Low-cost 3D printed lenses for brightfield and fluorescence microscopy

Christopher, Jay; Rooney, Liam M.; Donnachie, Mark; Uttamchandani, Deepak; McConnell, Gail; Bauer, Ralf

doi:10.1101/2023.11.22.568227

Cited by 3 publications

(1 citation statement)

References 30 publications

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“…The demonstrated optical performance of 3D printed lenses shows great promise for optical imaging and prototyping optical instrumentation. Moreover, we have shown separately that 3D printed lenses can be implemented in bioimaging applications, using both absorption and fluorescence imaging modalities [50]. The potential impact of these accessible and open manufacturing methods could also impact across low resource settings for rapid diagnostics of blood smears, for example, where 3D printing has already made significant impacts.…”

Section: Discussionmentioning

confidence: 99%

Printing, Characterising, and Assessing Transparent 3D Printed Lenses for Optical Imaging

Rooney,

Christopher,

Watson

et al. 2023

Preprint

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High-quality lens production has involved subtractive manufacturing methods for centuries. These methods demand specialist equipment and expertise that often render custom high-grade glass optics inaccessible. We aimed to develop a low-cost, accessible, and reproducible method to manufacture high-quality three-dimensional (3D) printed lenses using consumer-grade technology. Various planoconvex lenses were produced using a consumer-grade 3D printer and low-cost spin coating setup, and printed lenses were compared to commercial glass counterparts. A range of mechanical and optical methods are introduced to determine the surface quality and curvature of 3D printed lenses. Amongst others, high-resolution interference reflection microscopy methods were used to reconstruct the convex surface of printed lenses and quantify their radius of curvature. The optical throughput and performance of 3D printed lenses were assessed using optical transmissivity measurements and classical beam characterisation methods. We determined that 3D printed lenses had comparable curvature and performance to commercial glass lenses. Finally, we demonstrated the application of 3D printed lenses for brightfield transmission microscopy, resolving sub-cellular structures over a 2.3 mm field-of-view. The high reproducibility and comparable performance of 3D printed lenses present great opportunities for additive manufacturing of bespoke optics for low-cost rapid prototyping and improved accessibility to high-quality optics in low-resource settings.

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Section: Discussionmentioning

confidence: 99%

Printing, Characterising, and Assessing Transparent 3D Printed Lenses for Optical Imaging

Rooney,

Christopher,

Watson

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

End-to-end Optimization of Fluidic Lenses

Na,

Jimenez Romero,

Yang

et al. 2024

SIGGRAPH Asia 2024 Conference Papers

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Low-cost 3D printed lenses for brightfield and fluorescence microscopy

Christopher,

Rooney,

Donnachie

et al. 2024

Biomed. Opt. Express

Self Cite

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We present the fabrication and implementation of low-cost optical quality 3D printed lenses, and their application as microscope objectives with different prescriptions. The imaging performance of the 3D printed lenses was benchmarked against commercially available optics including a 20 mm focal length 12.7 mm diameter NBK-7 plano-convex lens used as a low magnification objective, and a separate high magnification objective featuring three 6 mm diameter NBK-7 lenses with different positive and negative focal lengths. We describe the design and manufacturing processes to produce high-quality 3D printed lenses. We tested their surface quality using a stylus profilometer, showing that they conform to that of commercial glass counterpart lenses. The 3D printed lenses were used as microscope objectives in both brightfield and epi-fluorescence imaging of specimens including onion, cyanobacteria, and variegated Hosta leaves, demonstrating a sub-cellular resolution performance obtained with low-cost 3D printed optical elements within brightfield and fluorescence microscopy.

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Low-cost 3D printed lenses for brightfield and fluorescence microscopy

Cited by 3 publications

References 30 publications

Printing, Characterising, and Assessing Transparent 3D Printed Lenses for Optical Imaging

Printing, Characterising, and Assessing Transparent 3D Printed Lenses for Optical Imaging

End-to-end Optimization of Fluidic Lenses

Low-cost 3D printed lenses for brightfield and fluorescence microscopy

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