Publications and Case Studies

Art & Science Collaboration: "Living Data" of the Alpine Ibex Horn

2017 - 2018. Biomedical Modeling Inc. is excited to have collaborated with Boston based artist and Massachusetts College of Art and Design professor Edward Monovich on his "Living Data" sculpture exhibited at the University of Zurich (UZH) Zoological Museum. The work features a 5-foot tall, dramatically enlarged, 3D printed replication of an Alpine Ibex horn.

The sculpture calls attention to the detailed growth rings of the horn which also serve as a record for many types of environmental data from the animal's lifetime including: snowfall, vegetation protein content, temperature, and heterozygosity. An engraving along the length of the horn describes a theoretical, mathematical model predicting annual horn growth using these environmental factors.

 

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Biomodels in Stratasys J750 Launch

2016. Biomedical Modeling Inc. was asked by 3D printing giant, Stratasys, to design anatomical models for demonstrating the technical capabilities of its new J750 PolyJet 3D printer. It is the first high resolution 3D printer with full color (360,000 color combinations) and multiple materials. The printer can mix up to 6 materials including VeroClear and DigitalABS.

The models of the head, hand, and heart that we created were printed and featured in the launch of Stratasys' printer, including on the cover of their brochure. The models are intended as educational communication tools for illustrating human anatomy.

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Surgical Simulator for Spina Bifida Repair

2013. BMI worked with the University of Illinois, College of Medicine at Peoria to develop a medical simulator as a platform for training neurosurgery residents to correct the congenital spinal cord defect myelomeningocele (spina bifida cystica).

A technical brief of the project was published in the Journal of Medical Devices (Vol.7, Iss. 2) titled A Surgical Simulation Model for Myelomeningocele Repair. We also presented a poster on the project at the 2013 Design of Medical Devices Conference and recorded a video of the simulated surgery performed on the first prototype models.

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Biomodels for Improving Surgical Education and Clinical Practice

2011-2015. BMI worked with Harvard Medical School and Beth Israel Deaconess Medical Center on a feasibility study looking at opportunities for using 3D printing to enhance surgical education and clinical practice. Biomodels were created with the aim of serving as an educational reference to pathologic anatomy, improving communication between surgeons and patients, preoperative planning, and as an interaporative reference to aid decision making during surgery. Two of the models created as part of this study. An academic article discussing this project were published in SAGE journal Surgical Innovation" ( vol. 23 no. 2 189-195 ).

One of the 3D printed models used in this study was a model of a liver tumor, blood vessels adjacent to the tumor, and the liver parenchyma. The model was perceived to assist surgical planning and decision making between surgical resection and complete organ transplant.

The model was created as an assembly of three components: a single component containing the tumor and blood vessels and two 'halves' of a shelled wall representing the liver parenchyma. As an assembly model, the tumor mass and blood vessels could be both viewed within the anatomical context of its position in the liver, as well as more closely when disassembled from the liver.

Related articles in the press: Surgical Innovation Article: Three-Dimensional Modeling May Improve Surgical Education and Clinical Practice   | ( PDF of abstract ) Additive Manufacturing Users Group Recognizes Excellence   | ( PDF of article ) About AMUG (The Additive Manufacturing User Group)

Modern Anatomical Art: Matthew Day Jackson's Blockman

2010. BMI is always happy to work with modern artist Matthew Day Jackson in his various artistic ventures. Our most recent work with him revolved around the production of Blockman. BMI contributed to the production of sculpture piece which features a sharp-angle geometric rendering of the artist's skeleton built in rapid prototype epoxy material and embedded in lucite. Blockman was first on display among Jackson's In Search Of exhibit at the Peter Blum Chelsea Gallery in New York City.

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Inside Dentistry Journal Article About Biomodels

2006. Our BioDental models were featured in the dental journal Inside Dentistry.

Click the link below to read the article on the journal's website or contact us for a complimentary hard-copy:

King Tut Revealed

2005. A CT scan of Tutankhamen’s mummy was carried out in the Valley of the Kings by an all- Egyptian team led by Dr. Zahi Hawass, using a portable CT-scanner provided by the National Geographic Society and Siemens AG. The fragile body of the Pharaoh has lain undisturbed since it was last examined by Howard Carter in 1926, except for X-rays in 1978 and 1988. The CT-scan definitively disproved the popular theory that King Tut had been murdered by a blow to the head.

Khaled El-Said of Biomedical Modeling Inc led one of the three teams asked to reconstruct King Tut’s face. While the other teams used traditional methods of clay sculpture and silicone casting, our team generated digital reconstructions directly from the 1,700 CT images. After separating bone and dry skin structures in the CT scan, computer-generated 3D reconstructions were made of Tutankhamen’s skull.

The Pharaoh was classified as Caucasoid using forensic anthropology techniques, including craniometry. Skeletal and dentition development suggested he was 17-18 years old. Tissue depth markers were placed on the 3D skull to provide guidance for virtual reconstruction of his face. These facial reconstructions were made possible with the help of the Graphic Arts Unit of the Boston Police Department.

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Separation of Conjoined Twins

2002. In the summer of 2002, BMI undertook a most unusual and exciting case - the separation of conjoined twins from Guatemala, Maria Teresa and Maria de Jesus Quiej Alvarez. They were craniopagus twins – joined at the head – and were separated at UCLA on August 6 in a challenging operation. BMI contributed three Biomodels to UCLA for the girls. UCLA and Healing the Children are donating all of the surgical and medical care.

This project pushed the limits of modeling technology in that surgeons wanted both bone (hard tissue) and blood vessels (soft tissue) reproduced together in each Biomodel. One Biomodel was made of each of the twins' skulls, which could be studied separately or combined to provide the surgical team with a replica of the conjoined anatomy. The third Biomodel showed the region where the twins were joined, enabling the surgeons to easily see the architecture of arteries and veins.

The surgical team, headed by Drs. Henry Kawamoto and Jorge Lazareff, included more than 50 medical professionals. BMI’s Biomodels facilitated communication among the members of the team. The plastic surgeons used the Biomodels to plan the separation of the skulls and how to cut skin flaps to cover the girls’ brains. The neurosurgeons used Biomodels in planning the delicate reconstruction of the blood vessels so that each girl ended up with her own complete circulation. Biomodels played a key role in the rehearsal of the surgery and were taken into the OR for consultation during the procedure itself. Dr. Kawamoto felt that the Biomodels had been so valuable that he even called BMI the same day he completed the 23- hour operation.

Maria Theresa and Maria del Jesus are living at home with their family, and growing to be two beautiful, happy children babbling, eating and playing quite normally.

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