidad timpánica (más grande que en el humano), la ventana oval (más grande que en el humano), el nervio vestibular, el nervio coclear, los huesecillos del oído, seis músculos extraoculares, la pupila, el músculo retractor del ojo (no se encuentra en el ser humano), nervio óptico, bulbo olfatorio (considerablemente grande), conducto del órgano vomeronasal (no se encuentra en el ser humano), glándula infraorbitaria (no se encuentra en los humanos), músculos masticatorios (más grandes que en el humano), nervio maxilar (más grande que en el humano) y nervio mandibular. En este trabajo describimos detalladamente, desde el punto de vista de la anatomía seccional, las estructuras de la cabeza de un gato. Las imágenes seccionadas estarán a disponibles para otros investigadores en forma gratuita.