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  • Welcome to embodi3D Downloads! This is the largest and fastest growing library of 3D printable anatomic models generated from real medical scans on the Internet. A unique scientific resource, most of the material is free. Registered members can download, upload, and sell models. To convert your own medical scans to a 3D model, take a look at democratiz3D, our free and automated conversion service.

     

    Alert (6/17/22) - The democratiz3D scan-to-model conversion app is down due to a technical issue. We are working on a solution. 

Head and Neck

Vessels of the head and neck, including cerebral and carotids.

15 files

  1. $3

    Right middle cerebral artery bifurcation aneurysm

    By hozermd

    Right middle cerebral artery bifurcation aneurysm 3D smooth model. I haven't tried to print it, but I've printed the Willis polygon before. 

    3 downloads

       (0 reviews)

    0 comments

    Submitted

  2. Free

    Open Mouth Model

    By concioussedation

    Open Mouth Model

    8 downloads

       (0 reviews)

    0 comments

    Updated

  3. Free

    Conscious Sedation Head Model

    By concioussedation

    Intubation Head model

    6 downloads

       (0 reviews)

    0 comments

    Updated

  4. Free

    Vascular try - stl file processed

    By drdert

    Vascular try - 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.

    7 downloads

       (0 reviews)

    0 comments

    Submitted

  5. $9.99

    3d neck vasculature model (from real patient)

    By micamaca

    This 3D printable model of neck vasculature was generated from an real life patient MRI scan by clinical expert.
     
    The model comprise of 20 stl files:  one of all structures together (.stl), and following muscles as separate .stl files (provided in zip due to upload limitation): 
     
    1. Brachiocephalic trunk
    2. Common carotid artery
    3. Internal carotid artery
    4. External carotid artery
    5. Subclavian artery
    6. Vertebral artery
    7. Basilar artery
    8. Internal jugular vein
    9. Brachiocephalic vein
    10. Subclavian vein
    11. External jugular vein
    12. Posterior auricular vein
    13. Retromandibular vein (posterior branch)
    14. Facial vein
    15. Transverse cervical veins
    16. Superficial temporal veins
    17. Middle temporal vein
    18. Deep superficial veins
    19. Retromandibular vein (anterior branch)
     
    Mesh integrity: manifold STL (watertight), vtk
    Additional supports are needed to print the various components.

    2 downloads

       (0 reviews)

    0 comments

    Updated

  6. Free

    brainScan

    By wrathofheavennn

    ct scan of patient
     
    Callosomarginal artery, Anterior parietal artery,  Pericallosal artery, Posterior parietal artery, Pericallosal artery, Frontal polar artery, Precentral sulcal artery, Third segment of the anterior cerebral artery or pericallosal artery,  Artery of the angular gyrus,  Posterior temporal artery,  Prefrontal arteries,  Anterior choroidal artery,  Second segment of the anterior cerebral artery (from here on referred to as the pericallosal artery),  Second segment of the middle cerebral artery,  Anterior communicating artery of the cerebrum, First segment of the middle cerebral artery (sphenoid part),  Temporal polar artery, Frontal orbital artery, Ophthalmic artery, Internal carotid artery, Superior sagittal sinus, Parietal vein, Superior anastomotic vein (vein of Trolard), Occipital veins,  Inferior sagittal sinus, Internal cerebral vein, Superior thalamostriate veins, Vein of the septum pellucidum, Straight sinus,  Great cerebral vein of Galen,  Ascending frontal veins,  Basal vein of Rosenthal,  Inferior anastomotic vein (vein of Labbé),  Veins of the fossa of Sylvius,  Confluence of sinuses,  Cavernous sinus (anterior drainage),  Transverse sinus,  Superior petrosal sinus,  Cavernous sinus (posterior drainage),  Sigmoid sinus,  Inferior petrosal sinus,  Occipital sinus,  Pterygoid plexus,  Internal jugular vein, MRI, MRA, with, contrast, .stl, 3d, model, printable, printing, head, skull

    34 downloads

       (0 reviews)

    0 comments

    Updated

  7. Free

    Mr head - stl file processed

    By haritonovs.arturs@gmail.co

    Mr head - 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.
     
    Parieto-occipital artery,  Dorsal corpus callosal branch , Calcarine branch of the medial occipital artery,  Choroidal arteries (posterior,
    medial, and lateral), Temporo-occipital artery,  Posterior cerebral artery, Branches of the posterior cerebral, artery to the thalamus, Posterior communicating artery,  Superior cerebellar artery,  Basilar artery,  Anterior inferior cerebellar artery,  Posterior inferior cerebellar artery,  Vertebral arteries, vascular, 3D, model printable, printing, medical, medicine,

    32 downloads

       (0 reviews)

    0 comments

    Updated

  8. $14.99

    3d brain vasculature model

    By micamaca

    This dataset includes a large array of arteries (and some veins) in the brain.
    Right hand side is highly detailed, left hand side more simple segmentation showing divisions of the major arteries. 
     
    Mesh integrity: manifold STL (watertight)
    Additional supports are needed to print the various components.
    The model comprise of 75 .stl files: one stl file that includes all arteries and veins together and 74 separate files of following arteries and veins:

    1. Paraopthalmic part of right internal carotid artery
    2. Posterior communicating part of right internal carotid artery
    3. Anterior choroidal part of the right internal carotid artery
    4. Right carotid terminus
    5. Right M1
    6. Right posterior communicating artery
    7. Right P1
    8. Right P2
    9. Left P1
    10. Left posterior communicating artery
    11. Left P2
    12. Right A1
    13. Anterior communicating artery (partially fenestrated, variant)
    14. Right A2
    15. Left paraopthalmic part of the internal carotid
    16. Left opthalmic artery
    17. Left posterior communicating part of the internal carotid
    18. Left anterior choroidal artery part of the internal carotid
    19. Left carotid terminus
    20. Left A1
    21. Left A2
    22. Right opthalmic artery
    23. Left M1
    24. Right anterior choroidal artery
    25. Right posteromedial central arteries
    26. Right superior cerebellar artery
    27. Right paramedian artery branch
    28. Left anterior choroidal artery
    29. Right medial frontobasal artery
    30. Left medial orbitofrontal artery
    31. Left polar frontal artery
    32. Right polar frontal artery
    33. Left pericallosal artery
    34. Left callosomarginal artery (A3/4)
    35. Right callosomarginal artery (A3/4)
    36. Right anterior internal frontal artery
    37. Left anterior internal frontal artery
    38. Right intermediate internal frontal artery
    39. Left intermediate internal frontal artery
    40. Basilar artery
    41. Insular segment of the right middle cerebral artery
    42. Insular branches of the left middle cerebral artery (M3/M4)
    43. Right lenticolstriate arteries
    44. Left posteromedial central arteries
    45. Right anterior insular part of middle cerebral artery (M2/M3/M4)
    46. Right middle meningeal artery
    47. Right prefrontal artery
    48. Right artery of precentral gyrus
    49. Right artery of central sulcus
    50. Right polar temporal artery
    51. Right temporal branch
    52. Right anterior temporal artery branch
    53. Right middle temporal artery branch
    54. Right posterior parietal artery
    55. Right posterior temporal artery branch of the MCA
    56. Right parietal branches of the middle cerebral artery
    57. Right posterior insular part of the middle cerebral artery
    58. Right superior terminal branch of the middle cerebral artery
    59. Superior sagittal sinus
    60. Right posterior temporal branches of the PCA
    61. Right medial occipital artery
    62. Right precuneal branches
    63. Right calcarine branches
    64. Right parietooccipital branches
    65. Left P3
    66. Left P4/P5
    67. Left M2-branches
    68. Left M3/M4
    69. Right parietal cortical branches of the insular part of the middle
    cerebral artery
    70. Right superior cerebellar artery (duplication, variant)
    71. Left superior cerebellar artery
    72. Left lenticulostriate arteries
    73. Right lateral frontobasal artery
    74. Left middle meningeal artery
     
    They are included into .zip file due to upload limit of 10 files. 
     
     

    28 downloads

       (0 reviews)

    1 comment

    Updated

  9. Free

    Brain and neck CTA - stl file processed

    By Reginasa

    Brain and neck CTA - 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.

    14 downloads

       (0 reviews)

    0 comments

    Submitted

  10. Free

    not

    By zykiria minto

    nothing like 

    0 downloads

       (0 reviews)

    0 comments

    Submitted

  11. Free

    abc - stl file processed

    By Lisowczyk

    abc - 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.

    1 download

       (0 reviews)

    0 comments

    Submitted

  12. Free

    NPS

    By zhengxiong.wong

    NPS

    2 downloads

       (0 reviews)

    0 comments

    Updated

  13. $6

    internal carotid artery C1 to C7 and M1 to M2

    By simonsheng

    This is an 1:1 Internal carotid arteries model that was reconstructed based on CT images and medical research documents, as the model shows, the reconstructed parts are C1 to C7 and M1 to M2, with accurate gradient exterior and interior diameter, this model can also be used as training model.
     
    internal, carotid, artery, ica, base, skull, .stl, 3d, model, printable, vascular, carotid, cervical, petrous, cavernous, supraclinoid, M1, M2, middle, cerebral, artery, mca, head, bone, ridge, foramina, foramen, frontal, temporal, clinoid, apophysis, cranial, fossa, anterior, posterior, clivus, magnum, zygomatic, arch, incisor, molar, premolar, canine, teeth, tooth, maxillofacial, orbit, nasal, lacrimonasal, paranasal, sinuses, sphenoid, ethmoid, lower, turbinates, hard, palate,
     
    Items:Half Skull(Left and Right), ICA(Left and Right)
    Scale: (1:1)
     
     
     
     
     
     

    343 downloads

       (0 reviews)

    6 comments

    Updated

  14. Free

    abhi

    By ANUSHKA

    arteries
    I10.nrrd, angiography, stl, 3d, model, carotid, commun, external, internal, cerebellar, artery, anteroinferior, posteroinferior, basilar, pontine, middle, cerebral, anatomy normal, anterior, cerebral, posterior, vessels, aorta, arch, cerebellar.

    35 downloads

       (0 reviews)

    0 comments

    Updated

  15. Free

    CNS_Venography_3D_SR_Nevit_Dilmen.stl

    By nevitdilmen

    The Venous Drainage of the Central Nervous System.  Model from MRI data. Anatomy plate from Gray's Anatomy.

    132 downloads

       (0 reviews)

    0 comments

    Submitted

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    • Hermione
      Temperature Control Software for Core XY 3D Printers: A Comprehensive Guide

      By Hermione · Posted

      This article provides an in-depth exploration of temperature control software for Core XY 3D printer, its importance, functionalities, and how it can enhance the printing process. Understanding Temperature Control in 3D Printing In 3D printing, precise temperature control is critical for the following reasons: Hotend Temperature: The hotend melts the filament, and controlling its temperature ensures the filament flows consistently and smoothly. Inconsistent hotend temperatures can result in issues such as under-extrusion, over-extrusion, stringing, and layer separation. Heated Bed Temperature: The heated bed prevents warping by keeping the printed object’s base warm, ensuring strong adhesion to the print surface. If the bed temperature is too low, prints may not stick properly, leading to warping and failed prints. Conversely, if the temperature is too high, it can cause over-adhesion, making parts difficult to remove. Cooling Systems: Cooling fans are often overlooked, but they play a crucial role in controlling the temperature of the printed layers. Cooling too quickly or too slowly can impact layer adhesion, print quality, and overall strength. For Core XY printers, which are designed for high precision and speed, temperature control becomes even more critical to ensure that prints are both accurate and durable. Importance of Temperature Control Software The role of temperature control software in Core XY 3D printing is to automate and optimize the heating and cooling processes of both the hotend and heated bed. Without proper software, maintaining a stable temperature can be difficult, leading to uneven extrusion and poor-quality prints. Advanced temperature control software comes with the ability to: Maintain Consistent Temperature: Software that monitors and adjusts temperature in real-time prevents fluctuations that could negatively affect print quality. Optimize Material-Specific Settings: Different filaments such as PLA, ABS, PETG, or TPU require specific temperature ranges for optimal printing. Temperature control software can store preset values and automatically adjust the printer’s settings to suit the material being used. Improve Print Speed and Quality: Core XY printers are capable of high-speed printing, but rapid movements can lead to temperature drops in the hotend. Software helps to maintain stable temperatures during high-speed prints, resulting in consistent extrusion and higher print quality. Prevent Overheating and Thermal Runaway: Safety is another key factor. Temperature control software can detect overheating and prevent dangerous scenarios like thermal runaway, where unchecked temperatures cause equipment damage or fire hazards. Adaptive Temperature Adjustment: Some software includes features that adjust temperatures dynamically based on the size, complexity, or layer height of the print, ensuring optimal settings throughout the print job. Types of Temperature Control Software for Core XY Printers There are several types of software used to manage and optimize temperature control in Core XY 3D printers. These include: Firmware-Based Control: The firmware of a 3D printer, such as Marlin, RepRap, or Klipper, is where basic temperature control is handled. This software communicates directly with the hardware and allows users to set and monitor temperatures through G-code commands. Firmware is responsible for executing commands to control the hotend and heated bed, ensuring temperatures stay within the designated range throughout the print. Firmware-based control provides basic temperature management, but it also includes advanced features such as PID tuning (Proportional, Integral, Derivative). PID tuning ensures that temperature fluctuations are minimized and that the hotend and bed quickly reach and maintain the set temperature without overshooting or oscillating. Slicing Software: Temperature control is also managed through slicing software like Cura, PrusaSlicer, or Simplify3D. These programs allow users to define specific temperatures for both the hotend and heated bed based on the filament type and desired print quality. Slicing software communicates these settings to the printer via G-code, ensuring that the printer follows precise temperature instructions throughout the print job. Slicing software typically includes the ability to control temperatures for different stages of the print, such as: First Layer: The initial layer may require a higher bed temperature to ensure proper adhesion. Subsequent Layers: Temperatures may be lowered after the first few layers to prevent warping or over-adhesion. Cooling Settings: Slicing software often includes controls for fan speeds, which can be adjusted dynamically based on the layer height or complexity of the print. Real-Time Monitoring and Control Software: Programs such as OctoPrint, Repetier-Host, or MatterControl provide real-time monitoring and control over 3D printer temperatures. These programs allow users to connect to their Core XY printer remotely, adjust temperatures on-the-fly, and view temperature charts to ensure consistency. These programs often integrate with temperature sensors and webcams, offering users full control and oversight during the printing process. Features like thermal graphs help users visualize the performance of the hotend and bed, while alerts and notifications can warn of potential temperature-related issues. Standalone Temperature Controllers: Some users opt for standalone temperature controllers that can be connected directly to the printer. These controllers provide more precise control over temperature settings, independent of the printer’s firmware or slicing software. This can be particularly useful in industrial settings where ultra-precise temperature control is required. Advanced Features in Temperature Control Software for Core XY Printers Modern temperature control software includes several advanced features that improve print quality and reliability. Here are some of the key functionalities: PID Autotuning: PID autotuning is an advanced algorithm used in most temperature control systems to automatically fine-tune the hotend and heated bed’s temperature response. By running a PID autotune command, the printer will heat the hotend or bed multiple times, measure the response, and adjust the PID settings to reduce temperature oscillation. This results in faster and more accurate heating. Multiple Temperature Zones: Some temperature control software supports the use of multiple temperature zones within a print job. For example, the hotend temperature may need to be adjusted depending on the layer height or print speed. Multiple zones allow for greater flexibility and can improve print quality by tailoring the temperature profile to the specific needs of different sections of the print. Smart Cooling: Cooling is just as important as heating when it comes to print quality. Advanced temperature control software can dynamically adjust cooling fan speeds based on the complexity of the print, the filament material, or the print height. Smart cooling algorithms prevent warping and improve layer adhesion by optimizing the cooling rate in real-time. Temperature Ramping: Temperature ramping is another advanced feature that gradually increases or decreases the temperature of the hotend or bed over time. This feature is useful when printing large objects or materials that require slower temperature changes to avoid cracking or warping. 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Best Practices for Temperature Control in Core XY 3D Printers To achieve optimal temperature control in Core XY 3D printers, consider the following best practices: Perform Regular PID Tuning: Over time, the performance of the hotend and heated bed can change due to wear and tear or environmental factors. Performing regular PID tuning ensures that the printer maintains accurate and consistent temperatures. Use Material-Specific Temperature Settings: Different filament types require different temperature settings. Using temperature control software that allows for easy switching between profiles for PLA, ABS, PETG, TPU, or exotic materials ensures the best print quality and prevents material-related issues like warping or stringing. Monitor Temperature Graphs: Real-time temperature graphs provide valuable insight into the performance of the hotend and bed during a print. Monitoring these graphs allows users to spot inconsistencies or temperature drops and make adjustments as needed. 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      I want to order a 3D print of my spinal model but I don't see an option to order?

      By Retsuko · Posted

      I want to order a medical 3D print of my spine but I don't see anywhere on the site where I can order it. There isn't any "3D print this file" button next to the download button, as exhibited in the attached video.    There's little information here either: https://www.embodi3d.com/medical-3d-printing-service/   I had no problem finding it back in 2021, I'm unsure what changed.  
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