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Found 753 results

  1. Version 2.0.0

    4 downloads

    disphip v2 - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. bone, pelvis, hip, .stl, 3d, model, printable, bone, iliac, pubis, ischium, sacrum, coccyx, neck, diaphysis, trochanter, lower, limb, femur, sacrum, sacroiliac, joint, obturator, foramen,

    Free

  2. 3D Free Scapula, Clavicle, and Humerus Models in 3D-Printable STL Format Shoulders are comprised of three main bones. These include humerus (bone in the upper arm), scapula (shoulder blade), and the clavicle, which we commonly refer to as the "collarbone." Bones of the shoulder work together with the transverse humeral ligament, synovial membrane of the bicep, bursa sac, and the superior transverse ligament to perform a complex range of motions. In fact, the shoulder has the most extended pivot range of any joint within the body. Your glenohumearal joint (shoulder) is a ball-and-socket joint that is able to move in so many positions due to the relatively small size of the glenoid fossa, as well as the laxity ("wiggle room") of the joint capsule. But, these features also make the shoulder prone to overuse injuries, subluxation, dislocation, and ligament tears. In this week's embodi3D® Top Ten, we are bringing you some of the best 3D scapula, clavicle, and humerus models which comprise the majority of the human shoulder joint. Before you dive into this week's Top 10 and start printing your own 3D anatomical models, you must first register with embodi3D®. It's absolutely free to sign up and you can take advantage of many of the features found on the embodi3D® website, including standard resolution democratiz3D® conversions. Register with embodi3D® today! Technologies like these were recently featured in the journal Société Internationale de Chirurgie Orthopédique et de Traumatologie (SICOT), where models of a 3D scapula, humerus, and soft tissues are being used in preoperative planning. If you are interested in uploading your CT scans and converting these to 3D-printable STL format, the democratiz3D® Quick Start Guide will help you to quickly get up and running. How Shoulders Achieve Their Range of Motion Flexion, extension, abduction, adduction, circumduction, medial rotation, and lateral rotation. * Flexion: Pectoralis major, deltoid, coracobrachialis, & biceps muscles * Extension: Deltoid & teres major muscles. – If against resistance, also latissimus dorsi & pectoralis major. * Abduction: Deltoid & supraspinatus muscles. – Subscapularis, infraspinatus, & teres minor exert downward traction – Supraspinatus contribution controversial * Medial rotation: Pectoralis major, deltoid, latissimus dorsi, & teres major muscles. – Subscapularis when arm at side * Lateral rotation: Infraspinatus, deltoid, & teres minor muscles. #1. An Incredible 3D Model of the Shoulder in STL Format This articulation is maintained by overlying soft tissue structures. The posterosuperior acromion process of the scapula provides one half of the AC joint. It also forms most of the osseous portion of the coracoacromial arch, the roof over the rotator cuff. The acromion process is connected to the body of the scapula by the spine. The osseous structures of the shoulder girdle are the clavicle, scapula, and humerus. Medially, the clavicle articulates with the manubrium of the sternum at the sternoclavicular (SC) joint. This joint serves as the only true articulation between the shoulder girdle and the axial skeleton. Laterally, the clavicle articulates with the acromion process of the scapula at the acromioclavicular (AC) joint #2. STL File Showing Scapular Notch and Shoulder Variations in the shape of the clavicle are considered normal and are not usually pathologic. These variations may range from an almost straight bone to one with exaggerated curves. Another variation of the clavicle that is present in 6-10% of the population is termed the canalis nervi supraclavicularis. In this variation, a foramen forms through the clavicle, and the medial supraclavicular nerve passes through this accessory osseous canal. The scapular notch varies in size and shape. The notch is bridged by the superior transverse scapular ligament. This ligament ossifies in 10% of patients, producing a bony foramen for the suprascapular nerve. #3. A 3D Model of the Shoulders of the Muscle Rotator cuff: 4 muscles arising on scapula and inserting on humerus * Supraspinatus: From supraspinatus fossa of scapula to greater tuberosity – Abducts humerus, also depresses humeral head. * Infraspinatus: From posterior surface of scapula to greater tuberosity. – Externally rotates humerus * Teres minor: From lateral border of scapula to greater tuberosity – Externally rotates humerus * Subscapularis muscle: From anterior surface of scapula to lesser tuberosity – Superficial fibers extend across to anterior margin of greater tuberosity as part of transverse ligament – Internally rotates, adducts humerus #4. 3D Model (STL Format) of the Muscles Connecting the Arm to Axial Skeleton 4. Various muscles also serve to connect the arm to the axial skeleton. Anteriorly, the pectoralis major and minor muscles extend from the sternum and clavicle to the proximal humeral shaft. Posteriorly, the latissimus dorsi muscle arises from the thoracic cage to attach onto the proximal humeral shaft. The great range of motion provided for by the glenohumeral joint is executed in large part by the muscles of the rotator cuff. The supraspinatus muscle arises superior to the scapular spine and attaches to the superior facet of the greater tuberosity. The more posterior infraspinatus muscle arises below the spine and inserts onto the posterior facet of the greater tuberosity. The teres minor muscle originates and inserts just caudal to the infraspinatus. The subscapularis muscle arises from the anterior scapular body to insert onto the lesser tuberosity. The long head of the biceps originates at the superior glenoid rim, passes through the rotator cuff interval at the anterosuperior glenohumeral joint, and then follows the bicipital groove between the tuberosities into the upper arm. The deltoid muscle has a broad origination along the lateral aspect of the acromion from anterior to posterior. It covers the lateral portion of the upper arm before inserting on to the lateral proximal humeral shaft at the deltoid tuberosity. #5. 3D Model of the Skin around the Shoulder, Arm, and Upper Chest A 3D model of the skin of the shoulder where the soft tissue of the shoulder and arm are shown. Trapezius: is responsible for the smooth contour of the lateral side of the neck and over the superior aspect of the shoulder. It can be seen and felt throughout its entirety when the shoulder girdles are retracted against resistance; the superior part can be palpated when the shoulders are elevated against resistance. Posterior axillary fold: is formed by the latissimus dorsi winding around the lateral border of the teres major muscle. Latissimus dorsi forms much of the muscle mass underlying the posterior axillary fold extending obliquely upward from the trunk to the arm. Teres major passes from the inferior angle of the scapula to the upper humerus and contributes to the fold laterally. Both muscles can be palpated on resisted shoulder adduction. Pectoralis major: can be seen and felt throughout its entire extent when it is contracted against resistance as in pressing the palm together in front of the body. Clavicular fibers can be felt if the shoulder is flexed against resistance to a position midway between flexion and extension, while the sternocostal fibers can be felt if the shoulder is extended against resistance starting in a flexed position. The inferior border of the pectoralis major muscle forms the anterior axillary fold. Deltoid: forms the muscular eminence inferior to the acromion and around the glenohumeral joint. The anterior, middle, and posterior fibers of the deltoid can be palpated. When the arm is abducted against resistance, the anterior border of the deltoid can be felt. The clavipectoral triangle (deltopectoral triangle) is the depressed area just inferior to the lateral part of the clavicle, bounded by the clavicle superiorly, the deltoid laterally, and the clavicular head of the pectoralis major medially. #6. CT Scan Showing a Fracture in the Proximal Humeral A computed tomography (CT) is recommended for complex fracture situations although those situations were not clearly defined. Therefore, precise indications for CT in proximal humeral fractures are not established. #7. Connection of Scapula, Humerus, and Clavicle Shown in 3D STL File The scapula is a spade-shaped bone comprised of a thin triangular body and a semi-ovoid cavity known as the glenoid fossa (glenoid cavity). The glenoid fossa faces lateral and slightly anterior and cranial. A bony spine runs across the dorsal surface of the scapular body and terminates in the acromion. The scapula articulates with two bones, the humerus and clavicle. The scapula does not directly contact the bony rib cage: the two structures are separated by muscle and other soft tissue. #8. Right Shoulder Injury Revealed by CT Scan On CT acute trauma may result of bony, labral, ligamentous or musculotendinous damage. The shoulder may be injured following repetitive injury or as part of systemic inflammatory conditions or infection. Moreover, the bones around the shoulder may be affected by benign or malignant bony lesions, and associated pathological fracture. #9. Right Shoulder with Pleomorphic Spindle Cell Sarcoma (3D-Printable STL File) Pleomorphic sarcoma composed of fibroblasts, myofibroblasts and histiocyte-like cells. Historically considered the most common adult soft tissue sarcoma. Usually older adults (age 50+ years) with slight male predominance; more common in lower extremities, rarely retroperitoneum, head and neck, breast. Large and deep-seated with progressive enlargement. Sarcomas adjacent to orthopedic implants or post-radiation are usually osteosarcoma or MFH. #10. 3D-Printable Model of Right Shoulder Bones The humerus is the large single bone of the upper arm. Proximally, it articulates with the glenoid fossa of the scapula forming the glenohumeral joint. The humeral head is large and globular. Just ventral to the articular surface is the lesser tubercle, where the subscapularis attaches. Lateral to the articular surface is the greater tubercle. The rotator cuff muscles of the shoulder insert on the proximal humerus. References 1. Manaster, B. J., & Crim, J. R. (2016). Imaging Anatomy: Musculoskeletal E-Book. Elsevier Health Sciences. 2. Bahrs, C., Rolauffs, B., Südkamp, N. P., Schmal, H., Eingartner, C., Dietz, K., ... & Helwig, P. (2009). Indications for computed tomography (CT-) diagnostics in proximal humeral fractures: a comparative study of plain radiography and computed tomography. BMC musculoskeletal disorders, 10(1), 33. 3. Duke University Medical School - Anatomy. (2018). Web.duke.edu. Retrieved 4 August 2018, from https://web.duke.edu/anatomy/ 4. Shoulder Joint Anatomy: Overview, Gross Anatomy, Microscopic Anatomy. (2018). Emedicine.medscape.com. Retrieved 4 August 2018, from https://emedicine.medscape.com/article/1899211-overview#a1 5. The Radiology Assistant : Shoulder MR - Anatomy. (2012). Radiologyassistant.nl. Retrieved 4 August 2018, from http://www.radiologyassistant.nl/en/p4f49ef79818c2/shoulder-mr-anatomy.html
  3. Version 1.0.0

    1 download

    femur fracture - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. vascular, aorta, iliac, common, external, pubis, sacroiliac, joint, sacrum, coccyx, transverse, spinous, process, intervertebral, disc, femur, trochanter, neck, diaphysis, fracture, condyle, femoral, artery, 3d, model, printable, bone, ,stl, lower, limb

    Free

  4. Myli

    asd

    Version 1.0.0

    2 downloads

    test1, child, lower, limb, metaphysis, condyle, tibia, fibula, knee, patella, tendon, patellar, ligaments, cruciate, triceps, soleus, muscles, mri, without, contrast,

    Free

  5. Version 1.0.0

    0 downloads

    test, axial, ct, scan, without, contrast, thorax, .stl, 3d, model, printable, abdomen, heart, heart, ventricle, auricle, mediastinum, diaphragm, ribs, bone, whole, body, pelvis, scapula, clavicle, neck, dorsal, spine, gastric, small, intestine, colon, rectum, hip, pubis, esophagus, trachea, bronchi, shoulder, upper, limb, humerus, diaphysis, trochin, psoas, muscle, lumbar, head, femur, trochanter, ischium, spleen,

    Free

  6. Top 10: Free Downloadable 3D Knee Model and Other STL Files As a complex joint and one of the largest joints in the body, the knee joint is a fascinating feature of the human form. This joint not only has the task of joining the femur (thigh bone), tibia (shin bone), and patella (knee cap), but also remaining flexible enough to allow for compound movements, such as running, jumping, dancing, kicking a soccer ball — the list goes on. The knee joint may have the greatest range of motion thanks to its non-interlocking form, but the muscles, joint, tendons, ligaments, menisci, capsule, and tendons must all work together to give the leg the rigidity it needs to support nearly the entire human bodyweight. Have you guessed this week's Top 10 featured uploads from the embodi3D® community? That's right, we're highlighting the marvel that is the human knee joint — bones, tissues, and all. Within the following sections you see stunning images and STL files of a 3D knee model (several, actually), as well as a number of other STL models of the lower limbs that you can download and create using your 3D printer. If this topic is of particular interest, you may also want to check out a recent article in the online trade journal Manufacturing Tomorrow highlighting the use of 3D-printed knee models in pre-operative preparation. And, don't forget to check out our Extremity, Lower Leg library for more 3D-printable STL files like these! But, before you can make use of all the amazing tools offered on the embodi3D® website you need to register with embodi3D®. This community is absolutely free to join and members can upload, download, convert, and sell their CT-converted STL files. The Radiologist's Difficult Task of Imaging Knee Joints There are a number of pitfalls and challenges when it comes to getting a stable image of the knee area, including: • Variants: Multiple osseous and soft tissue normal variants • Loose bodies on MR: Easily missed • Partial voluming over convex surfaces: Morphology of trochlea, femoral condyles, and patella makes them particularly difficult to evaluate in 3 standard planes • Imaging cartilage ○ T2 underestimates cartilage thickness since cortex and cartilage have similar signal ○ PD may have similar signal for cartilage and adjacent joint fluid, obscuring defects; fat saturation solves this. #1. 3D Knee Model Showing the Muscles (in 3D-Printable STL Format) Muscles acting on knee joint: Extensors (4 parts of quadriceps femoris) ○ Rectus femoris (crosses both hip and knee joints, flexing hip and extending knee), ○ Vastus lateralis , ○ Vastus medialis ○ Vastus intermedius ( Extends knee) Muscles acting on knee joint: Flexors ○ Biceps femoris (Flexes knee and also rotates tibia laterally; long head also extends hip joint) ○ Sartorius (Crosses both hip and knee joints, flexes both hip and knee joints, rotating thigh laterally to bring limbs into position adopted by cross-legged tailor) ○ Gracilis (Adducts thigh, flexes knee, and rotates flexed leg medially) ○ Semitendinosus (Crosses both hip and knee joints, extends hip, flexes knee, medially rotates flexed leg) ○ Semimembranosus (Crosses both hip and knee joints, extends hip, flexes knee, medially rotates flexed knee) ○ Popliteus (Flexes knee and medially rotates tibia at beginning of flexion) – Innervation: Tibial nerve Muscles acting on knee joint: Superficial flexors of knee ○ Gastrocnemius: (Flexes knee and plantar flexes ankle) ○ Plantaris (Flexes knee and plantar flexes ankle) Muscles acting on knee joint: Internal rotators of leg ○ Popliteus, gracilis, sartorius, semitendinosus, semimembranosus Muscles acting on knee joint: External rotator of leg ○ Biceps femoris • Extensor mechanism ○ Quadriceps tendon and retinacula converge to inferior patellar tendon #2. A Remarkable STL Model of the Skin Surface of the Knee This detailed STL file was converted from a CT scan through democratiz3D® and uploaded to the community for the benefit of all. #3. 3D Model of the Bones within the Knee (Femur, Tibia, Fibula, and Patella) The knee is composed of 4 bones: the femur, tibia, fibula and patella. All these bones are functional in the knee joint, except for the fibula. The femur is the longest and strongest bone in the human body. The tibia lies distal to the femur and medial to the fibula. The proximal end consists of medial and lateral condyles, an intercondylar area, and the tibial tuberosity that articulates with the medial and lateral condyles of the femur. Distally, the tibia articulates with the ankle. The distal and proximal ends of the tibia articulate with the fibula. In addition, the shaft of the tibia and fibula are connected with an interosseous membrane to form a syndesmosis joint. The fibula does not articulate with the femur or patella. Furthermore, the fibula is not directly involved in weight transmission. The patella is the largest sesamoid bone in the human body. This bone is flat, proximally curved, and distally tapered; however, the shape can vary. The posterior patella articulates with the femur, but the apex sits proximal to the line of the knee joint. The tendon of the quadriceps femoris completely encompasses the patella. #4. CT Scan of the Knee Showing Articulations of the Condylar Joints 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. #5. Fracture of the Tibial Plateau (Converted into STL, 3D-Printable Format) Fx of tibial plateau due to axial loading, ± rotational injury, ± valgus angulation. Most tibial plateau fx involve lateral plateau ○ "Split" component of fx describes fx line extending from articular surface to margin of metaphyseal cortex ○ "Depressed" component is displaced below level of remainder of articular surface. I-III involve lateral plateau only ○ Schatzker I: Split fx with no depression (usually younger patients) ○ Schatzker II: Lateral split/wedge fx with depression of weight-bearing portion (usually older patients with osteoporosis) ○ Schatzker III: Focal depression of articular surface, no associated split (elderly, osteoporotic patients) ○ Schatzker IV: Any medial plateau fx: Split, ± depression; may involve tibial spines; associated soft tissue injuries and poor prognosis – Lateral plateau fx line that extends to medial articular surface adjacent to tibial spines but without depression or extension to metaphyseal cortex not considered to involve medial plateau for classification purposes – Commonly associated with lateral collateral ligament complex or posterolateral corner injuries or proximal fibula fx ○ Schatzker V: Split fx of both medial and lateral plateau (bicondylar) ± depression – Up to 1/2 have meniscal injuries, 1/3 anterior cruciate ligament avulsions ○ Schatzker VI: Bicondylar or unicondylar split fx with dissociation of metaphysis from diaphysis by transverse fx component #6. CT Scan of the Knee Showing an LTP Fracture Findings of this CT scan include: • Assists in diagnosis of radiographically occult fx • Confirms anatomic relationship of fx fragments in complex cases ○ Describe number, size, and location for fragments and fx lines ○ Accurate measurement of size and extent of plateau fragment depression • Surgical planning for either elevation of depressed fragments or for Schatzker type IV-VI fxs #7. An MRI of the Menisci of the Knee (History of Injury) These MRIs highlight a patient with a history of injury to the area. We can clearly see the menisci and its analysis include: Lateral meniscus ○ Overall configuration: Semicircular ○ Shape: Uniform, minimally and gradually enlarging from anterior to posterior ○ Normal recess: Peripheral, inferior at anterior horn Medial meniscus ○ Overall configuration: Semilunar (C-shaped) ○ Shape nonuniform: Anterior horn similar in size & shape to LM but midbody is small, approximating an equilateral triangle; MM posterior horn is largest portion of MM, nearly 2x as long as anterior horn ○ Normal recess: Peripheral, superior at posterior horn Meniscal "flounce": Buckling of a portion of meniscus, perhaps related to femorotibial subluxation Signal • Generally uniformly low signal throughout • Exceptions ○ Children and adolescents may have normal increased intrameniscal signal that does not extend to surface (due to rich vascular supply) ○ Adults may develop central degenerative changes seen as linear or globular signal that does not extend to surface and does not represent a tear ○ Various high signal clefts and dots can normally be seen in anterior horn LM at and near its root attachment, due to immediate adjacency of origin of ACL and divergence of longitudinal fibers at root; do not misinterpret as tear ○ Peripheral portion of meniscus is quite vascular – Outer meniscal margin as seen by MR is usually not true periphery of structure: Meniscus signal in its peripheral vascular portion (10-30%) blends in with gray signal of the capsule ○ "Magic angle" may affect signal in posterior horn of LM in region of intercondylar notch #8. Knee Ligaments and Muscles in a 3D-Printable Model (STL File) This extraordinarily detailed 3D model of a 64-year-old male's knee shows the exquisite details of the muscles and ligaments. #9. Printable STL File of a Right Leg Bone Model Fibrohistiocytic tumors represent a highly heterogeneous group of soft tissue neoplasms composed of cells exhibiting fibroblastic and histiocytic features. The extremities are the most common site followed by the trunk, the pelvis, the head and neck region and the genital area. The differential diagnosis should exclude benign myxoid neoplasms, epitheloid types of MFS, carcinoma, melanoma, myoepithelial carcinoma, pleomorphic liposarcoma and pleomorphic rabdomyosarcoma. #10. Total Knee Arthroplasty Completed with 3D-Printed Metal Condyles Total knee arthroplasty (TKA): Replacement of femoral, tibial, and patellar articular surfaces DIAGNOSTIC CHECKLIST: • Keep in mind shape of polyethylene components; lucency of this shape in wrong location is hint of dislocation • Periprosthetic fractures are easily missed; include them in your search pattern ○ Increased risk for periprosthetic fracture with osteoporosis &/or tibial tubercle transfer. Complications, other than malalignment ○ Patellar button dislocation from cement or metal backing. ○ Tibial polyethylene may dislocate from metal tray ○ Stress shielding: Occurs in anterior and mid femoral metaphysis, seen on lateral radiograph – Does not predict component failure ○ Loosening: Change in position (tilt or subsidence) – Patellar button usually subsides superiorly. - Tibial component subsides inferiorly, usually with medial trabecular compression ○ Infection – Rare radiographic findings of serpiginous destruction – MR: Lamellated hyperintense synovitis differentiates infectious from noninfectious synovitis References 1. Manaster, B. J., & Crim, J. R. (2016). Imaging Anatomy: Musculoskeletal E-Book. Elsevier Health Sciences. 2. Castronovo, C., Arrese, J. E., Quatresooz, P., & Nikkels, A. F. (2013). Myxofibrosarcoma: a diagnostic pitfall. Rare tumors, 5(2), 60-61. 3. Blankenbaker, D. G., & Davis, K. W. (2016). Diagnostic Imaging: Musculoskeletal Trauma E-Book. Elsevier Health Sciences.
  7. Version 1.0.0

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    5 4 SAG GE STIR - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. 3d,model, printable, .stl, limb, knee,

    Free

  8. yovo24

    FIn

    Version 1.0.0

    2 downloads

    Sacrum, MRI, sagittal, iliac, pubis, ischium, bone, acetabulum, head, neck, trochanter, femur, lower, limb, .stl, 3d, model, gluteus, small, bowel, colon, sacrum,

    Free

  9. Version 1.0.0

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    deranged right stifle in cat, cat, dog bite, cat, limb, muscles, bone, 3d, model, printable, ct, scan, without, contrast, axial, hindtleg, femur, tibia, fibula, dog, bite,

    Free

  10. Version 1.0.0

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    deranged stifle in cat, dog bite, cat, limb, muscles, bone, 3d, model, printable, ct, scan, without, contrast, axial, hindtleg, femur, tibia, fibula, dog, bite,

    Free

  11. Version 1.0.0

    1 download

    deranged stifle cat - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. dog bite, cat, limb, muscles, bone, 3d, model, printable, ct, scan, without, contrast, axial, hindleg, femur, tibia, fibula,, dog, bite,

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  12. Version 1.0.0

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    derange stifle due to dog bite, cat, limb, muscles, bone, 3d, model, printable, ct, scan, without, contrast, axial, hindtleg, femur, tibia, fibula, dog, bite,

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  13. Version 1.0.0

    1 download

    skull to legs, chest, abdomen, pelvis, hip, bone, 3d, model, printable, .stl, sternum, ribs, thorax, dorsal, spine, atlas, axis, cervical, scapula, clavicle, upper, limb, mediastinum, lung, ventricle, auricle, septum, liver, spleen, gastric, abdominal, kidney, lumbar, body, intervertebral, disc, small, bowel, gallbladder, urinary, bladder, perineum, ischium, pubis, sacroiliac, joint, pubis, sacroiliac, joint, sacrum, coccyx, ct, scan, without, contrast,

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  14. Version 1.0.0

    1 download

    female_pelvis2 - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. upper, limb, .stl, 3d, model, printable, head, diaphysis, bone, scapula, clavicle, ribs, thorax, chest, sternum, dorsal, spinous, process, wrist, metatarsals, phalanx, lumbar, spine, intervertebral, disc, promontory, sacrum, foramina, iliac, pubis, ischium, iliac, pubis, ischium, elbow, radius, cubitus, sternocostoclavicular, manubrium,

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  15. Version 1.0.0

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    ece599, axial, dicom, .stl, 3d, model, printable, liver, spleen, stomach, lumbar, spine, bone, transverse, spinous, ribs, thorax, chest, pelvis, hip, acetabulum, upper, hip, acetabulum, upper, limb, upper, limb, head, trochin, diaphysis, small, bowel, ilium, ischium, psoas, kidney, urinary, bladder, gallbladder, pancreas, adrenal, colon, descendent, ascendent, pneumonia, lung, bronchi,ventricle, auricle, heart, mediastinum, dorsal,

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  16. Version 1.0.0

    2 downloads

    female_pelvis - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. thorax, sternum, ribs, chest, upper, limb, diaphysis, neck, head, trochin, pelvis, lumbar, spine , intervertebral, disc, body, radius, cubitus, dorsal, scapula, clavicle, sacrum, foramina, sacroiliac, joint

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  17. Muhsin

    test file

    Version 1.0.0

    2 downloads

    hi, stomach, .stl, 3d, model, printable, axial, dicom, liver, spleen, lung, lumbar, spine, ribs, thorax, pancreas, kidney, colon, transverse, descendent, ascendent, cervical, trachea, scapula, clavicle, humerus, head, diaphysis, bone, upper, limb, atlas, abdomen, ct, scan, without, contrast, esophagus,

    Free

  18. Version 1.0.0

    1 download

    Female Head, whole, body, .stl, 3d, model, ct, scan, without, contrast, petrous, ridge, maxilla, mandible, pharynx, thorax, ribs, scapula, bone, neck, cervical, dorsal, lumbar, spine, sacrum, coccyx, foramina, intervertebral, disc, foramina, intervertebral, disc, head, humerus, chest, mediastinum, cardiac, ventricle, auricle, septum, rectum, sigmoid, hard, palate, nasal, muscle, pelvis, gluteus,

    Free

  19. Version 1.0.0

    1 download

    Glasgow NHS, lower, limb, .stl, ct, scan, without, contrast, condyle, soleus, quadriceps, femur, bone, lateral, medial, 3d, model, printing, printable, knee, patella,

    Free

  20. Version 1.0.0

    6 downloads

    Glasgow NHS, condyle, lateral, medial, meniscus, bone, femur, .stl, 3d, model quadriceps, muscle, soleum, lower, limb, ct, scan, without, contrast,

    Free

  21. Version 1.0.0

    2 downloads

    Rotura de Glena, glenoid, shoulder, scapula, clavicle, neck, trochin, head, skull, ribs, lung, mediastinum, .stl, 3d, model, ct, scan, without, contrast, coronoid, process, glenohumeral, joint, upper, limb, dorsal, spine, intervertebral, disc, body, chest, ventricle, auricle, septum,

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  22. Version 1.0.0

    2 downloads

    new knee - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. lower, limb, .stl, 3d, model, knee, skin,

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  23. Version 1.0.0

    2 downloads

    Left elbow CT scan - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. upper, limb, .stl, 3d, model, elbow, cubitus, radius, printable, left, bone,

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  24. Version 1.0.0

    4 downloads

    CT scan of radial head fracture, head, radial, fracture, bone, 3d, model, ct, scan, without, contrast, axial, dicom, muscles, condyle, cubitus, upper, limb,

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  25. Version 1.0.0

    1 download

    skull 5th attempt - stl file processed Have embodi3D 3D print this model for you. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. head, skull, cervical, spine, atlas, axis, thorax, chest, ribs, sternum, .stl, 3d, model, printable, bone, orbit, muscles, quadriceps, vastus, medialis, lateralis, knee, femur, tibia, fibula, scapula, clavicle, abdomen, upper, limb, lower,

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