Beads for Cell Immobilization: Comparison of Alternative Additive Manufacturing Techniques

Gatto, Maria Laura; Mengucci, P.; Munteanu, Daniel; Nasini, Roberto; Tognoli, Emanuele; Denti, Lucia; Gatto, Andrea

doi:10.3390/bioengineering10020150

Cited by 4 publications

(9 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…All benchmark masters were produced by the VPP process using an acrylic acid ester commercially known as VITRA DL375 (DWS, Thiene, Italy), as detailed in a previous paper by the authors [39] (VITRA DL375 specifications are listed in the Supplementary Materials [40]). In addition to the masters, the analysis of the replicas was a crucial aspect for validating the entire production process and guiding biotechnologists' decisions for production improvement, especially in the presence of significant variability in device dimensions and shapes.…”

Section: Benchmark Master Materialsmentioning

confidence: 99%

“…The objective is to significantly impact the time-to-market required for producing PDMS microfluidic devices. Three distinct benchmark masters (BM1, BM2, and BM3) were specifically designed to assess the feasibility and dimensional limits of ribs produced by VPP, employing a set of process parameters and a material that has been previously optimized and described by the authors [39]. Building upon the insights gained from BM1-BM3, two additional benchmark masters (BM4 and BM5) were designed for applications in the microfluidic field.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Features of Vat-Photopolymerized Masters for Microfluidic Device Manufacturing

Gatto,

Mengucci,

Mattioli-Belmonte

et al. 2024

Bioengineering

Self Cite

View full text Add to dashboard Cite

The growing interest in advancing microfluidic devices for manipulating fluids within micrometer-scale channels has prompted a shift in manufacturing practices, moving from single-component production to medium-size batches. This transition arises due to the impracticality of lab-scale manufacturing methods in accommodating the increased demand. This experimental study focuses on the design of master benchmarks 1–5, taking into consideration critical parameters such as rib width, height, and the relative width-to-height ratio. Notably, benchmarks 4 and 5 featured ribs that were strategically connected to the inlet, outlet, and reaction chamber of the master, enhancing their utility for subsequent replica production. Vat photopolymerization was employed for the fabrication of benchmarks 1–5, while replicas of benchmarks 4 and 5 were generated through polydimethylsiloxane casting. Dimensional investigations of the ribs and channels in both the master benchmarks and replicas were conducted using an optical technique validated through readability analysis based on the Michelson global contrast index. The primary goal was to evaluate the potential applicability of vat photopolymerization technology for efficiently producing microfluidic devices through a streamlined production process. Results indicate that the combination of vat photopolymerization followed by replication is well suited for achieving a minimum rib size of 25 µm in width and an aspect ratio of 1:12 for the master benchmark.

show abstract

Section: Benchmark Master Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Features of Vat-Photopolymerized Masters for Microfluidic Device Manufacturing

Gatto,

Mengucci,

Mattioli-Belmonte

et al. 2024

Bioengineering

Self Cite

View full text Add to dashboard Cite

show abstract

“…This material is made of Si-O and Si-C chains in a matrix of linear polymers, which enables the free exchange of molecules and low interfacial energy. Therefore, the cast material is not exposed to a reaction with the surface of the mold [ 81 , 82 , 83 , 84 , 85 , 86 , 87 , 88 , 89 , 90 ].…”

Section: A Review Of the Literaturementioning

confidence: 99%

Rapid Prototyping Technologies: 3D Printing Applied in Medicine

Oleksy,

Dynarowicz,

Aebisher

2023

Pharmaceutics

View full text Add to dashboard Cite

Three-dimensional printing technology has been used for more than three decades in many industries, including the automotive and aerospace industries. So far, the use of this technology in medicine has been limited only to 3D printing of anatomical models for educational and training purposes, which is due to the insufficient functional properties of the materials used in the process. Only recent advances in the development of innovative materials have resulted in the flourishing of the use of 3D printing in medicine and pharmacy. Currently, additive manufacturing technology is widely used in clinical fields. Rapid development can be observed in the design of implants and prostheses, the creation of biomedical models tailored to the needs of the patient and the bioprinting of tissues and living scaffolds for regenerative medicine. The purpose of this review is to characterize the most popular 3D printing techniques.

show abstract

“…For example, restraining the cells attachment to certain surfaces, directing cells growth and inducing cells differentiation are some of the main goals in designing complex 3D architectures for biomedical applications ( Liao et al, 2020 ; Paun et al, 2020a ; Sharaf et al, 2022 ). Until present, different cells entrapment techniques have been extensively studied regarding their ability to immobilize cells in different pathologies, such as cancer metastasis ( Ju et al, 2020 ; Preciado et al, 2021 ), microbial infections ( Li et al, 2021a ) or inflammation ( Schmidt and Wittrup, 2009 ), etc., as well as for tissue engineering applications (Khetan et al, 2009; Guvendiren and Burdick, 2012 ) or for “cell delivery” applications ( Gatto et al, 2023 ).…”

Section: Introductionmentioning

confidence: 99%

“…The cells are kept inside the device through physical immobilization ( Zhou et al, 2018 ; Shao et al, 2020 ; Veernala et al, 2021 ; Hasturk et al, 2022 ), extracellular‐matrix‐like adherence ( Rao and Winter 2009 ), specific antigen‐antibody recognition ( Roupioz et al, 2011 ; Boulanger et al, 2022 ), barrier containing ( Spagnolo et al, 2015 ; Larramendy et al, 2019 ; Li et al, 2021b ) and external stimuli‐activated entrapment ( Fu et al, 2008 ; Long et al, 2020 ), etc. The entrapment of cells can be switched on and off through enzymatic control ( Chen et al, 2003 ), pH variations ( Kocak et al, 2017 ), barrier containing ( Seifan et al, 2017 ; Larramendy et al, 2019 ; Gatto et al, 2023 ) or radiation switch ( Fu et al, 2008 ; Long et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Magnetically‐actuated microcages for cells entrapment, fabricated by laser direct writing via two photon polymerization

Popescu,

Calin,

Tanasa

et al. 2023

Front. Bioeng. Biotechnol.

View full text Add to dashboard Cite

The manipulation of biological materials at cellular level constitutes a sine qua non and provocative research area regarding the development of micro/nano‐medicine. In this study, we report on 3D superparamagnetic microcage‐like structures that, in conjunction with an externally applied static magnetic field, were highly efficient in entrapping cells. The microcage‐like structures were fabricated using Laser Direct Writing via Two‐Photon Polymerization (LDW via TPP) of IP‐L780 biocompatible photopolymer/iron oxide superparamagnetic nanoparticles (MNPs) composite. The unique properties of LDW via TPP technique enabled the reproduction of the complex architecture of the 3D structures, with a very high accuracy i.e., about 90 nm lateral resolution. 3D hyperspectral microscopy was employed to investigate the structural and compositional characteristics of the microcage‐like structures. Scanning Electron Microscopy coupled with Energy Dispersive X‐Ray Spectroscopy was used to prove the unique features regarding the morphology and the functionality of the 3D structures seeded with MG‐63 osteoblast‐like cells. Comparative studies were made on microcage‐like structures made of IP‐L780 photopolymer alone (i.e., without superparamagnetic properties). We found that the cell‐seeded structures made by IP‐L780/MNPs composite actuated by static magnetic fields of 1.3 T were 13.66 ± 5.11 folds (p < 0.01) more efficient in terms of cells entrapment than the structures made by IP‐L780 photopolymer alone (i.e., that could not be actuated magnetically). The unique 3D architecture of the microcage‐like superparamagnetic structures and their actuation by external static magnetic fields acted in synergy for entrapping osteoblast‐like cells, showing a significant potential for bone tissue engineering applications.

show abstract

Beads for Cell Immobilization: Comparison of Alternative Additive Manufacturing Techniques

Cited by 4 publications

References 29 publications

Features of Vat-Photopolymerized Masters for Microfluidic Device Manufacturing

Features of Vat-Photopolymerized Masters for Microfluidic Device Manufacturing

Rapid Prototyping Technologies: 3D Printing Applied in Medicine

Magnetically‐actuated microcages for cells entrapment, fabricated by laser direct writing via two photon polymerization

Contact Info

Product

Resources

About