Cavitation in soft matter

Barney, Christopher W.; Dougan, Carey E.; McLeod, Kelly R.; Kazemi-Moridani, Amir; Zheng, Yue; Ye, Ziyu; Tiwari, Sacchita; Sacligil, Ipek; Riggleman, Robert A.; Cai, Shengqiang; Lee, Jae‐Hwang; Peyton, Shelly R.; Tew, Gregory N.; Crosby, Alfred J.

doi:10.1073/pnas.1920168117

Cited by 104 publications

(68 citation statements)

References 131 publications

(210 reference statements)

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“…30 who used the forced syringe injection of liquid and optical dye attenuation to measure the penny-shaped crack thickness. This new method also complements previous cavitation rheology methods, 33 based on the growth of spherical elastic (nonfracturing) bubbles to estimate material properties such as E. 34 Decompression sickness. Our key result also suggests a new potential mechanism for decompression sickness: the growth of inert gas pockets with a potentially catastrophic linear scaling, and a thin penny-shaped geometry that irreversibly fractures body tissues.…”

Section: Resultsmentioning

confidence: 85%

Growth of gas-filled penny-shaped cracks in decompressed hydrogels

2021

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Section: Resultsmentioning

confidence: 85%

Growth of gas-filled penny-shaped cracks in decompressed hydrogels

2021

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“…LCR potentially offers new opportunities to investigate cellular mechanotransduction 47 , 67 in a 3D context with simultaneous characterization of the ECM mechanical properties. Moreover, through its ability to subject soft materials to large deformations at high strain rates, LCR may provide a unique tool to study and probe fundamental rheological properties of soft materials on the mesoscopic scale under such extreme conditions 58 . Moreover, LCR is particularly useful to study and probe the rheological response of biological systems to impact/blast injury with potential utility in laser microsurgery 59 , 60 , molecular delivery 61 , cell lysis 62 , tissue ablation 63 , and traumatic brain or spinal cord injury 64 – 66 .…”

Section: Discussionmentioning

confidence: 99%

Laser cavitation rheology for measurement of elastic moduli and failure strain within hydrogels

Luo

Ching

Wilson

et al. 2020

Sci Rep

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We introduce laser cavitation rheology (LCR) as a minimally-invasive optical method to characterize mechanical properties within the interior of biological and synthetic aqueous soft materials at high strain-rates. We utilized time-resolved photography to measure cavitation bubble dynamics generated by the delivery of focused 500 ps duration laser radiation at λ = 532 nm within fibrin hydrogels at pulse energies of E p = 12, 18 µJ and within polyethylene glycol (600) diacrylate (PEG (600) DA) hydrogels at E p = 2, 5, 12 µJ. Elastic moduli and failure strains of fibrin and PEG (600) DA hydrogels were calculated from these measurements by determining parameter values which provide the best fit of the measured data to a theoretical model of cavitation bubble dynamics in a Neo-Hookean viscoelastic medium subject to material failure. We demonstrate the use of this method to retrieve the local, interior elastic modulus of these hydrogels and both the radial and circumferential failure strains.

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“…Cavitation rheology quantifies the elastic properties by growing a bubble in a gel or fluid and monitoring the pressure dynamics (Hashemnejad and Kundu, 2017). The resolution of cavitation rheology can go as low as 1 µm and requires only small sample volumes (Barney et al, 2020). One drawback of this method is that it is destructive to the sample.…”

Section: Emerging Techniquesmentioning

confidence: 99%

“…One drawback of this method is that it is destructive to the sample. Questions also remain around relating gel fracture to cavitation and the influence of local network structures on cavitation bubble growth (Barney et al, 2020).…”

Section: Emerging Techniquesmentioning

confidence: 99%