Scalable and Isotropic Expansion of Tissues with Simply Tunable Expansion Ratio

Park, Han-Eol; Choi, Dong Hyun; Park, Jisu; Sim, Changgon; Park, Sohyun; Kang, Seok Jin; Yim, Hyunsoo; Lee, Myungsun; Kim, Jaeyoun; Pác, J.; Rhee, Kunsoo; Lee, Jun-Ho; Lee, Yong Kyu; Lu, Yan; Kim, Sung-Yon

doi:10.1002/advs.201901673

Cited by 52 publications

(90 citation statements)

References 55 publications

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“…This simple idea was rapidly adapted by various laboratories, leading to the development of new protocols that allow expansion factors of up to 10× (Truckenbrodt et al, 2019) or even 20× by iterative expansion (Chang et al, 2017). Other protocols focus on preservation and isotropic expansion of ultrastructure (U-ExM) (Gambarotto et al, 2019) or on precise tuning of the expansion factor between 2 and 8 (ZOOM) (Park et al, 2019). Recently, ExM has been applied also to bacterial pathogens (Kunz et al, 2019) and to plants (Kao and Nodine, 2019), paving the way for new methodological approaches in these fields.…”

Section: Introductionmentioning

confidence: 99%

Expansion Microscopy for Cell Biology Analysis in Fungi

Götz¹,

Panzer²,

Trinks³

et al. 2020

Front. Microbiol.

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Super-resolution microscopy has evolved as a powerful method for subdiffractionresolution fluorescence imaging of cells and cellular organelles, but requires sophisticated and expensive installations. Expansion microscopy (ExM), which is based on the physical expansion of the cellular structure of interest, provides a cheap alternative to bypass the diffraction limit and enable super-resolution imaging on a conventional fluorescence microscope. While ExM has shown impressive results for the magnified visualization of proteins and RNAs in cells and tissues, it has not yet been applied in fungi, mainly due to their complex cell wall. Here we developed a method that enables reliable isotropic expansion of ascomycetes and basidiomycetes upon treatment with cell wall degrading enzymes. Confocal laser scanning microscopy (CLSM) and structured illumination microscopy (SIM) images of 4.5-fold expanded sporidia of Ustilago maydis expressing fluorescent fungal rhodopsins and hyphae of Fusarium oxysporum or Aspergillus fumigatus expressing either histone H1-mCherry together with Lifeact-sGFP or mRFP targeted to mitochondria, revealed details of subcellular structures with an estimated spatial resolution of around 30 nm. ExM is thus well suited for cell biology studies in fungi on conventional fluorescence microscopes.

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Section: Introductionmentioning

confidence: 99%

Expansion Microscopy for Cell Biology Analysis in Fungi

Götz¹,

Panzer²,

Trinks³

et al. 2020

Front. Microbiol.

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“…Fluid‐assisted injection molding technique (FAIM), such as the gas‐assisted injection molding (GAIM) process and the water‐assisted injection molding (WAIM) process, enables the efficient production of complex, highly integrated parts in one process step with the help of pressurized fluid . In the case of WAIM, the polymer melt is displaced by water.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, larger part diameters are possible with WAIM . In FAIM, however, the residual wall thickness (RWT) is determined largely by the rheological properties of the polymer and fluid used . FAIM is known to have some problems in the uniformity of the inner diameter, the uniformity of the RWT, the smoothness of the inner surface, and the production of pipes with diameters greater than 40 mm .…”

Section: Introductionmentioning

confidence: 99%

“…In FAIM, however, the residual wall thickness (RWT) is determined largely by the rheological properties of the polymer and fluid used . FAIM is known to have some problems in the uniformity of the inner diameter, the uniformity of the RWT, the smoothness of the inner surface, and the production of pipes with diameters greater than 40 mm . For FAIM parts with large diameters, the achievable wall thicknesses are relatively thick, which leads to an unfavorably heavy part weight and relatively long cycle times to cool down the final product .…”

Section: Introductionmentioning

confidence: 99%

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Residual wall thickness of water‐powered projectile‐assisted injection molding pipes

Kuang

Junyu

Feng

et al. 2018

Polymer Engineering & Sci

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Water‐powered projectile‐assisted injection molding (W‐PAIM) is an innovative molding process for the production of hollow shaped polymer parts. The W‐PAIM utilizes high pressure water as a power to drive a solid projectile to displace the molten polymer core to form the hollow space. The residual wall thickness (RWT) and its distribution are the important quality criteria. The experimental and numerical investigations were conducted. Experimental specimens showed that the RWT of a W‐PAIM pipe was much thinner than that of a water‐assisted injection molding pipe. The cross‐section size of the projectile defined the basic penetration section size. The software FLUENT was used to obtain the instantaneous distributions of the flow field, which revealed the forming mechanism of the RWT. The experiments indicated that the processing parameters, such as melt temperature, melt injection pressure, mold temperature, and water injection delay time had obvious effects on the RWT, while the water pressure had little effect on it. The RWT of curved pipes was thin at the inner concave side while thick at the outer convex side. The RWTs at the bend portion are influenced by the deflection angle and bending radius, which is due to the pressure difference between the two sides. POLYM. ENG. SCI., 59:295–303, 2019. © 2018 Society of Plastics Engineers

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“…However, one consequence of tissue expansion is a decrease in the fluorescence intensity of labeled proteins primarily due to the digestion process and the dilution of fluorescence signal per unit volume. Various ExM protocols have described different methods for improving fluorescence retention, primarily by modifying fixation, crosslinking, and/or digestion conditions to preserve protein epitopes [2][3][4][5][6][7][8] . One common ExM protocol uses a strong protease-based digestion (Proteinase K 2 ), but other gentler proteases have also been used (LysC 2,3 ), as well as a combination of heat and detergents in place of proteases (e.g.…”

Section: Introductionmentioning

confidence: 99%

Visualizing subcellular structures in neuronal tissue with expansion microscopy

Campbell

Pannoni

Savory

et al. 2020

Preprint

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Protein expansion microscopy (proExM) is a powerful technique that crosslinks proteins to a swellable hydrogel to physically expand and optically clear biological samples. The resulting increased resolution (~70 nm) and physical separation of labeled proteins make it an attractive tool for studying the localization of subcellular organelles in densely packed tissues, such as the brain. However, the digestion and expansion process greatly reduces fluorescence signals making it necessary to optimize ExM conditions per sample for specific end goals. Here we describe a proExM workflow optimized for resolving subcellular organelles (mitochondria and the Golgi apparatus) and reporter-labeled spines in fixed mouse brain tissue. By directly comparing proExM staining and digestion protocols, we found that immunostaining before proExM and using a Proteinase K based digestion for 8 hours consistently resulted in the best fluorescence signal to resolve subcellular organelles while maintaining sufficient reporter labeling to visualize spines and trace individual neurons. With these methods, we more accurately quantified mitochondria size and number and better visualized Golgi ultrastructure in reconstructed CA2 neurons of the hippocampus.

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Scalable and Isotropic Expansion of Tissues with Simply Tunable Expansion Ratio

Cited by 52 publications

References 55 publications

Expansion Microscopy for Cell Biology Analysis in Fungi

Expansion Microscopy for Cell Biology Analysis in Fungi

Residual wall thickness of water‐powered projectile‐assisted injection molding pipes

Visualizing subcellular structures in neuronal tissue with expansion microscopy

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