Vacuum-assisted delivery is a medical procedure in which a vacuum device is used to guide the baby through the birth canal, when problems arise during the delivery. This device makes use of a hard plastic suction cup that is attached to the baby’s head. Excessive suction forces cause a cone-shaped swelling on the baby’s head, which increases the risk of bruising, bleeding in the skull and skull fracture.

In this graduation project, you will explore a 3D printed variable stiffness suction cup that can adapt to the shape of the baby’s head. You will be taking inspiration from animals with suction cups, such as the octopus, as those can perfectly adapt their discs to the objects they grasp. We want to use the form complexity of 3D printing to create the suction cup. This is an exploratory assignment, so we are looking for a creative student with an investigative, curious mind and experience with Solidworks.

Interested? Contact Vera Kortman (v.g.kortman@tudelft.nl) or Kirsten Lussenburg (k.m.lussenburg@tudelft.nl).

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[image courtesy of EOS]

This graduation assignment focuses on the design of a steerable needle for urology procedures, in specific prostate cancer treatment, with a focus on improving accuracy, precision, and patient comfort. The design of the needle will be inspired by the root system of plants, particularly how they extend and move through soil. The tip of the needle will have an extension that can be steered to the desired location within the prostate. 

The assignment involves designing, developing, and testing a novel steerable needle that allows for accurate needle positioning. We are looking for a student who is interested in a design-oriented project and who can start at short notice (i.e., spring or summer 2023). For this project, creative problem solving, SolidWorks, and 3D-printing skills, and an interest in medical topics would be useful. 

Interested? Please contact Jette Bloemberg, j.bloemberg@tudelft.nl, and/or Esther de Kater, e.p.dekater@tudelft.nl.

When a patient has a broken bone often a customized medical cast is made to immobilize that part of the body where the broken bone is located in order for the bone to heel. Every patient receives a custom made cast or a custom made splint. The cast is made by specialist in the hospital. During the heeling of the bone patients suffer from muscle atrophy because of the immobilization. This occurs typically after 5 days of immobilization. This can cause more space between the cast and part of the body of the patient where the cast is located. This can reduce the function of the cast. On the other hand is some mobilization helpful for the healing process.

In this graduation project, you will design an adjustable medical cast so that the immobilization is optimized and the muscle atrophy minimized.

Interested? Contact Karin Thomassen k.e.thomassen@tudelft

When a patient has a broken bone often a customized cast is made to immobilize that part of the body where the broken bone is located in order for the bone to heel. Every patient receives a custom made cast or a custom made splint. During the phase of immobilization most patients are not hospitalized. Therefor their physician cannot monitor the heeling process of the bone. What noninvasive device could help both patient and physician to get a better insight in the heeling progress during immobilization in order to minimize the immobilization phase so that complications like muscle atrophy is minimalized?

In this graduation project, you will design a non-invasive monitoring medical cast to inform both patient and physician about the progress of the healing of the bone.

Interested? Contact Karin Thomassen k.e.thomassen@tudelft

During spinal fusion surgery, multiple vertebrae are fused by fixating them together. The fixation of the vertebrae is achieved by placing screws through the pedicles of the vertebrae that are connected to rods. The fixation strength of the screw mainly relies on the contact area between the screw and the outer bone layer of the vertebra. This contact can only be achieved within the pedicle of the vertebra. However, even in the pedicle, this contact is limited due to the hourglass shape and oval cross-section of the pedicle.

In this graduation project, you will design a bone anchor that can adapt its shape in 3D to the pedicle of the vertebra to fixate to increase the contact area between the anchor and the cortical outer layer of the pedicle.

Interested? Contact Esther de Kater, E.P.dekater@tudelft.nl

During spinal fusion surgery multiple vertebrae are fused by fixating them together. The fixation of the vertebrae is achieved by placing screws through the pedicles of the vertebrae that are connected to rods. The rods run along the vertebrae and are embedded in the surrounding soft tissue. This can result in pain and irritation for the patient.

The vertebra grow together and form one bony mass in the first six months after surgery. During this period the forces acting on the fixation are substantial during daily activities. If the screw loosen during this period, the desired fusion cannot be achieved.

In this graduation project we will set the first steps in the direction of a new fixation method that is mainly located within the vertebra. The graduation projects focuses on the development of a drilling and/or anchoring system that can be used to create the desired fixation.

Interested? Contact Esther de Kater, E.P.dekater@tudelft.nl

The spine is the central support structure of the body that helps us humans sit, stand up and walk around, twist and bend. Age-related degeneration, but also congenital deformities can cause back pain and spinal instability, requiring surgical fixation of the spine. To guide the surgeon’s drill during spine surgery, the tissue in front of its tip is assessed with a fiber-optic sensing system, but we currently don’t know how to evaluate the recorded data.

The focus of this graduation project in collaboration with Philips Research will be to train a neural network with data from different tissues found in/around the spine to develop a classifier that will guide surgeons during spine surgery. This project does not require preliminary AI knowledge or programming skills, although knowing some python basics will be of use.

Interested? Contact Merle Losch, m.s.losch@tudelft.nl