Correction: Corrigendum: Biomechanics of subcellular structures by non-invasive Brillouin microscopy

Abstract: Scientific Reports 6: Article number: 37217; published online: 15 November 2016; updated: 09 May 2017 The authors wish to acknowledge other contributors and other sources of funding. The Author Contributions statement should read: G.A. and S.B. contributed to the design of the experiments. G.A. contributed to the development of the microscope.

“…BM can achieve submicron-scale spatial resolution [25,167], which is sufficient for visualizing subcellular structures. A recent study used BM to reveal a liquid-solid phase transition in intracellular stress granules by measuring the elastic longitudinal modulus [168]. Although no direct measurement was made on the viscoelastic properties, it demonstrated the feasibility of probing intracellular compartments with BM.…”

Existing and Potential Applications of Elastography for Measuring the Viscoelasticity of Biological Tissues In Vivo

“…BM can achieve submicron-scale spatial resolution [25,167], which is sufficient for visualizing subcellular structures. A recent study used BM to reveal a liquid-solid phase transition in intracellular stress granules by measuring the elastic longitudinal modulus [168]. Although no direct measurement was made on the viscoelastic properties, it demonstrated the feasibility of probing intracellular compartments with BM.…”

Existing and Potential Applications of Elastography for Measuring the Viscoelasticity of Biological Tissues In Vivo

Investigating the Feasibility of Laser-Doppler Vibrometry for Vibrational Analysis of Living Mammalian Cells