Podrobno

Dissipative particle dynamics models of encapsulated microbubbles and nanoscale gas vesicles for biomedical ultrasound simulations
ID Ntarakas, Nikolaos (Avtor), ID Lah, Maša (Avtor), ID Svenšek, Daniel (Avtor), ID Potisk, Tilen (Avtor), ID Praprotnik, Matej (Avtor)

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Izvleček
Ultrasound-guided drug and gene delivery (USDG) enables controlled and spatially precise delivery of drugs and macromolecules, encapsulated in microbubbles (EMBs) and nanoscale gas vesicles (GVs), to target areas such as cancer tumors. It is a noninvasive, high precision, low toxicity process with drastically reduced drug dosage. Rheological and acoustic properties of GVs and EMBs critically affect the outcome of USDG and imaging. Detailed understanding and modeling of their physical properties is thus essential for ultrasound-mediated therapeutic applications. State-of-the-art continuum models of shelled bodies cannot incorporate critical details such as varying thickness of the encapsulating shell or specific interactions between its constituents and interior or exterior solvents. Such modeling approaches also do not allow for detailed modeling of chemical surface functionalizations, which are crucial for tuning the GV−blood interactions. We develop a general particle-based modeling framework for encapsulated bodies that accurately captures elastic and rheological properties of GVs and EMBs at the mesoscopic and nanoscale levels. We use dissipative particle dynamics to model the solvent, the gaseous phase in the capsid, and the triangulated surfaces of immersed objects. Their elastic behavior is studied and validated through stretching and buckling simulations, eigenmode analysis, shear flow simulations, and comparison of predicted GV buckling pressure with published experimental data. The presented modeling approach paves the way for large-scale simulations of nanoscale and microscale encapsulated bodies of different shapes and local anisotropy, capturing their dynamics, interactions, and collective behavior.

Jezik:Angleški jezik
Ključne besede:molecular simulations, molecular dynamics, liquid crystals, electrocaloric effect, ultrasound, gas vesicles, proteinaceous nanostructures, microbubbles, particle simulations, mesoscopic modeling, deformation, encapsulation, energy, fluid dynamics, membranes
Vrsta gradiva:Članek v reviji
Tipologija:1.01 - Izvirni znanstveni članek
Organizacija:FMF - Fakulteta za matematiko in fiziko
Status publikacije:Objavljeno
Različica publikacije:Objavljena publikacija
Leto izida:2025
Št. strani:Str. 16053−16070
Številčenje:Vol. 8, iss. 32
PID:20.500.12556/RUL-171386 Povezava se odpre v novem oknu
UDK:536.91
ISSN pri članku:2574-0970
DOI:10.1021/acsanm.5c02783 Povezava se odpre v novem oknu
COBISS.SI-ID:246402563 Povezava se odpre v novem oknu
Datum objave v RUL:25.08.2025
Število ogledov:448
Število prenosov:357
Metapodatki:XML DC-XML DC-RDF
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Gradivo je del revije

Naslov:ACS applied nano materials
Skrajšan naslov:ACS appl. nano mater.
Založnik:American Chemical Society
ISSN:2574-0970
COBISS.SI-ID:32649255 Povezava se odpre v novem oknu

Licence

Licenca:CC BY 4.0, Creative Commons Priznanje avtorstva 4.0 Mednarodna
Povezava:http://creativecommons.org/licenses/by/4.0/deed.sl
Opis:To je standardna licenca Creative Commons, ki daje uporabnikom največ možnosti za nadaljnjo uporabo dela, pri čemer morajo navesti avtorja.

Sekundarni jezik

Jezik:Slovenski jezik
Ključne besede:molekulske simulacije, molekulska dinamika, tekoči kristali, elektrokalorični pojav

Projekti

Financer:EC - European Commission
Program financ.:H2020
Številka projekta:885155
Naslov:Multiscale modeling and simulation approaches for biomedical ultrasonic applications
Akronim:MULTraSonicA

Financer:ARIS - Javna agencija za znanstvenoraziskovalno in inovacijsko dejavnost Republike Slovenije
Številka projekta:P1-0002
Naslov:Večskalno modeliranje in simulacija mehke in biološke snovi v in izven ravnovesja

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