Low-Cost Passive Sampling Device with Integrated Porous Membrane Produced Using Multimaterial 3D Printing

Kalsoom, Umme; Hasan, Chowdhury Kamrul; Tedone, Laura; Desire, Christopher T.; Li, Feng; Breadmore, Michael C.; Nesterenko, Pavel N.; Paull, Brett

doi:10.1021/acs.analchem.8b02893

Cited by 57 publications

(39 citation statements)

References 51 publications

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“…Relying on the porous property of the printing material, separation membranes can be fabricated directly via different 3D printing techniques. Breadmore's group utilized an FDM 3D printer for direct separation membrane fabrication [32,36–38]. A microfluidic device with a printed integrated membrane was fabricated using a multi‐material FDM printer for direct colorimetric analysis of nitrate in the soil as shown in Figure 3.…”

Section: D Printed Separation Membranesmentioning

confidence: 99%

“…The pore size of the membrane was examined to be 12 nm, and it was shown to filter out big particles from the soil and extract nitrate ions, which facilitated the direct soil analysis without sample pretreatment [32]. Another similar passive sampling device with an integrated membrane was also fabricated for extraction of atrazine from water prior to GC–MS analysis [36].…”

Section: D Printed Separation Membranesmentioning

confidence: 99%

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3D Printing in analytical sample preparation

Ceballos

Balavandy

et al. 2020

J of Separation Science

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In the last 5 years, additive manufacturing (three-dimensional printing) has emerged as a highly valuable technology to advance the field of analytical sample preparation. Three-dimensional printing enabled the cost-effective and rapid fabrication of devices for sample preparation, especially in flow-based mode, opening new possibilities for the development of automated analytical methods. Recent advances involve membrane-based three-dimensional printed separation devices fabricated by print-pause-print and multi-material three-dimensional printing, or improved three-dimensional printed holders for solid-phase extraction containing sorbent bead packings, extraction disks, fibers, and magnetic particles. Other recent developments rely on the direct three-dimensional printing of extraction sorbents, the functionalization of commercial three-dimensional printable resins, or the coating of three-dimensional printed devices with functional micro/nanomaterials. In addition, improved devices for liquid-liquid extraction such as extraction chambers, or phase separators are opening new possibilities for analytical method development combined with high-performance liquid chromatography. The present review outlines the current state-of-the-art of three-dimensional printing in analytical sample preparation. K E Y W O R D S3D printing, liquid-liquid extraction, membrane separation, sample preparation, solid-phase extraction 1854

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Section: D Printed Separation Membranesmentioning

confidence: 99%

Section: D Printed Separation Membranesmentioning

confidence: 99%

3D Printing in analytical sample preparation

Ceballos

Balavandy

et al. 2020

J of Separation Science

Self Cite

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“…Fused deposition modeling (FDM) printers (Figure 3C ) are the most common to begin with in a medical or dental set-up owing to its wide availability, moderately reliable printing quality, ease of installation, and use and economic affordability (Huang et al, 2017 ). It is competent with a number of materials like acrylonitrile butadiene styrene (ABS) and polylactic acid (PLA) (Kalsoom et al, 2018 ). The spooled material is supplied into a hot nozzle, melting and extruding it in the X-Y dimensions, one layer at a time, before the nozzle is elevated or the print bed drops down (Figure 3C ).…”

Section: Introductionmentioning

confidence: 99%

“…It is the printer of choice for the in house production of easily accessible anatomical models, but for complex anatomies, the higher printing time, limited color selection, moderate printing resolution and complete removal of the support material are technical limitations (Huang et al, 2017 ). Both SLS and SLA (Figures 3D,E ) use laser to scan and build the object layer-by-layer, while SLS uses powder-based material for printing the object, SLA is based on a liquid resin material (Mazzoli, 2013 ; Kalsoom et al, 2018 ). It overcomes the printing resolution and support material limitations of the FDM, however, object shrinkage is a matter of concern.…”

Section: Introductionmentioning

confidence: 99%

3D Printing—Encompassing the Facets of Dentistry

Oberoi

Nitsch

Edelmayer

et al. 2018

Front. Bioeng. Biotechnol.

170

125

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This narrative review presents an overview on the currently available 3D printing technologies and their utilization in experimental, clinical and educational facets, from the perspective of different specialties of dentistry, including oral and maxillofacial surgery, orthodontics, endodontics, prosthodontics, and periodontics. It covers research and innovation, treatment modalities, education and training, employing the rapidly developing 3D printing process. Research-oriented advancement in 3D printing in dentistry is witnessed by the rising number of publications on this topic. Visualization of treatment outcomes makes it a promising clinical tool. Educational programs utilizing 3D-printed models stimulate training of dental skills in students and trainees. 3D printing has enormous potential to ameliorate oral health care in research, clinical treatment, and education in dentistry.

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“…This is an emerging platform for the production of low-cost novel 3D-printed sorbents using an FDM printer. These materials are advantageous over solid-phase extraction and liquid-liquid extraction in terms of accuracy due to reproducibility and less carry-over, costs, and time consumption [12,13]. Similar elastomer PVA-based 3D-printed materials like Poro-Lay find application in passive sampling devices.…”

Section: Introductionmentioning

confidence: 99%

The impact of 3D-printed LAY-FOMM 40 and LAY-FOMM 60 on L929 cells and human oral fibroblasts

et al. 2020

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Objectives LAY-FOMM is a promising material for FDA-approved Fused Deposition Modeling (FDM) applications in drug delivery. Here we investigated the impact on oral cells. Materials and methods We evaluated the impact of 3D-printed LAY-FOMM 40, LAY-FOMM 60, and biocompatible polylactic acid (PLA) on the activity of murine L929 cells, gingival fibroblasts (GF), and periodontal ligament fibroblasts (PDLF) using indirect (samples on cells), direct monolayer culture models (cells on samples), and direct spheroid cultures with resazurin-based toxicity assay, confirmed by MTT and Live-dead staining. The surface topography was evaluated with scanning electron microscopy. Results The materials LAY-FOMM 40 and LAY-FOMM 60 led to a reduction in resazurin conversion in L929 cells, GF, and PDLF, higher than the impact of PLA in indirect and direct culture models. Fewer vital cells were found in the presence of LAY-FOMM 40 and 60 than PLA, in the staining in both models. In the direct model, LAY-FOMM 40 and PLA showed less impact on viability in the resazurin-based toxicity assay than in the indirect model. Spheroid microtissues showed a reduction of cell activity of GF and PDLF with LAY-FOMM 40 and 60. Conclusion Overall, we found that LAY-FOMM 40 and LAY-FOMM 60 can reduce the activity of L292 and oral cells. Based on the results from the PLA samples, the direct model seems more reliable than the indirect model. Clinical relevance A material modification is desired in terms of biocompatibility as it can mask the effect of drugs and interfere with the function of the 3D-printed device.

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Low-Cost Passive Sampling Device with Integrated Porous Membrane Produced Using Multimaterial 3D Printing

Cited by 57 publications

References 51 publications

3D Printing in analytical sample preparation

3D Printing in analytical sample preparation

3D Printing—Encompassing the Facets of Dentistry

The impact of 3D-printed LAY-FOMM 40 and LAY-FOMM 60 on L929 cells and human oral fibroblasts

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