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Extremity, Lower (Leg) Muscles

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Lower extremity musculature: thigh, leg, ankle, foot.

67 files

  1. Free

    Muscles and tendons of the foot and ankle

    This 3D printable STL file contains a model of the right foot was derived from a real medical CT scan. It shows in detail the musculature, tendons, and ligaments of the foot and ankle. The anatomy is normal, and was derived from the foot of a 60 year old woman.
    This model was created using the democratiz3D free online 3D model creation service.
     
    STS_010 legs

    92 downloads

       (0 reviews)

    0 comments

    Updated

  2. Free

    Right knee - Muscle model STL file from converted CT scan

    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_051   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: 

    59 downloads

       (0 reviews)

    0 comments

    Updated

  3. Free

    Normal Right Foot and Ankle Muscle Model 3D Printable STL File Converted from CT Scan

    This is the normal right foot and ankle muscle model of a 56-year-old male with right anterior thigh pleomorphic leiomyosarcoma. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The primary motions of the ankle are dorsiflexion, plantarflexion, inversion, and eversion. However, with the addition of midfoot motion (adduction, and abduction), the foot may supinate (inversion and adduction) or pronate (eversion and abduction). In order to accomplish these motions, muscles outside of the foot (extrinsic) and muscles within the foot (intrinsic) attach throughout the foot, crossing one or more joints.
     
    Laterally, the peroneus brevis and tertius attach on the proximal fifth metatarsal to evert the foot. The peroneus longus courses under the cuboid to attach on the plantar surface of the first metatarsal, acting as the primary plantarflexor of the first ray and, secondarily, the foot. Together, these muscles also assist in stabilizing the ankle for patients with deficient lateral ankle ligaments from chronic sprains. Medially, the posterior tibialis inserts on the plantar aspect of the navicular cuneiforms and metatarsal bases, acting primarily to invert the foot and secondarily to plantarflex the foot.  The flexor hallucis longus inserts on the base of the distal phalanx of the great toe to plantarflex the great toe, and the flexor digitorum inserts on the bases of the distal phalanges of the lesser four toes, acting to plantarflex the toes. The gastrocnemius inserts on the calcaneus as the Achilles tendon and plantarflexes the foot. Anteriorly, the tibialis anterior inserts on the dorsal medial cuneiform and plantar aspect of the first metatarsal base as the primary ankle dorsiflexor and secondary inverter. The Extensor hallucis longus and extensor digitorum longus insert on the dorsal aspect of the base of the distal phalanges to dorsiflex the great toe and lesser toes, respectively.
     
    This model was created from the file STS_014.

    37 downloads

       (0 reviews)

    0 comments

    Updated

  4. Free

    Normal Right Foot and Ankle Muscle Model 3D Printable STL File Converted from CT Scan

    This model is the right foot and ankle muscle rendering of a 65-year-old male with left thigh myxoid fibrosarcoma. At the time of diagnosis, the patient had metastases to his lungs. The patient therefore underwent neoadjuvant radiotherapy, surgery, and adjuvant chemotherapy and was found to have an intermediate grade lesion at the time of diagnosis. The patient unfortunately died 9.5 months after diagnosis. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The primary motions of the ankle are dorsiflexion, plantarflexion, inversion and eversion. However with the addition of midfoot motion (adduction, and abduction), the foot may supinate (inversion and adduction) or pronate (eversion and abduction). In order to accomplish these motions, muscles outside of the foot (extrinsic) and muscles within the foot (intrinsic) attach throughout the foot, crossing one or more joints.
     
    Laterally, the peroneus brevis and tertius attach on the proximal fifth metatarsal to evert the foot. The peroneus longus courses under the cuboid to attach on the plantar surface of the first metatarsal, acting as the primary plantarflexor of the first ray and, secondarily, the foot. Together, these muscles also assist in stabilizing the ankle for patients with deficient lateral ankle ligaments from chronic sprains. Medially, the posterior tibialis inserts on the plantar aspect of the navicular cuneiforms and metatarsal bases, acting primarily to invert the foot and secondarily to plantarflex the foot.  The flexor hallucis longus inserts on the base of the distal phalanx of the great toe to plantarflex the great toe, and the flexor digitorum inserts on the bases of the distal phalanges of the lesser four toes, acting to plantarflex the toes. The gastrocnemius inserts on the calcaneus as the Achilles tendon and plantarflexes the foot. Anteriorly, the tibialis anterior inserts on the dorsal medial cuneiform and plantar aspect of the first metatarsal base as the primary ankle dorsiflexor and secondary inverter. The Extensor hallucis longus and extensor digitorum longus insert on the dorsal aspect of the base of the distal phalanges to dorsiflex the great toe and lesser toes, respectively.
     
    This model was created from the file STS_023.

    34 downloads

       (0 reviews)

    0 comments

    Updated

  5. Free

    Muscles of the legs

    This highly detailed 3D printable model of the musculature of the legs was derived from the CT scan of a 22 year old female. It shows all major muscle groups.
     
    This model was created with the democratiz3D free online conversion tool. 
     
    STS_004 0

    32 downloads

       (0 reviews)

    0 comments

    Updated

  6. Free

    Right Thigh Muscle Model 3D Printable STL File Converted from CT Scan

    This model is the right thigh muscle rendering of a 65-year-old male with left thigh myxoid fibrosarcoma. At the time of diagnosis, the patient had metastases to his lungs. The patient therefore underwent neoadjuvant radiotherapy, surgery, and adjuvant chemotherapy and was found to have an intermediate grade lesion at the time of diagnosis. The patient is still living with the metastatic disease at 2.5 years since diagnosis. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The thigh is divided into three compartments: the anterior, posterior, and adductor. The anterior compartment contains the “quadriceps muscles”, made up of the vastus lateralis, vastus medialis vastus intermedius, and rectus femoris, and the sartorius. These muscles are innervated by the femoral nerve (L3-L4), and act to extend the leg. The Sartorius muscle originates at the ASIS and crosses anterior to the quadriceps muscle to insert on the medial tibia in the pes anserinus. The posterior compartment contains the “hamstrings”, made up of the semitendinosus, semimembranosus, and short and long heads of the biceps femoris. These muscles act to flex the leg. All of these muscles are innervated by the sciatic nerve (tibial division) except for the short head of the biceps femoris, which is innervated by the sciatic nerve (peroneal division). The adductor compartment contains the adductor longus, adductor brevis, adductor magnus, and gracilis, which act to adduct the thigh. These muscles are innervated by the obturator, and the adductor magnus has dual innervation with the sciatic nerve. In addition, the obturator externus (a thigh external rotator) and pectineus muscle (thigh flexor and adductor) are located within this compartment.
     
    This model was created from the file STS_022.

    30 downloads

       (0 reviews)

    0 comments

    Updated

  7. Free

    Muscles of the knee

    This 3D printable STL file contains a model of the right knee was derived from a real medical CT scan. It shows in great detail the normal musculature of the knee joint, including the quadriceps and hamstring muscle groups, and calf musculature.
    This model was created using the democratiz3D free online 3D model creation service.
     
    STS_010

    23 downloads

       (0 reviews)

    0 comments

    Updated

  8. Free

    Left Leg Muscle Model 3D Printable STL File Converted from CT Scan

    This is the normal left leg muscle model (including foot) of a 56 year old male with right anterior thigh pleomorphic leiomyosarcoma. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The lower leg is divided into four muscle compartments: the anterior, lateral, superficial posterior, and deep posterior compartments.  The anterior compartment is made from the dorsiflexors, including the tibialis anterior, extensor hallucis longus (EHL), extensor digitorum longus (EDL) and peroneus tertius, which are innervated by the deep peroneal nerve. The lateral compartment includes the peroneus longus and peroneus brevis, which assist in foot eversion and are innervated by the superficial peroneal nerve. The superficial posterior compartment includes the gastrocnemius, soleus, and plantaris, which assist in plantarflexion and are innervated by the tibial nerve.  The deep posterior compartment is made up of the popliteus, flexor hallucis longus (FHL), flexor digitorum longus (FDL), and tibialis posterior, which mostly assist in plantarflexion and are innervated similarly by the tibial nerve.
     
    This file was created from the file STS_014.

    22 downloads

       (0 reviews)

    0 comments

    Updated

  9. Free

    Right Leg Muscle Model 3D Printable STL File Converted from CT Scan

    This is the normal right leg muscle model (including foot) of a 56 year old male with right anterior thigh pleomorphic leiomyosarcoma. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The lower leg is divided into four muscle compartments: the anterior, lateral, superficial posterior, and deep posterior compartments.  The anterior compartment is made from the dorsiflexors, including the tibialis anterior, extensor hallucis longus (EHL), extensor digitorum longus (EDL) and peroneus tertius, which are innervated by the deep peroneal nerve. The lateral compartment includes the peroneus longus and peroneus brevis, which assist in foot eversion and are innervated by the superficial peroneal nerve. The superficial posterior compartment includes the gastrocnemius, soleus, and plantaris, which assist in plantarflexion and are innervated by the tibial nerve.  The deep posterior compartment is made up of the popliteus, flexor hallucis longus (FHL), flexor digitorum longus (FDL), and tibialis posterior, which mostly assist in plantarflexion and are innervated similarly by the tibial nerve.
     
    This file was created from the file STS_014.

    21 downloads

       (0 reviews)

    0 comments

    Updated

  10. Free

    Right Leg Muscle Model 3D Printable STL File Converted from CT Scan

    This model is the right leg muscle rendering of a 65-year-old male with left thigh myxoid fibrosarcoma. At the time of diagnosis, the patient had metastases to his lungs. The patient therefore underwent neoadjuvant radiotherapy, surgery, and adjuvant chemotherapy and was found to have an intermediate grade lesion at the time of diagnosis. The patient is still living with the metastatic disease at 2.5 years since diagnosis. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The lower leg is divided into four muscle compartments: the anterior, lateral, superficial posterior, and deep posterior compartments.  The anterior compartment is made from the dorsiflexors, including the tibialis anterior, extensor hallucis longus (EHL), extensor digitorum longus (EDL) and peroneus tertius, which are innervated by the deep peroneal nerve. The lateral compartment includes the peroneus longus and peroneus brevis, which assist in foot eversion and are innervated by the superficial peroneal nerve. The superficial posterior compartment includes the gastrocnemius, soleus, and plantaris, which assist in plantarflexion and are innervated by the tibial nerve.  The deep posterior compartment is made up of the popliteus, flexor hallucis longus (FHL), flexor digitorum longus (FDL), and tibialis posterior, which mostly assist in plantarflexion and are innervated similarly by the tibial nerve.
     
    The primary motions of the ankle are dorsiflexion, plantarflexion, inversion and eversion. However, with the addition of midfoot motion (adduction, and abduction), the foot may supinate (inversion and adduction) or pronate (eversion and abduction). In order to accomplish these motions, muscles outside of the foot (extrinsic) and muscles within the foot (intrinsic) attach throughout the foot, crossing one or more joints.
     
    Laterally, the peroneus brevis and tertius attach on the proximal fifth metatarsal to evert the foot. The peroneus longus courses under the cuboid to attach on the plantar surface of the first metatarsal, acting as the primary plantarflexor of the first ray and, secondarily, the foot. Together, these muscles also assist in stabilizing the ankle for patients with deficient lateral ankle ligaments from chronic sprains. Medially, the posterior tibialis inserts on the plantar aspect of the navicular cuneiforms and metatarsal bases, acting primarily to invert the foot and secondarily to plantarflex the foot.  The flexor hallucis longus inserts on the base of the distal phalanx of the great toe to plantarflex the great toe, and the flexor digitorum inserts on the bases of the distal phalanges of the lesser four toes, acting to plantarflex the toes. The gastrocnemius inserts on the calcaneus as the Achilles tendon and plantarflexes the foot. Anteriorly, the tibialis anterior inserts on the dorsal medial cuneiform and plantar aspect of the first metatarsal base as the primary ankle dorsiflexor and secondary inverter. The Extensor hallucis longus and extensor digitorum longus insert on the dorsal aspect of the base of the distal phalanges to dorsiflex the great toe and lesser toes, respectively.
     
    This model was created from the file STS_022.

    20 downloads

       (0 reviews)

    0 comments

    Updated

  11. Free

    Left knee - Muscle model STL file from converted CT scan

    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_051   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: 

    19 downloads

       (0 reviews)

    0 comments

    Updated

  12. Free

    Muscles and soft tissues of the knee, with synovial sarcoma tumor

    This 3D printable STL model of the muscles and soft tissues of the knee was derived from the CT scan of a 22 year old female. The patient has a synovial sarcoma tumor involving the lateral thigh, in the vastus lateralus muscle near the attachment point at the knee.
     
    This model was created with the democratiz3D free online conversion tool.
     
    STS_004 0

    15 downloads

       (0 reviews)

    0 comments

    Updated

  13. Free

    Right Leg and Foot Normal Anatomy Muscle Model STL File Converted from CT Scan for 3D Printing

    This is the normal right leg muscle model (including foot) of an 82-year-old male. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The lower leg is divided into four muscle compartments: the anterior, lateral, superficial posterior, and deep posterior compartments.  The anterior compartment is made from the dorsiflexors, including the tibialis anterior, extensor hallucis longus (EHL), extensor digitorum longus (EDL) and peroneus tertius, which are innervated by the deep peroneal nerve. The lateral compartment includes the peroneus longus and peroneus brevis, which assist in foot eversion and are innervated by the superficial peroneal nerve. The superficial posterior compartment include the gastrocnemius, soleus, and plantaris, which assist in plantarflexion and are innervated by the tibial nerve.  The deep posterior compartment is made up of the popliteus, flexor hallucis longus (FHL), flexor digitorum longus (FDL), and tibialis posterior, which mostly assist in plantarflexion and are innervated similarly by the tibial nerve.
     
    This file was created from the file STS_013.

    12 downloads

       (0 reviews)

    0 comments

    Updated

  14. Free

    Right Knee Muscle Model 3D Printable STL File Converted from CT Scan

    This model is the right knee muscle rendering of a 65-year-old male with left thigh myxoid fibrosarcoma. At the time of diagnosis, the patient had metastases to his lungs. The patient therefore underwent neoadjuvant radiotherapy, surgery, and adjuvant chemotherapy and was found to have an intermediate grade lesion at the time of diagnosis. The patient is still living with the metastatic disease at 2.5 years since diagnosis. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The knee is a hinge joint that does not have true bony stabilization, so it requires soft tissue static and dynamic stabilizers to prevent excess motion through the joint. In addition, the knee goes through a “screw home” mechanism in which the tibia rotates externally and “locks” into extension during the last 15-20 degrees of extension. Multiple structures, therefore, are needed to work in concert to prevent excess strain through this joint during these daily motions.
     
    On the medial aspect of the knee, the static stabilizers consist of the superficial and deep medial collateral ligaments (MCL) and the posterior oblique ligament (POL). The dynamic stabilizers are the semimembranosus, vastus medialis, medial gastrocnemius, and pes tendons (semitendinosus, gracilis, and sartorius). The lateral stabilizers are best known as the posterolateral corner, and consist of the static stabilizers (lateral collateral ligament (LCL), iliotibial band (ITB), arcuate ligament), and dynamic stabilizers (popliteus, biceps femoris, lateral gastrocnemius). Inside the joint, the anterior cruciate ligament provides resistance to anterior tibial translation varus, and internal rotation, whereas the posterior cruciate ligament provides resistance to posterior tibial translation, varus, valgus, and external rotation.
     
    This model was created from the file STS_022.

    12 downloads

       (0 reviews)

    0 comments

    Updated

  15. Free

    Normal Left Foot and Ankle Muscle Model 3D Printable STL File Converted from CT Scan

    This model is the left foot and ankle muscle rendering of a 65-year-old male with left thigh myxoid fibrosarcoma. At the time of diagnosis, the patient had metastases to his lungs. The patient therefore underwent neoadjuvant radiotherapy, surgery, and adjuvant chemotherapy and was found to have an intermediate grade lesion at the time of diagnosis. The patient unfortunately died 9.5 months after diagnosis. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The primary motions of the ankle are dorsiflexion, plantarflexion, inversion and eversion. However with the addition of midfoot motion (adduction, and abduction), the foot may supinate (inversion and adduction) or pronate (eversion and abduction). In order to accomplish these motions, muscles outside of the foot (extrinsic) and muscles within the foot (intrinsic) attach throughout the foot, crossing one or more joints.
     
    Laterally, the peroneus brevis and tertius attach on the proximal fifth metatarsal to evert the foot. The peroneus longus courses under the cuboid to attach on the plantar surface of the first metatarsal, acting as the primary plantarflexor of the first ray and, secondarily, the foot. Together, these muscles also assist in stabilizing the ankle for patients with deficient lateral ankle ligaments from chronic sprains. Medially, the posterior tibialis inserts on the plantar aspect of the navicular cuneiforms and metatarsal bases, acting primarily to invert the foot and secondarily to plantarflex the foot.  The flexor hallucis longus inserts on the base of the distal phalanx of the great toe to plantarflex the great toe, and the flexor digitorum inserts on the bases of the distal phalanges of the lesser four toes, acting to plantarflex the toes. The gastrocnemius inserts on the calcaneus as the Achilles tendon and plantarflexes the foot. Anteriorly, the tibialis anterior inserts on the dorsal medial cuneiform and plantar aspect of the first metatarsal base as the primary ankle dorsiflexor and secondary inverter. The Extensor hallucis longus and extensor digitorum longus insert on the dorsal aspect of the base of the distal phalanges to dorsiflex the great toe and lesser toes, respectively.
     
    This model was created from the file STS_023.

    12 downloads

       (0 reviews)

    0 comments

    Updated

  16. Free

    fOOT 3D SCAN - stl file processed

    fOOT 3D SCAN - stl file processed
    3dmodel, foot, muscle, phalanx, metatarsal, stl, lower limb

    10 downloads

       (0 reviews)

    0 comments

    Updated

  17. Free

    Tutorial right thigh - processed

    Tutorial right thigh - processed, stl, lower, limb, stl, tigh, muscle, quadriceps, gluteus, 3dmodel

    9 downloads

       (0 reviews)

    0 comments

    Updated

  18. Free

    Left Thigh Muscle Model 3D Printable STL File Converted from CT Scan

    This is the normal left thigh muscle model of a 56 year old male with contralateral anterior thigh pleomorphic leiomyosarcoma. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The thigh is divided into three compartments: the anterior, posterior, and adductor. The anterior compartment contains the “quadriceps muscles”, made up of the vastus lateralis, vastus medialis vastus intermedius, and rectus femoris, and the sartorius. These muscles are innervated by the femoral nerve (L3-L4), and act to extend the leg. The Sartorius muscle originates at the ASIS and crosses anterior to the quadriceps muscle to insert on the medial tibia in the pes anserinus. The posterior compartment contains the “hamstrings”, made up of the semitendinosus, semimembranosus, and short and long heads of the biceps femoris. These muscles act to flex the leg. All of these muscles are innervated by the sciatic nerve (tibial division) except for the short head of the biceps femoris, which is innervated by the sciatic nerve (peroneal division). The adductor compartment contains the adductor longus, adductor brevis, adductor magnus, and gracilis, which act to adduct the thigh. These muscles are innervated by the obturator, and the adductor magnus has dual innervation with the sciatic nerve. In addition, the obturator externus (a thigh external rotator) and pectineus muscle (thigh flexor and adductor) are located within this compartment.
     
    This model was created from the file STS_014.

    9 downloads

       (0 reviews)

    0 comments

    Updated

  19. Free

    eu - stl file processed

    eu - stl file processed
    3dmodel, stl, muscle, tigh, testicles, penis,

    8 downloads

       (0 reviews)

    0 comments

    Updated

  20. Free

    3Dleg(muscles) - stl file processed

    3Dleg(muscles) - stl file processed

    Have embodi3D 3D print this model for you. Learn More. This file was created with democratiz3D. Automatically create 3D printable models from CT scans. Learn more.
     
    Gluteus medius muscle, Piriformis muscle, Gluteus maximus muscle, Levator ani muscle, Gemellus superior muscle, Obturator internus muscle, Adductor magnus muscle, Iliotibial tract, Gracilis muscle, Vastus lateralis muscle, Biceps femoris muscle, Semitendinosus, biceps femoris muscles, Rectus femoris muscle, Vastus intermedius muscle, Sartorius muscle, Semimembranosus muscle, Popliteus muscle, Gastrocnemius muscle, Tibialis posterior muscle, Tibialis anterior muscle, 3d, model, .stl, lower, limb, extremity, muscles,

    8 downloads

       (0 reviews)

    0 comments

    Updated

  21. Free

    Left Leg Muscle Model 3D Printable STL File Converted from CT Scan

    This model is the left leg muscle rendering of a 65-year-old male with left thigh myxoid fibrosarcoma. At the time of diagnosis, the patient had metastases to his lungs. The patient therefore underwent neoadjuvant radiotherapy, surgery, and adjuvant chemotherapy and was found to have an intermediate grade lesion at the time of diagnosis. The patient is still living with the metastatic disease at 2.5 years since diagnosis. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The lower leg is divided into four muscle compartments: the anterior, lateral, superficial posterior, and deep posterior compartments.  The anterior compartment is made from the dorsiflexors, including the tibialis anterior, extensor hallucis longus (EHL), extensor digitorum longus (EDL) and peroneus tertius, which are innervated by the deep peroneal nerve. The lateral compartment includes the peroneus longus and peroneus brevis, which assist in foot eversion and are innervated by the superficial peroneal nerve. The superficial posterior compartment includes the gastrocnemius, soleus, and plantaris, which assist in plantarflexion and are innervated by the tibial nerve.  The deep posterior compartment is made up of the popliteus, flexor hallucis longus (FHL), flexor digitorum longus (FDL), and tibialis posterior, which mostly assist in plantarflexion and are innervated similarly by the tibial nerve.
     
    The primary motions of the ankle are dorsiflexion, plantarflexion, inversion and eversion. However, with the addition of midfoot motion (adduction, and abduction), the foot may supinate (inversion and adduction) or pronate (eversion and abduction). In order to accomplish these motions, muscles outside of the foot (extrinsic) and muscles within the foot (intrinsic) attach throughout the foot, crossing one or more joints.
     
    Laterally, the peroneus brevis and tertius attach on the proximal fifth metatarsal to evert the foot. The peroneus longus courses under the cuboid to attach on the plantar surface of the first metatarsal, acting as the primary plantarflexor of the first ray and, secondarily, the foot. Together, these muscles also assist in stabilizing the ankle for patients with deficient lateral ankle ligaments from chronic sprains. Medially, the posterior tibialis inserts on the plantar aspect of the navicular cuneiforms and metatarsal bases, acting primarily to invert the foot and secondarily to plantarflex the foot.  The flexor hallucis longus inserts on the base of the distal phalanx of the great toe to plantarflex the great toe, and the flexor digitorum inserts on the bases of the distal phalanges of the lesser four toes, acting to plantarflex the toes. The gastrocnemius inserts on the calcaneus as the Achilles tendon and plantarflexes the foot. Anteriorly, the tibialis anterior inserts on the dorsal medial cuneiform and plantar aspect of the first metatarsal base as the primary ankle dorsiflexor and secondary inverter. The Extensor hallucis longus and extensor digitorum longus insert on the dorsal aspect of the base of the distal phalanges to dorsiflex the great toe and lesser toes, respectively.
     
    This model was created from the file STS_022.

    8 downloads

       (0 reviews)

    0 comments

    Updated

  22. Free

    Muscles and ligaments of the knee in a 64 year old man

    This 3D printable STL file contains a model of the muscles around the knee of a 64 year old man was derived from a real medical CT scan.
    This model was created using the democratiz3D free online 3D model creation service.
    STS006
     

    7 downloads

       (0 reviews)

    0 comments

    Updated

  23. Free

    Muscles of the thigh and knee in a 64 year old man.

    This 3D printable STL file contains a model of the muscles of the thigh and knee of a 64 year old man was derived from a real medical CT scan.
    This model was created using the democratiz3D  3D model creation service
    STS006

    6 downloads

       (0 reviews)

    0 comments

    Updated

  24. Free

    Muscles of the legs in a 64 year old man

    This 3D printable STL file contains a model of the legs was derived from a real medical CT scan. Its shows the muscles of the legs in great detail. Part of the table that the patient was scanned on is also included in the model and can be easily removed prior to 3D printing.
    This model was created using the democratiz3D free online 3D model creation service.
    STS006

    6 downloads

       (0 reviews)

    0 comments

    Updated

  25. Free

    Left Knee Muscle Model 3D Printable STL File Converted from CT Scan

    This is the normal left knee muscle model of a 56 year old male with right anterior thigh pleomorphic leiomyosarcoma. This is an STL file created from DICOM images of his CT scan which may be used for 3D printing.
     
    The knee is composed of 3 separate joints: two hinge joints (medial and lateral femorotibial joints), and one sellar, or gliding, joint (the patellofemoral joint). These also compose the three compartments of the knee: medial, lateral, and patellofemoral. Although the knee is thought of as a hinge joint, it actually has 6 degrees of motion: extension/flexion, internal/external rotation, varus/valgus, anterior/posterior translation, medial/lateral translation, and compression/distraction. In order to provide stability to this inherently unstable knee, static and dynamic stabilizers surround the knee, including muscles and ligaments.
     
    On the medial aspect of the knee, the static stabilizers consist of the superficial and deep medial collateral ligaments (MCL) and the posterior oblique ligament (POL). The dynamic stabilizers are the semimembranosus, vastus medialis, medial gastrocnemius, and pes tendons (semitendinosus, gracilis, and sartorius). The lateral stabilizers are best known as the posterolateral corner, and consist of the static stabilizers (lateral collateral ligament (LCL), iliotibial band (ITB), arcuate ligament), and dynamic stabilizers (popliteus, biceps femoris, lateral gastrocnemius). Inside the joint, the anterior cruciate ligament provides resistance to anterior tibial translation varus, and internal rotation, whereas the posterior cruciate ligament provides resistance to posterior tibial translation, varus, valgus, and external rotation.
     
    This model was created from the file STS_014.

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    • For this particular model, I used support on the build plate only and few small support enforcers for the overhanged parts of the big vessels. I also added a "box" support enforcer from the base to the level of the valves, because with support on the build plate only there is a small part of the aortic valve, which doesn't print well. With those settings, the entire athriums will be clean and the vessels will be steady. It requires to play a bit with the settings, but at the end the control over
    • Hi @valchanov and thank you! I was actually wondering where exactly you put the blockers... well I'm almost done my first print of this, and I just enabled support everywhere (but from bed only) so we'll see how it looks... I'm using MK3S and PrusaSlicer too.
    • On every slicer there is a "support blocker" function - you can add a simple object and in the volume of it the support won't be generated. On Cura it was bugged the last time I checked, but on Slicer it works great. Or you can select "support on build plate only" and then to add few "support enforcers" on the big vessels, which is the more elegant solution. Anyway, at the end the big vessels and the ventricles will be a hollow shell. 
    • Any tips on how you did the support blocking areas?
    • Wow, that is pretty cool! Thanks for sharing!
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