Conference Agenda

Overview and details of the sessions of this conference. Please select a date or location to show only sessions at that day or location. Please select a single session for detailed view (with abstracts and downloads if available).

Please note that all times are shown in the time zone of the conference. The current conference time is: 4th Aug 2021, 12:42:02am CEST

 
 
Program for LiM 2021
Session
Additive Manufacturing: Medical Applications
Time:
Thursday, 24/June/2021:
10:00am - 11:00am

Session Chair: Dr. Florian Klämpfl, Institute of Photonic Technologies (LPT), Germany
Location: Room 3
ICM Ground Floor 125

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Presentations
10:00am - 10:30am

Invited Talk: Selective laser sintering 3D printing of bespoke medications

Atheer Awad

University College London, United Kingdom

3D printing is a rapid manufacturing technology that has found promising applications in many fields, including pharmacy. In particular, laser-based technologies enable the creation of precise and intricate structures, potentially causing a paradigm shift in medicine design, manufacture and use. As an example, early-phase drug development (such as preclinical studies and first-in-human trials) could be expedited by using these technologies to rapidly produce formulations with excellent dose flexibility at low cost, on demand. Similarly, they could support formulation development because they have the capability to produce rapid product iterations for testing, such as excipient compatibility and drug release. Within hospitals and pharmacies, such technologies could accelerate the field of personalised medicine by moving treatment away from a ‘one size fits all approach’ towards personalisation. This presentation will give an overview on the use of a laser-based 3D printing technology and its promising applications, highlighting its potential in personalising medications.



10:30am - 10:45am

Laser directed energy deposition produces improved cp Ti for dental prosthetic applications

Óscar Barro1,2, Felipe Arias-González3, Fernando Lusquiños1,5, Rafael Comesaña4, Jesús del Val1, Antonio Riveiro4, Aida Badaoui4, Félix Gómez-Baño2, Juan Pou1,5

1CINTECX, University of Vigo, LaserON Research Group, Vigo, SPAIN; 2Corus-Fegoba, A Coruña, SPAIN; 3School of Dentistry, Universitat Internacional de Catalunya, Barcelona, SPAIN; 4Materials Engineering, Applied Mechanics and Construction Department, University of Vigo, Vigo, SPAIN; 5Galicia Sur Health Research Institute (IIS Galicia Sur), SERGAS-UVIGO, Vigo, SPAINin

Titanium and titanium alloys are widely employed in biomedical applications by virtue of their remarkable corrosion resistance, biocompatibility, exceptional specific strength and relatively low elastic modulus. Commercially pure titanium (cp-Ti) is a designation for titanium with reduced content of alloying elements, having a great resistance to corrosion and reduced cytotoxicity.

Laser directed energy deposition (LDED) is an additive manufacturing method able to produce metallic materials of great quality. By controlling the cooling rates, the material microstructure can be tuned in order to improve its mechanical/chemical properties. In the present work, LDED using a high power diode laser as energy source, was used to produce cp-Ti parts of grade 4. The cp-Ti obtained by LDED showed a higher mechanical performance than the commercial counterpart: 7% increment of ultimate tensile strength and 30% increment of toughness. These results can be attributed to a specific microstructure modification inherent to the LDED process.



10:45am - 11:00am

Additive manufacturing for minimally invasive endomicroscopy

Robert Kuschmierz, Elias Scharf, Jürgen Czarske

TU Dresden, Germany

Miniaturized flexible endoscopes employ coherent fiber bundles (CFB) to transfer intensity information by using lenses. This increases the footprint of the endoscope to several millimeters. Furthermore, the phase information of the light is distorted during transfer due to manufacturing errors of the CFB, which limits the endoscope to 2D imaging. Calibrating and compensating the phase distortion allows for lens less imaging. We present, the use of additive manufacturing to apply diffractive optical elements (DOE) onto the fiber facet for phase compensation. Using 2P-polymerization axial resolutions better than 20 nm can be achieved. This enables robust and cost efficient, endoscopes for 3D imaging. The influence of the DOE quality especially the axial resolution towards the image quality is discussed. With a total diameter below 400 µm, novel applications for instance for in-vivo cancer diagnostics in the brain can be envisioned.



 
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