Jump to content

Search the Community

Showing results for tags 'medical 3d printable'.



More search options

  • Search By Tags

    Type tags separated by commas.
  • Search By Author

Content Type


Blogs

  • Embodi3d Test Blog
  • 3D Printing in Medicine
  • Cool Medical 3D-Printing
  • 3D Bio Printing by Paige Anne Carter
  • SSchoppert's Blog
  • Additive Manufacturing in Medicine
  • biomedical 3D printing
  • Bryce's Blog
  • Chris Leggett
  • 3D Models Help Improve Surgical Precision, Reduce Operating Time
  • Desktop 3D Printing in Medical Imaging
  • 3D Printing: Radiology corner
  • The Embodi3D.com Blog
  • descobar3d's Blog
  • 3D Printing in Anthropology
  • Learn to 3D Print: Basic Tools from software to printers
  • 3D printing for bio-medicine
  • 3D Biomedical Printing - by Jacob M.
  • Valchanov's Blog
  • Deirdre_Manion-Fischer's Blog
  • Matt Johnson's Biomedical 3D Printing Blog
  • Devarsh Vyas's Biomedical 3D Printing Blogs
  • Devarsh Vyas's Biomedical 3D Printing Blogs
  • Mike at Medical Models
  • TOP TEN THE MOST DOWNLOADED EMBODI3D

Forums

  • Biomedical 3D Printing
    • Hardware and 3D Printers
    • democratiz3D®
    • Software
    • Clinical applications
    • 3D Printable Models
    • Medical Imaging: CT, MRI, US
    • Science and Research
    • News and Trending Topics
    • Education, Conferences, Meetings, Events
  • General
    • Announcements
    • Questions and Answers
    • Suggestions and Feedback
    • Member Lounge (members only)
  • Classifieds, Goods and Services
    • General Classifieds - members post free
    • Services needed
    • Services offered
    • Stuff for sale/needed
    • Post a Job
    • Looking for work - visible only to members

Categories

  • democratiz3D® Processing
  • Bones
    • Skull and Head
    • Dental, Orthodontic, Maxillofacial
    • Spine and Pelvis
    • Extremity, Upper (Arm)
    • Extremity, Lower (Leg)
    • Thorax and Ribs
    • Whole body
    • Skeletal tumors, fractures and bony pathology
  • Muscles
    • Head and neck muscles
    • Extremity, Lower (Leg) Muscles
    • Extremity, Upper (Arm) Muscles
    • Thorax and Ribs Muscles
    • Abdomen and Pelvis muscles
    • Whole body Muscles
    • Muscular tumors and sarcomas
  • Cardiac and Vascular
    • Heart
    • Congenital Heart Defects
    • Aorta
    • Mesenteric and abdominal arteries
    • Veins
  • Organs of the Body
    • Brain and nervous system
    • Kidneys
    • Lungs
    • Liver
    • Other organs
  • Skin
  • Veterinary
    • Dogs
    • Cats
    • Other
  • Science and Research
    • Paleontology
    • Anthropology
    • Misc Research
  • Miscellaneous
    • Formlabs
  • Medical CT Scan Files
    • Skull, Head, and Neck CTs
    • Dental, Orthodontic, Maxillofacial CTs
    • Thorax and Ribs CTs
    • Abdomen and Pelvis CTs
    • Extremity, Upper (Arm) CTs
    • Extremity, Lower (Leg) CTs
    • Spine CTs
    • Whole Body CTs
    • MRIs
    • Ultrasound
    • Veterinary/Animals
    • Other

Product Groups

  • Premium Services
  • Physical Print Quotes

Find results in...

Find results that contain...


Date Created

  • Start

    End


Last Updated

  • Start

    End


Filter by number of...

Joined

  • Start

    End


Group


Name


Secondary Email Address


Interests

Found 155 results

  1. Version 1.0.0

    5 downloads

    There are twelve pairs of ribs which are separated by the intercostal spaces. The upper 7 ribs show increase on length progressively while the lower 5 ribs show gradual decrease in length. The ribs could be: true the first 7 ribs that attach to the sternum directly false from 8th to 10th that attach to the sternum through costal cartilage floating the 11th and 12th with no articulation to the sternum This model shows pieces of the related vertebral bodies as well the sternum, clavicle and scapula. This 3D model was created from the file STS_040 The original CT examination can be reviewed at:

    Free

  2. Version 1.0.0

    4 downloads

    There are twelve pairs of ribs which are separated by the intercostal spaces. The upper 7 ribs show increase on length progressively while the lower 5 ribs show gradual decrease in length. The ribs could be: true the first 7 ribs that attach to the sternum directly false from 8th to 10th that attach to the sternum through costal cartilage floating the 11th and 12th with no articulation to the sternum This model shows pieces of the related vertebral bodies as well the sternum, clavicle and scapula. This 3D model was created from the file STS_040 The original CT examination can be reviewed at:

    Free

  3. Version 1.0.0

    18 downloads

    Whole body: chest, abdomen and pelvis The chest wall (thoracic cage) is composed by twelve pairs of ribs laterally and the sternum anteriorly. The ribs are attached to the dorsal vertebrae (thoracic spine) posteriorly and along their costal cartilage to the sternum. The thoracic cage main function is to protect the vital chest organs such as the heart and lungs. The cervical spine is the upper most spines forming the spinal column, extending from the skull base to the level of the thoracic vertebra (the spines with attached ribs). The cervical spines are usually seven and the main function is to support the skull and to protect the spinal cord. The dorsal (thoracic) spine forms the middle portion of the vertebral column extending below the seventh cervical vertebra to above the first lumbar vertebra. The dorsal spine is formed by twelve vertebral bodies. The vertebrae forming the dorsal spine are unique in shape as they are the only vertebral bodies articulating with ribs. The lumbar spine represents the mid-lower segment of the vertebral column and is composed of five adjacent vertebrae. They are convex anteriorly to form a lumbar lordosis. The lumbar spine facet joints allows limited movements and rotation. The bony pelvis is formed by 4 bones; a pair of hip bones, the sacrum and the coccyx. The bony pelvis supports the pelvic viscera and works to transmit force from the axial skeleton to the lower limbs. The two hip bones are related anteriorly by the symphysis pubis and posteriorly to the sacroiliac joints bilaterally. This 3D model was created from the file STS_040 The original CT examination can be reviewed at: The 3D muscle model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  4. Version 1.0.0

    17 downloads

    Whole body: chest, abdomen and pelvis The chest wall (thoracic cage) is composed by twelve pairs of ribs laterally and the sternum anteriorly. The ribs are attached to the dorsal vertebrae (thoracic spine) posteriorly and along their costal cartilage to the sternum. The thoracic cage main function is to protect the vital chest organs such as the heart and lungs. The cervical spine is the upper most spines forming the spinal column, extending from the skull base to the level of the thoracic vertebra (the spines with attached ribs). The cervical spines are usually seven and the main function is to support the skull and to protect the spinal cord. The dorsal (thoracic) spine forms the middle portion of the vertebral column extending below the seventh cervical vertebra to above the first lumbar vertebra. The dorsal spine is formed by twelve vertebral bodies. The vertebrae forming the dorsal spine are unique in shape as they are the only vertebral bodies articulating with ribs. The lumbar spine represents the mid-lower segment of the vertebral column and is composed of five adjacent vertebrae. They are convex anteriorly to form a lumbar lordosis. The lumbar spine facet joints allows limited movements and rotation. The bony pelvis is formed by 4 bones; a pair of hip bones, the sacrum and the coccyx. The bony pelvis supports the pelvic viscera and works to transmit force from the axial skeleton to the lower limbs. The two hip bones are related anteriorly by the symphysis pubis and posteriorly to the sacroiliac joints bilaterally. This 3D model was created from the file STS_040 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  5. Version 1.0.0

    7 downloads

    Whole body: chest, abdomen and pelvis The chest wall (thoracic cage) is composed by twelve pairs of ribs laterally and the sternum anteriorly. The ribs are attached to the dorsal vertebrae (thoracic spine) posteriorly and along their costal cartilage to the sternum. The thoracic cage main function is to protect the vital chest organs such as the heart and lungs. The cervical spine is the upper most spines forming the spinal column, extending from the skull base to the level of the thoracic vertebra (the spines with attached ribs). The cervical spines are usually seven and the main function is to support the skull and to protect the spinal cord. The dorsal (thoracic) spine forms the middle portion of the vertebral column extending below the seventh cervical vertebra to above the first lumbar vertebra. The dorsal spine is formed by twelve vertebral bodies. The vertebrae forming the dorsal spine are unique in shape as they are the only vertebral bodies articulating with ribs. The lumbar spine represents the mid-lower segment of the vertebral column and is composed of five adjacent vertebrae. They are convex anteriorly to form a lumbar lordosis. The lumbar spine facet joints allows limited movements and rotation. The bony pelvis is formed by 4 bones; a pair of hip bones, the sacrum and the coccyx. The bony pelvis supports the pelvic viscera and works to transmit force from the axial skeleton to the lower limbs. The two hip bones are related anteriorly by the symphysis pubis and posteriorly to the sacroiliac joints bilaterally. This 3D model was created from the file STS_040 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D muscle model created from this scan can be reviewed at:

    Free

  6. Version 1.0.0

    3 downloads

    The lumbar spine represents the mid-lower segment of the vertebral column and is composed of five adjacent vertebrae. They are convex anteriorly to form a lumbar lordosis. The lumbar spine facet joints allows limited movements and rotation. Each lumbar vertebra is formed of: A body which is kidney shaped and is convex anteriorly while flattened posteriorly, pedicles and lamina, transverse processes, articular processes and a spinous process. The sacrum is the lower most segment of the vertebral column and also forms the posterior wall of the bony pelvis. The sacrum is formed by five fused sacral vertebrae. The sacrum is formed by fusion of five sacral vertebrae has three surfaces, a base and an apex. The body of the first segment is large and is similar to lumbar vertebra whereas the bodies of the next bones get progressively smaller, are flattened from the back, and curved to shape. The sacrum articulates with four other bones – iliac bones on either side, L5 above and coccyx below. It is tilted forward and curved with anterior concavity and posterior convexity allowing greater room for pelvic cavity. The curvature of sacrum varies in individuals. This 3D model was created from the file STS_040 The original CT examination can be reviewed at:

    Free

  7. Version 1.0.0

    9 downloads

    The lumbar spine represents the mid-lower segment of the vertebral column and is composed of five adjacent vertebrae. They are convex anteriorly to form a lumbar lordosis. The lumbar spine facet joints allows limited movements and rotation. Each lumbar vertebra is formed of: A body which is kidney shaped and is convex anteriorly while flattened posteriorly, pedicles and lamina, transverse processes, articular processes and a spinous process. This 3D model was created from the file STS_040 The original CT examination can be reviewed at:

    Free

  8. Version 1.0.0

    9 downloads

    The dorsal (thoracic) spine forms the middle portion of the vertebral column extending below the seventh cervical vertebra to above the first lumbar vertebra. The dorsal spine is formed by twelve vertebral bodies. The vertebrae forming the dorsal spine are unique in shape as they are the only vertebral bodies articulating with ribs. This 3D model was created from the file STS_040 The original CT examination can be reviewed at:

    Free

  9. Version 1.0.0

    5 downloads

    The cervical spine is the upper most spines forming the spinal column, extending from the skull base to the level of the thoracic vertebra (the spines with attached ribs). The cervical spines are usually seven and the main function is to support the skull and to protect the spinal cord. Apart from the first cervical vertebra (atlas) and the second vertebra (axis), the other vertebral bodies share a general anatomical appearance: Oval shaped vertebral bodies with wide vertebral arch, large vertebral foramina and long spinous processes. This 3D model was created from the file STS_040 The original CT examination can be reviewed at:

    Free

  10. Version 1.0.0

    43 downloads

    Whole Spine (Cervical-Dorsal-Lumbar-Sacral) The cervical spine is the upper most spines forming the spinal column, extending from the skull base to the level of the thoracic vertebra (the spines with attached ribs). The cervical spines are usually seven and the main function is to support the skull and to protect the spinal cord. Apart from the first cervical vertebra (atlas) and the second vertebra (axis), the other vertebral bodies share a general anatomical appearance: Oval shaped vertebral bodies with wide vertebral arch, large vertebral foramina and long spinous processes. The dorsal (thoracic) spine forms the middle portion of the vertebral column extending below the seventh cervical vertebra to above the first lumbar vertebra. The dorsal spine is formed by twelve vertebral bodies. The vertebrae forming the dorsal spine are unique in shape as they are the only vertebral bodies articulating with ribs. The lumbar spine represents the mid-lower segment of the vertebral column and is composed of five adjacent vertebrae. They are convex anteriorly to form a lumbar lordosis. The lumbar spine facet joints allows limited movements and rotation. This model shows lumbar spondylo-degenerative changes manifested by marginal osteophytic lipping. The sacrum is the lower most segment of the vertebral column and also forms the posterior wall of the bony pelvis. The sacrum is formed by five fused sacral vertebrae. The sacrum is formed by fusion of five sacral vertebrae has three surfaces, a base and an apex. The body of the first segment is large and is similar to lumbar vertebra whereas the bodies of the next bones get progressively smaller, are flattened from the back, and curved to shape. The sacrum articulates with four other bones – iliac bones on either side, L5 above and coccyx below. It is tilted forward and curved with anterior concavity and posterior convexity allowing greater room for pelvic cavity. The curvature of sacrum varies in individuals. This model shows also the clavicle, parts of ribs, sacroiliac joints and the symphysis pubis. This 3D model was created from the file STS_040 The original CT examination can be reviewed at:

    Free

  11. Version 1.0.0

    0 downloads

    The knee joint is formed by three bones: the femur, the tibia and the patella. the knee joint is the largest synovial joint and provides the flexion and extension movements of the leg as well as relative medial and lateral rotations while in relative flexion. The knee joint articulations are two condylar joints between the femur and the tibia as well as a joint between the patella and the femur. Although the fibula is closely related to the knee joint but it doesn't share in articulation. The knee joint is also formed by some ligaments and cartilage called (mensci) which are best imaged by MRI. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D muscle model created from this scan can be reviewed at:

    Free

  12. Version 1.0.0

    0 downloads

    The knee joint is formed by three bones: the femur, the tibia and the patella. the knee joint is the largest synovial joint and provides the flexion and extension movements of the leg as well as relative medial and lateral rotations while in relative flexion. The knee joint articulations are two condylar joints between the femur and the tibia as well as a joint between the patella and the femur. Although the fibula is closely related to the knee joint but it doesn't share in articulation. The knee joint is also formed by some ligaments and cartilage called (menisci) which are best imaged by MRI. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  13. Version 1.0.0

    6 downloads

    The knee joint is formed by three bones: the femur, the tibia and the patella. the knee joint is the largest synovial joint and provides the flexion and extension movements of the leg as well as relative medial and lateral rotations while in relative flexion. The knee joint articulations are two condylar joints between the femur and the tibia as well as a joint between the patella and the femur. Although the fibula is closely related to the knee joint but it doesn't share in articulation. The knee joint is also formed by some ligaments and cartilage called (menisci) which are best imaged by MRI. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D muscle model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  14. Version 1.0.0

    5 downloads

    The knee joint is formed by three bones: the femur, the tibia and the patella. the knee joint is the largest synovial joint and provides the flexion and extension movements of the leg as well as relative medial and lateral rotations while in relative flexion. The knee joint articulations are two condylar joints between the femur and the tibia as well as a joint between the patella and the femur. Although the fibula is closely related to the knee joint but it doesn't share in articulation. The knee joint is also formed by some ligaments and cartilage called (mensci) which are best imaged by MRI. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D muscle model created from this scan can be reviewed at:

    Free

  15. Version 1.0.0

    3 downloads

    The knee joint is formed by three bones: the femur, the tibia and the patella. the knee joint is the largest synovial joint and provides the flexion and extension movements of the leg as well as relative medial and lateral rotations while in relative flexion. The knee joint articulations are two condylar joints between the femur and the tibia as well as a joint between the patella and the femur. Although the fibula is closely related to the knee joint but it doesn't share in articulation. The knee joint is also formed by some ligaments and cartilage called (mensci) which are best imaged by MRI. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  16. Version 1.0.0

    19 downloads

    The knee joint is formed by three bones: the femur, the tibia and the patella. the knee joint is the largest synovial joint and provides the flexion and extension movements of the leg as well as relative medial and lateral rotations while in relative flexion. The knee joint articulations are two condylar joints between the femur and the tibia as well as a joint between the patella and the femur. Although the fibula is closely related to the knee joint but it doesn't share in articulation. The knee joint is also formed by some ligaments and cartilage called (mensci) which are best imaged by MRI. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D muscle model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  17. Version 1.0.0

    4 downloads

    The foot is a highly developed, biomechanically complex structure that serves to bear the weight of the body. The foot can be divided into 3 parts: the hindfoot, the midfoot, and the forefoot. The hindfoot is composed of 2 of the 7 tarsal bones, the talus, and the calcaneus; the midfoot contains the rest of the tarsal bones; and the forefoot contains the metatarsals and the phalanges. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  18. Version 1.0.0

    13 downloads

    The foot is a highly developed, biomechanically complex structure that serves to bear the weight of the body. The foot can be divided into 3 parts: the hindfoot, the midfoot, and the forefoot. The hindfoot is composed of 2 of the 7 tarsal bones, the talus, and the calcaneus; the midfoot contains the rest of the tarsal bones; and the forefoot contains the metatarsals and the phalanges. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D muscle model created from this scan can be reviewed at:

    Free

  19. Version 1.0.0

    14 downloads

    The foot is a highly developed, biomechanically complex structure that serves to bear the weight of the body. The foot can be divided into 3 parts: the hindfoot, the midfoot, and the forefoot. The hindfoot is composed of 2 of the 7 tarsal bones, the talus, and the calcaneus; the midfoot contains the rest of the tarsal bones; and the forefoot contains the metatarsals and the phalanges. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D muscle model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  20. Version 1.0.0

    8 downloads

    The foot is a highly developed, biomechanically complex structure that serves to bear the weight of the body. The foot can be divided into 3 parts: the hindfoot, the midfoot, and the forefoot. The hindfoot is composed of 2 of the 7 tarsal bones, the talus, and the calcaneus; the midfoot contains the rest of the tarsal bones; and the forefoot contains the metatarsals and the phalanges. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D muscle model created from this scan can be reviewed at:

    Free

  21. Version 1.0.0

    4 downloads

    The foot is a highly developed, biomechanically complex structure that serves to bear the weight of the body. The foot can be divided into 3 parts: the hindfoot, the midfoot, and the forefoot. The hindfoot is composed of 2 of the 7 tarsal bones, the talus, and the calcaneus; the midfoot contains the rest of the tarsal bones; and the forefoot contains the metatarsals and the phalanges. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  22. Version 1.0.0

    16 downloads

    The foot is a highly developed, biomechanically complex structure that serves to bear the weight of the body. The foot can be divided into 3 parts: the hindfoot, the midfoot, and the forefoot. The hindfoot is composed of 2 of the 7 tarsal bones, the talus, and the calcaneus; the midfoot contains the rest of the tarsal bones; and the forefoot contains the metatarsals and the phalanges. This 3D model was created from the file STS_039 The original CT examination can be reviewed at: The 3D muscle model created from this scan can be reviewed at: The 3D skin model created from this scan can be reviewed at:

    Free

  23. Version 1.0.0

    6 downloads

    The bony pelvis is formed by 4 bones; a pair of hip bones, the sacrum and the coccyx. The bony pelvis supports the pelvic viscera and works to transmit force from the axial skeleton to the lower limbs. The two hip bones are related anteriorly by the symphysis pubis and posteriorly to the sacroiliac joints bilaterally. This model if for a 57 years old female pelvis, it shows some irregular shaped pieces related to the contrast media within the colon as well as the upper halves of the femoral bones. The CT scan is derived from the file STS_040 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at:

    Free

  24. Version 1.0.0

    21 downloads

    The bony pelvis is formed by 4 bones; a pair of hip bones, the sacrum and the coccyx. The bony pelvis supports the pelvic viscera and works to transmit force from the axial skeleton to the lower limbs. The two hip bones are related anteriorly by the symphysis pubis and posteriorly to the sacroiliac joints bilaterally. This model if for a 57 years old female pelvis, it shows some irregular shaped pieces related to the contrast media within the colon as well as the upper halves of the femoral bones. The CT scan is derived from the file STS_040 The original CT examination can be reviewed at: The 3D muscle model created from this scan can be reviewed at:

    Free

  25. Version 1.0.0

    2 downloads

    The shoulder joint is a large and complex ball and socket joint formed by the humerus and the scapula (glenohumeral joint) while the clavicle join the acromion to form the acromioclavicular joint. The shoulder joint is the most mobile joint in the human body on cost of instability. Lot of elements share to compensate the instability such as rotator cuff muscles, tendons and ligaments as well as the glenoid labrum. Muscles of the shoulder joint The rotator cuff: supraspinatus, infraspinatus, teres minor and subscapularis Posterior muscle group: deltoid, latissimus dorsi and teres major Anterior muscle group: pectoralis major and coracobrachialis This 3D model was created from the file STS_040 The original CT examination can be reviewed at: The 3D bone model created from this scan can be reviewed at:

    Free

×
×
  • Create New...