01995nam a2200217Ia 4500003001000000005001700010040000900027090001200036245009700048490006100145520116700206650002701373700001901400700001201419700001801431856015601449942001401605008004101619952010001660999001701760MX-MdCICY20250625162412.0  cCICY  aB-1842710aMultiscale and multidisciplinary approach to understanding nanoparticle transport in plants.0 vCurrent Opinion in Chemical Engineering, p.100659., 20203 aRecent advances in nanoparticle (NP)technology have revealed potential to improve efficiencies in agriculture and plant biotechnology - specifically through controlled nutrient delivery, pathogen mitigation, and genetic engineering. However, most NP-based biotechnology applications have focused on demonstrative experimental studies, with few rigorous mechanistic explanations of how NPs translocate within plant structures. This article highlights advances in understanding NP transport in plants, categorized into NP movement across three length scales each distinguished by a different transport barrier: (i)the macroscale where different plant organs present unique obstacles to continuum transport, (ii)the microscale where the cell wall and dynamic size exclusion controls transport, and (iii)the molecular scale where cell and organelle membranes provide a hydrophobic barrier. To fully understand transport in plants and realize the benefits of responsible NP-based agri-technologies, researchers must combine knowledge from several disciplines and apply a multiscale approach to bridge knowledge about NP transport in plants across these length scales.14aNANOPARTICLE TRANSPORT12aHubbard, J. D.12aLui, A.12aLandry, M. P.40uhttps://drive.google.com/file/d/1btSetQaLSZ3luWs4j_GxNpCblpWNtoaP/view?usp=drivesdkzPara ver el documento ingresa a Google con tu cuenta: @cicy.edu.mx  2LoccREF1250602s9999    xx |||||s2   |||| ||und|d  102Loc40708F1aCICYbCICYcREd2025-06-25l0oB-18427r2025-06-25 16:24:12w2025-06-25yREF1  c52579d52579