Design, fabrication, and reduction to practice of milliscale membrane-free organ chip systems

January 2021

archives@tulane.edu / The goal of this research was to establish a novel digital manufacturing-based workflow for the fabrication of membrane free organ chip (MFOC) systems. This workflow is based on the implementation of top-down design, starting with CAD design of molds for MFOC components and can be conducted on a benchtop removing the need for cleanroom use. In conducting this research, a commercially available SLA printer was characterized and optimized for manufacturing molds suitable for MFOC fabrication. To achieve this, extensive research was required to determine printer resolution limits and work within the limitations of the resins available for printing. Specifically, the molds need to be flat and smooth in order to produce perfectly horizontal and transparent PDMS devices. Post-processing workflows were engineered to satisfy these MFOC design constraints. After establishing a reliable and reproducible workflow for MFOC fabrication, the focus of the research was reduction to practice, i.e. achieving a design that enables loading MFOC with patterned aqueous solutions with 100% success and a high degree of forgiveness. Key MFOC dimensions were systematically varied in a manner only possible with the rapid prototyping capability of DM in a series of experiments with a standardized injection test and success rate of loading as the primary output. With a robust MFOC design in place, more complex designs for tissue patterning applications were created, and advanced configurations for engineering patterned vascularized stromal tissues were tested and validated. Seqeuntial and simultaneous loading scenerios were imvestigated to better understand cell migration impedence in multi-gel lane devices. / 1 / William Bralower

SLA 3D Printing

Organ-Chip

Membrane-Free

Inkjet-Printed In-Vitro Organic Electronic Devices

Asghar, Hussain

09 1900

In-vitro electronic devices are promising to dynamically monitor minute-changes in biological systems. Electronic devices based on conducting polymers such as poly(3,4- ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) provide suitable and attractive substrates for biointerfacing. The soft polymer surface acts as a cushion for the living systems to interface while electronically detecting their properties. However, to this date, most bioelectronics devices have been fabricated via multi-step lithography techniques, which do not allow for mass fabrication and hence high throughput biosensing. Inkjet printing presents an alternative to fabricate organic bioelectronic devices. Besides being low-cost, inkjet printing allows to fabricate several devices in a short time with flexible design patterns and minimal material waste. Here, using inkjet printing, we fabricated PEDOT:PSS based organic electrochemical transistors (OECTs) for biomembrane interfacing. We optimized the deposition of various inks (silver nanoparticles (AgNPs), PEDOT:PSS, and the dielectric SU-8) used during the fabrication of these devices. We characterized the electrical characteristics of all-printed OECTs with various geometries and identified the high-performing ones. Due to the flexibility of ink optimization and design patterns, these all inkjet-printed electronic devices provide an alternative for mass production of biointerfacing platforms.

inkjet printing

printed organic electronics

in-vitro diagnostics

A co-culture microplate platform to quantify microbial interactions and growth dynamics

Jo, Charles

30 August 2019

This thesis reports the development of BioMe, a co-culture microplate platform that enables high-throughput, real-time quantitative growth dynamics measurements of interacting microbial batch cultures. The primary BioMe components can be 3D-printed, allowing ease of fabrication and DIY accessibility in the microbiome community. A pairwise 3D-printed iteration of the BioMe device was used in diffusion and co-culture experiments. Genetically engineered Escherichia Coli lysine and isoleucine auxotroph strains were used to characterize the diffusion of amino acids across the porous membranes. Results demonstrated a nonlinear relationship between growth rate and pore size and also distinct diffusion behavior for lysine and isoleucine. Pairwise syntrophic co-culture experiments demonstrated synergistic but repressed interaction between these two paired auxotrophs. Investigation of the effect of varying initial amino acid conditions on growth dynamics demonstrated that small changes in initial media condition can consistently affect patterns of yield and growth rate of constituent microbial species. / 2020-08-30T00:00:00Z

Biomedical engineering

3D-printing

Microbiome

Synthetic ecology

Comparison of the accuracy between 3D printed and milled dental models by a digital inspection software

Alvi, Shan

27 October 2017

STATEMENT OF PROBLEM: The production of full arch dental models through Rapid Additive Prototyping (3D Printing) have been questioned for their accuracy in the past decade. PURPOSE: To compare the accuracy of 3D printed and milled dental models, using a digital metrology software. MATERIALS AND METHOD: A mandibular arch typodont was duplicated to produce a conventional Type IV dental stone model. This Model was scanned to create a digital model and an STL file was created which would be sent to Milling and 3D printing machines.15 models were printed using 3 different 3D printing companies and 10 models Milled with a CNC (Computerized Numeric Controlled) milling machine. Each model was scanned and a digital model was created. These scanned models were then super imposed to the scan of the master model through an inspection software (Geomagic Control X, 3D Systems) for accuracy of production. RESULTS: The mean difference in measurement in Absolute Gap, by either of the two methods of prototyping adopted, (0.075 mm for 3D Printed and 0.084 mm for milled) are well below the clinically acceptable values mentioned in previous literature. The means in absolute tooth distance discrepancy for both prototyping methods (0.0361 mm for 3DPand 0.0353 mm for Milled) were not statistically significant. CONCLUSION: 3D printed dental models were more accurate statistically than milled dental models. In general, the mean accuracy for both methods of rapid prototyping is within clinical tolerance and both are clinically acceptable.

Dentistry

CAD/CAM

3D printing

Accuracy

Milling

Světlostálost inkoustového tisku / Lightfastness of inkjet prints

Buteková, Silvia

January 2010

The stability of inkjet print is influenced by a lot of factors. Just the surrounding environment in image stability plays an important role. When the prints fade, not only this does occur by light exposure, but also considerable effect has relative humidity, ozone and other air pollutants. The types of receiving layers or ink composition belong to other factors, which affect the stability of prints. This diploma thesis deals with the long-term ageing of digital prints produced by ink jet technology. The study of resistance of inkjet prints was realized on nine different types of media. Samples were prepared with use of dye-based and pigment-based inks. The attention was especially focused on the influence of light on print durability, but study was also oriented on the impact of ozone. The samples were exposed to the indoor daylight. Changes in printed colours were measured and evaluated in colorimetric quantities. In this study of inkjet prints degradation the dependence of colour gamut volumes on UV and VIS exposure dose was evaluated.

Spektrální analýza chemického kódu / Spectral analysis of chemical code

Šimončičová, Monika

January 2021

The diploma thesis deals with the study of the process of grinding aggregates of particles of a mixture of powdered lanthanide oxides in the dowanol solvent. The formed dispersions were characterised and used for the preparation of printing inks and subsequently for the printing of labels with chemical codes readable by XRF spectrometry. The aim was to study the milling process, to verify the reliability of reading and recognition of marks with the appropriate codes and to monitor the influence of the additive of the up-conversion powder on the resulting relative intensities of the elements in the chemical code. The statistical significance of the differences in the averages of relative intensities was assessed based on the Student's t test.

The efficacy of a scaffold-free Bio 3D conduit developed from human fibroblasts on peripheral nerve regeneration in a rat sciatic nerve model / ラット坐骨神経モデルにおけるヒト線維芽細胞を用いたscaffold-free Bio 3D conduitの末梢神経再生に対する有効性

Yurie, Hirofumi

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第21675号 / 医博第4481号 / 新制||医||1036(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 渡邉 大, 教授 林 康紀, 教授 井上 治久 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

3D printing

peripheral nerve

regeneration

490

Magnet-assisted Layer-by-layer Assembly on Nanoparticles Based on 3D-printed Microfluidic Devices

Cheng, Kuan

21 June 2019

No description available.

Polymers

Layer-by-layer

3D-printing

Microfluidic

Amphiphilic Triblock Copolymers for 3D Printable and Biodegradable Hydrogels

Wang, Zeyu

02 July 2020

No description available.

Polymers

Hydrogels

3D printing

biodegradable

block copolymer

Permeable Skin Patch with Miniaturized Octopus-Like Suckers for Enhanced Mechanics and Biosignal Monitoring

Alsharif, Aljawharah A.

02 May 2023

3D printed on-skin electrodes are of notable interest because, unlike traditional wet silver/silver chloride (Ag/AgCl) on-skin electrodes, they can be personalized and 3D printed using a variety of materials with distinct properties such as stretchability, conformal interfaces with skin, biocompatibility, wearable comfort, and, finally, low-cost manufacturing. Dry on-skin electrodes, in particular, have the additional advantage of replacing electrolyte gel, which dehydrates and coagulates with prolonged use. However, issues arise in performance optimization with the recently discovered dry materials. These challenges become even more critical when the on-skin electrodes are scaled down to a miniaturized size, making the detection of various biosignals while keeping mechanical resilience under several conditions crucial. Thus, this thesis focuses on designing, fabricating, optimizing, and applying a personalized, fully 3D-printed permeable skin patch with miniaturized octopus-like suckers and embedded microchannels for enhanced mechanical strengths, breathability, and biosignal monitoring. The developed device showcases a rapid, cost-effective fabrication process of porous skin patches and the printing process of ink metal-based materials that expands its applications to low-resource settings and environments.

3D Printing

Dry Electrodes

Biosignal Monitoring

Electrocardiogram