Single-shot impulsive stimulated Brillouin microscopy by tailored ultrashort pulses

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The paper investigates impulsive stimulated Brillouin scattering (ISBS)-based Brillouin microscopy and how different excitation parameters affect spatial, temporal, and spectral resolution. Using tailored ultrashort single-shot excitation and a noise-suppressing window function, the authors report a measurement rate of 20 µs/pixel in hydrogel, aiming at faster 3D elastography with balanced resolution and energy to manage phototoxicity constraints. The main limitation is that improving spatial resolution requires higher pump energy density, so excitation parameters must be optimized to remain below a phototoxic threshold. This paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

Brillouin microscopy has become an important tool for investigating the mechanical properties of tissue. The recently developed Impulsive stimulated Brillouin Scattering (ISBS) promises a label-free, non-invasive measurements of viscoelastic properties of transparent samples and offers the potential for a high temporal resolution. However, the spatial resolution of ISBS is currently limited, which hinders its transfer to real-world applications. Increasing the spatial resolution of ISBS leads to an increase in the energy density of the pump beams, which requires a balancing of the excitation parameters to stay below the phototoxic threshold. This paper focuses on the influences of different excitation parameters on the spatial, temporal and spectral resolution and their optimal values. Combined with the adoption of a noise suppressing window function, a measurement rate of 20µs/pixel in hydrogel is achieved, which is promising for fast 3D imaging. The presented advanced impulsive stimulated Brillouin microscopy can be applied for fast tissue elastography to-ward disease studies.
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Abstract Brillouin microscopy has become an important tool for investigating the mechanical properties of tissue. The recently developed Impulsive stimulated Brillouin Scattering (ISBS) promises a label-free, non-invasive measurements of viscoelastic properties of transparent samples and offers the potential for a high temporal resolution. However, the spatial resolution of ISBS is currently limited, which hinders its transfer to real-world applications. Increasing the spatial resolution of ISBS leads to an increase in the energy density of the pump beams, which requires a balancing of the excitation parameters to stay below the phototoxic threshold. This paper focuses on the influences of different excitation parameters on the spatial, temporal and spectral resolution and their optimal values. Combined with the adoption of a noise suppressing window function, a measurement rate of 20µs/pixel in hydrogel is achieved, which is promising for fast 3D imaging. The presented advanced impulsive stimulated Brillouin microscopy can be applied for fast tissue elastography to-ward disease studies. Competing Interest Statement The authors have declared no competing interest.

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last seen: 2026-05-20T01:45:00.602351+00:00