A 3D Printed Vitrification Device for Storage in Cryopreservation Vials

Liu, Yue; Lin, Andrew; Tiersch, Terrence R.; Monroe, W. Todd

doi:10.3390/app11177977

Cited by 11 publications

(7 citation statements)

References 38 publications

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“…Thus the CMAS was designed and fabricated as an open-technology platform that can serve as a starting point for further refinement and for future technology development. This device provides an opportunity to increase the reach of open technologies in the aquatic germplasm community [ 29 , 41 ]. It is a design amenable to open, distributed fabrication by 3-D printing, laser cutting, and hand-soldering.…”

Section: Discussionmentioning

confidence: 99%

An automated modular open-technology device to measure and adjust concentration of aquatic sperm samples for cryopreservation

Zuchowicz

Liu²,

Monroe³

et al. 2023

SLAS Technology

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Section: Discussionmentioning

confidence: 99%

An automated modular open-technology device to measure and adjust concentration of aquatic sperm samples for cryopreservation

Zuchowicz

Liu²,

Monroe³

et al. 2023

SLAS Technology

Self Cite

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“…With the rising popularity of low-cost resin printers, advances in LCD technologies will likely address these problems in the near future, and bring in next-generation resolution capabilities (e.g., 8K resolution). Approaches such as these can be especially powerful when presented in the form of open hardware by functioning as force multipliers in addressing large, intractable, global problems, such as ensuring quality management for germplasm repository development in aquatic species [43,44].…”

Section: Discussionmentioning

confidence: 99%

Low-Cost Resin 3-D Printing for Rapid Prototyping of Microdevices: Opportunities for Supporting Aquatic Germplasm Repositories

Zuchowicz

Belgodere

Liu

et al. 2022

Fishes

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Germplasm repositories can benefit sustainable aquaculture by supporting genetic improvement, assisted reproduction, and management of valuable genetic resources. Lack of reliable quality management tools has impeded repository development in the past several decades. Microfabricated open-hardware devices have emerged as a new approach to assist repository development by providing standardized quality assessment capabilities to enable routine quality control. However, prototyping of microfabricated devices (microdevices) traditionally relies on photolithography techniques that are costly, time intensive, and accessible only through specialized engineering laboratories. Although resin 3-D printing has been introduced into the microfabrication domain, existing publications focus on customized or high-cost (>thousands of USD) printers. The goal of this report was to identify and call attention to the emerging opportunities to support innovation in microfabrication by use of low-cost (<USD 350) resin 3-D printing for rapid prototyping. We demonstrate that low-cost mask-based stereolithography (MSLA) 3-D printers with straightforward modifications can provide fabrication quality that approaches traditional photolithography techniques. For example, reliable feature sizes of 20 µm with dimensional discrepancy of <4% for lateral dimensions and <5% for vertical dimensions were fabricated with a consumer-level MSLA printers. In addition, alterations made to pre-processing, post-processing, and printer configuration steps improved print quality as demonstrated in objects with sharper edges and smoother surfaces. The prototyping time and cost of resin 3-D printing (3 h with USD 0.5/prototype) were considerably lower than those of traditional photolithography (5 d with USD 80/prototype). With the rapid advance of consumer-grade printers, resin 3-D printing can revolutionize rapid prototyping approaches for microdevices in the near future, facilitating participation in interdisciplinary development of innovative hardware to support germplasm repository development for aquatic species.

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“…Specialized equipment was required to produce the master wafer molds. However, the evaluated designs can be used in open-hardware applications [45][46][47]. Advancements in 3-D printing have allowed for fabrication of microfluidic devices with consumer-level machines that cost <USD 400 [22,23].…”

Section: Discussionmentioning

confidence: 99%

Development of a Single-Piece Sperm Counting Chamber (SSCC) for Aquatic Species

Belgodere

Liu

Reich

et al. 2022

Fishes

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Accurate determination of sperm concentration in aquatic species is important for assisted reproduction and cryopreservation, yet is challenging as current counting methods are costly or not suitable for many species. The goal of this work was to develop a simple (single-piece and single-layer photolithography) sperm counting chamber (SSCC) for aquatic species. Goldfish (Carassius auratus) and zebrafish (Danio rerio) sperm were used for evaluation in the device, which was created with soft lithography. Four designs with different geometries were evaluated for counting accuracy. Open-corner and open-midpoint designs were the most accurate with no significant differences (P > 0.05) for most of the target sperm concentrations (0.5–1.0 × 108 cells/mL). The open-corner design was not significantly different from the Makler® counting chamber intended for human sperm cells (P = 0.6) but was significantly different from a hemocytometer (P < 0.001) intended for other cell sizes. Material cost of device production was USD 16 per unit, including photolithography supplies, glass slide and coverslip, and polydimethylsiloxane. The cost can be reduced to USD 2 per unit with repeated wafer casts. This device could be further refined for resin 3-D printing and sharing via open-hardware approaches and modified to best suit species specific applications.

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A 3D Printed Vitrification Device for Storage in Cryopreservation Vials

Cited by 11 publications

References 38 publications

An automated modular open-technology device to measure and adjust concentration of aquatic sperm samples for cryopreservation

An automated modular open-technology device to measure and adjust concentration of aquatic sperm samples for cryopreservation

Low-Cost Resin 3-D Printing for Rapid Prototyping of Microdevices: Opportunities for Supporting Aquatic Germplasm Repositories

Development of a Single-Piece Sperm Counting Chamber (SSCC) for Aquatic Species

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