Hoppa till huvudinnehållet

Publikationer

Publikationer av Dmitry Grishenkov

Refereegranskade

Artiklar

[1]

X. Song, G. Shen och D. Grishenkov, "A comparative study on detection of polymer-shelled microbubbles by different excitation pulses," Journal of the Acoustical Society of America, vol. 154, no. 1, s. 482-493, 2023.

[2]

F. R. Talabazar et al., "Cavitation inception and evolution in cavitation on a chip devices at low upstream pressures," Physics of fluids, vol. 35, no. 1, 2023.

[3]

K. Loskutova et al., "Cellulose Nanofiber-Coated Perfluoropentane Droplets: Fabrication and Biocompatibility Study," International Journal of Nanomedicine, vol. 18, s. 1835-1847, 2023.

[4]

F. R. Talabazar et al., "Chemical effects in "hydrodynamic cavitation on a chip" : The role of cavitating flow patterns," Chemical Engineering Journal, vol. 445, 2022.

[5]

S. Seyedmirzaei Sarraf et al., "Fundamentals, biomedical applications and future potential of micro-scale cavitation-a review," Lab on a Chip, vol. 22, no. 12, s. 2237-2258, 2022.

[6]

T. Nordenfur et al., "Safety of arterial shear wave elastography-ex-vivo assessment of induced strain and strain rates," Biomedical Engineering & Physics Express, vol. 8, no. 5, 2022.

[7]

K. Loskutova et al., "A Study on the Acoustic Response of Pickering Perfluoropentane Droplets in Different Media," ACS Omega, 2021.

[8]

X. Song et al., "Deriving acoustic properties for perfluoropentane droplets with viscoelastic cellulose nanofiber shell via numerical simulations," Journal of the Acoustical Society of America, s. 1750-1761, 2021.

[9]

F. Rokhsar Talabazar et al., "Design and fabrication of a vigorous "cavitation-on-a-chip" device with a multiple microchannel configuration," Microsystems & Nanoengineering, vol. 7, no. 1, 2021.

[10]

K. Loskutova et al., "Measuring the Compressibility of Cellulose Nanofiber-Stabilized Microdroplets Using Acoustophoresis," Micromachines, vol. 12, no. 12, s. 1465, 2021.

[11]

H. Chen et al., "On the Development of a Novel Contrast Pulse Sequence for Polymer-Shelled Microbubbles," IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, vol. 68, no. 5, s. 1569-1579, 2021.

[12]

T. Abbasiasl et al., "Effect of intensified cavitation using poly (vinyl alcohol) microbubbles on spray atomization characteristics in microscale," AIP Advances, vol. 10, no. 2, 2020.

[13]

H. Chen, Y. Zhao och D. Grishenkov, "Polymer microbubbles loaded with gold nanoparticles as hybrid contrast agent for computed tomography and ultrasound," Biomedical Research and Clinical Practice, vol. 5, s. 1-9, 2020.

[14]

M. Talebian Gevari et al., "Energy harvesting with micro scale hydrodynamic cavitation-thermoelectric generation coupling," AIP Advances, vol. 9, 2019.

[15]

M. Ghorbani et al., "Facile Hydrodynamic Cavitation ON CHIP via Cellulose Nanofibers Stabilized Perfluorodroplets inside Layer-by-Layer Assembled SLIPS Surfaces," Chemical Engineering Journal, 2019.

[16]

K. Loskutova, D. Grishenkov och M. Ghorbani, "Review on Acoustic Droplet Vaporization in Ultrasound Diagnostics and Therapeutics," BioMed Research International, 2019.

[17]

M. Ghorbani et al., "Unravelling the Acoustic and Thermal Responses of Perfluorocarbon Liquid Droplets Stabilized with Cellulose Nanofibers," Langmuir, vol. 35, no. 40, s. 13090-13099, 2019.

[18]

M. Ghorbani et al., "Intensifying cavitating flows in microfluidic devices with poly(vinyl alcohol) (PVA) microbubbles," Physics of fluids, vol. 30, no. 10, 2018.

[19]

M. A. Faridi et al., "MicroBubble Activated Acoustic Cell Sorting : BAACS," Biomedical microdevices (Print), vol. 19, no. 2, 2017.

[20]

Y. Toumia och D. Grishenkov, "Graphene Meets Microbubbles : A Superior Contrast Agent for Photoacoustic Imaging," ACS Applied Materials and Interfaces, vol. 8, no. 25, s. 16465-16475, 2016.

[21]

S. V. V. N. Kothapalli et al., "Investigation of polymer-shelled microbubble motions in acoustophoresis," Ultrasonics, vol. 70, s. 275-283, 2016.

[22]

G. Tamadapu, D. Grishenkov och A. Eriksson, "Modeling and parametric investigation of thick encapsulated microbubble's nonspherical oscillations," Journal of the Acoustical Society of America, vol. 140, no. 5, s. 3884-3895, 2016.

[23]

D. Grishenkov, G. Adrian och B. Janerot Sjöberg, "In search of the optimal ultrasound heart perfusion imaging platform," Journal of ultrasound in medicine, vol. 34, no. 9, s. 1599-1605, 2015.

[24]

D. Grishenkov et al., "Ultrasound contrast agent loaded with nitric oxide as a theranostic microdevice : Theranostic contrast agent loaded with nitric oxide," Drug Design, Development and Therapy, vol. 9, s. 2409-2419, 2015.

[25]

V. S. Kothapalli et al., "Assessment of the Viscoelastic and Oscillation Properties of a Nano-engineered Multimodality Contrast Agent," Ultrasound in Medicine and Biology, vol. 40, no. 10, s. 2476-2487, 2014.

[26]

M. Poehlmann et al., "On the interplay of shell structure with low- and high-frequency mechanics of multifunctional magnetic microbubbles," Soft Matter, vol. 10, no. 1, s. 214-226, 2014.

[27]

V. V. S. N. Kothapalli et al., "Unique pumping-out fracturing mechanism of a polymer-shelled contrast agent : An acoustic characterization and optical visualization," IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, vol. 62, no. 3, s. 451-462, 2014.

[28]

S. Capece et al., "A general strategy for obtaining biodegradable polymer shelled microbubbles as theranostic devices," Chemical Communications, vol. 49, no. 51, s. 5763-5765, 2013.

[29]

C. Sciallero et al., "Acoustic characterization and contrast imaging of microbubbles encapsulated by polymeric shells coated or filled with magnetic nanoparticles," Journal of the Acoustical Society of America, vol. 134, no. 5, s. 3918-3930, 2013.

[30]

T. B. Brismar et al., "Magnetite Nanoparticles Can Be Coupled to Microbubbles to Support Multimodal Imaging," Biomacromolecules, vol. 13, no. 5, s. 1390-1399, 2012.

[31]

D. Grishenkov et al., "In vitro contrast-enhanced ultrasound measurements of capillary microcirculation : Comparison between polymer- and phospholipid-shelled microbubbles," Ultrasonics, vol. 51, no. 1, s. 40-48, 2011.

[32]

D. Grishenkov et al., "Characterization of acoustic properties of PVA-shelled ultrasound contrast agents : ultrasound-induced fracture (Part II)," Ultrasound in Medicine and Biology, vol. 35, no. 7, s. 1139-1147, 2009.

[33]

D. Grishenkov et al., "Characterization of acoustic properties of PVA-shelled ultrasound contrast agents : linear properties (Part I)," Ultrasound in Medicine and Biology, vol. 35, no. 7, s. 1127-1138, 2009.

[34]

C. Pecorari och D. Grishenkov, "Characterization of ultrasound-induced fracture of polymer-shelled ultrasonic contrast agents by correlation analysis," Journal of the Acoustical Society of America, vol. 122, no. 4, s. 2425-2430, 2007.

Konferensbidrag

[35]

K. Loskutova et al., "Biocompatibility of Cellulose Nanofiber-Coated Perfluoropentane Droplets," i The 28th European Symposium on Ultrasound Contrast Imaging, 2023.

[36]

K. Loskutova et al., "Assessment of the Mechanical Propertiesof Cellulose Nanofiber-Stabilized Droplets Using Acoustophoresis," i 26th European Symposium on Ultrasound Contrast Imaging d online from 14-15 January 2021., 2021.

[37]

H. Chen och D. Grishenkov, "A mathematical model of polyvinyl alcohol microbubbles," i The Westlake International Forum on Ultrasound in Medicine and Biology 2020, 2020.

[38]

H. Chen, W. Löffler och D. Grishenkov, "Sequence design for ultrasound imaging of polyvinyl alcohol microbubbles," i The 25th European symposium on Ultrasound Contrast Imaging, 2020.

[39]

M. Ghorbani, A. J. Svagan och D. Grishenkov, "Targeted Hydrodynamic Cavitating Flows via Ultrasound Waves via Pickering Stabilized Perfluorodroplets," i The 25th European symposium on Ultrasound Contrast Imaging, 2020.

[40]

M. Ghorbani, A. J. Svagan och D. Grishenkov, "Acoustic Response of a Novel Class of Pickering Stabilized Perfluorodroplets," i 24th European symposium on Ultrasound Contrast Imaging, 2019.

[41]

H. Chen, D. Evangelou och D. Grishenkov, "Sequence design for ultrasound imaging of polyvinyl alcohol microbubbles," i 24th European symposium on Ultrasound Contrast Imaging, 2019.

[42]

H. Chen et al., "Polymer Microbubbles as Dual Modal Contrast Agent for Ultrasound and Computed Tomography," i The 23rd European symposium on Ultrasound Contrast Imaging, 2018.

[43]

M. A. Faridi et al., "Microbubble assisted cell sorting by acoustophoresis," i 20th International Conference on Miniaturized Systems for Chemistry and Life Sciences, MicroTAS 2016, 2016, s. 1677-1678.

[44]

S. Capese et al., "A general strategy for the obtainment of biodegradable polymer shelled microbubbles as theranostic device," i European Molecular Imaging Meeting EMIM 2013; Torino, Italy, 26-28 May, 2013, 2013.

[45]

D. Grishenkov, "Contrast agent for early diagnostics and monitoring of progression of liver cancer (hepatocellular carcinoma)," i Nanoparticles for Early Diagnostics of Inflammatory Diseases: new approaches in the field of soft and hard nanoparticle, 20-21 November 2013, Lisboa, Portugal., 2013.

[46]

S. V. V. N. Kothapalli et al., "Dynamic and Structural Behavior of Magnetic PVA-Shelled Microbubbles : Acoustic Characterization," i IEEE International Ultrasonics Symposium, 2013, s. 1509-1512.

[47]

V. S. Kothapalli et al., "Dynamic and Structural behavior of Magnetized PVA-shelled Microbubbles : Acoustic Characterization," i IEEE International Ultrasonics Symposium, 21–25 July 2013, Prague, Czech Republic., 2013.

[48]

B. Janerot Sjöberg, A. Gonon och D. Grishenkov, "In Search of the Optimal Ultrasound Heart Perfusion Imaging Platform," i Autumn meeting of Svensk förening för Klinisk Fysiologi, 26-27 Sept 2013, Gothenburg, Sweden, 2013.

[49]

M. Poehlman et al., "Magnetic microbubbles for multimodality imaging : the importance of the shell structure for low and high frequency mechanics," i European symposium and exhibition on biomaterials and related areas, Euro BioMAT2013 23-24 Apr 2013 Weimar, Germany, 2013.

[50]

D. Grishenkov et al., "Ultrasound contrast agent loaded with nitric oxide as a theranostic microdevise for myocardial ischemia," i Medicinteknikdagarna 2013; Stockholm, Sweden, 1-2 October 2013, 2013.

[51]

D. Grishenkov et al., "Ultrasound contrast agent loaded with nitric oxide as a theranostic microdevise for myocardial ischemia," i European Heart Journal Cardiovascular Imaging : Abstracts of EUROECHO 2013 The Seventeenth Annual Meeting of the European Association of Echocardiography, 2013.

[52]

D. Grishenkov och G. Paradossi, "Assessment of ultrasound-induced fracture of polymer-shelled ultrasound contrast agents using superharmonic technique," i 19th International Congress on Sound and Vibration (ICSV19) Vilnius, Lithuania, 8-12 July 2012., 2012.

[53]

V. V. S. N. Kothapalli och D. Grishenkov, "Optimization of driving pulse envelopes in detection of harmonic response from lipid-shelled ultrasound contrast agent," i 19th International Congress on Sound and Vibration 2012, ICSV 2012 : Volume 3, 2012, 2012, s. 1882-1889.

[54]

V. V. S. N. Kothapalli et al., "Coded Excitation Technique in Detection of Polymeric-Shelled Ultrasound contrast Agents: in Vitro Study," i 8th International Conference on Nanosciences & Nanotechnologies (NN11) 12-15 July 2011, Thessaloniki, Greece. : Workshop: NANOMEDICINE, 2011.

[55]

D. Grishenkov et al., "On comparison between polymer- and phospholipid-shelled microbubbles for contrast-enhanced ultrasound measurements of capillary microcirculation.," i Proceedings of the 34^th Scandinavian Symposium on Physical Acoustics, 2011.

[56]

M. Zheng et al., "Polymer-Shelled Ultrasound Contrast Agents with controlled size and polydispersity.," i Nanomedicine: Nanotechnology, Biology & Medicine, 2011.

[57]

D. Grishenkov, "Three modality contrast imaging using multi-functionalized microballoons," , 2011.

[58]

D. Grishenkov et al., "Acoustic properties of polymer-shelled ultrasound contrast agents. Bulk volume vs. microcapillary," i 16th International Congress on Sound and Vibration 2009, ICSV 2009, 2009, s. 2515-2522.

Icke refereegranskade

Konferensbidrag

[59]

V. V. S. N. Kothapalli et al., "On-chip actuation of polymer shelled microbubbles," i Medicinteknikdagarna 2013, 1-2 October 2013, Stockholm, Sweden., 2013.

[60]

C. Pecorari och D. Grishenkov, "Characterization of ultrasound-induced fracture of polymer-shelled ultrasonic contrast agents by correlation analysis," i 31st Scandinavian Symposium on Physical Acoustics, 27-30 January 2008, Geilo, Norway, 2008.

[61]

D. Grishenkov et al., "On the acoustic properties of polymer-shell ultrasonic contrast agents.," i 18th International Symposium on Nonlinear Acoustics, 7-10 July 2008, Stockholm , Sweden, 2008.

Kapitel i böcker

[62]

D. Grishenkov et al., "Characterization of Acoustic Properties of PVA-Shelled Ultrasound Contrast Agents," i Ultrasound Contrast Agents : Targeting And Processing Methods For Theranostics, G. Paradosi, P. Pellegretti, A. Trucco red., Italia : Springer-Verlag, 2010, s. 99-108.

Avhandlingar

[63]

D. Grishenkov, "Polymer-shelled Ultrasound Contrast Agents : Characterization and Application," Doktorsavhandling Stockholm : KTH, Trita-AVE, 2010.

Övriga

[64]

V. S. Kothapalli et al., "Assessment of the viscoelastic and oscillation properties of a nanoengineered-shelled multimodality contrast agent," (Manuskript).

[65]

S. V.V.N. Kothapalli et al., "Investigation of Polymer-Shelled Microbubble Motions in Acoustophoresis," (Manuskript).

[66]

H. Chen, W. Löffler och D. Grishenkov, "Model-guided customization of a contrast pulse sequence for polyvinyl alcohol microbubbles," (Manuskript).

Senaste synkning med DiVA:

2024-04-16 00:13:51