Your search keyword '"Naghsh‐Nilchi, Hamed"' showing total 5 results

1. Separation of cancer cells using vortical microfluidic flows.

Author

Haddadi, Hamed, Naghsh-Nilchi, Hamed, and Di Carlo, Dino

Subjects

Cancer, Classical Physics, Interdisciplinary Engineering, Nanotechnology, Nanoscience & Nanotechnology

Abstract

Label-free separation of viable cancer cells using vortical microfluidic flows has been introduced as a feasible cell collection method in oncological studies. Besides the clinical importance, the physics of particle interactions with the vortex that forms in a wall-confined geometry of a microchannel is a relatively new area of fluid dynamics. In our previous work [Haddadi and Di Carlo, J. Fluid. Mech. 811, 436-467 (2017)], we have introduced distinct aspects of inertial flow of dilute suspensions over cavities in a microchannel such as breakdown of the separatrix and formation of stable limit cycle orbits for finite size polystyrene particles. In this work, we extend our experiments to address the engineering-physics of cancer cell entrapment in microfluidic cavities. We begin by studying the effects of the channel width and device height on the morphology of the vortex, which has not been discussed in our previous work. The stable limit cycle orbits of finite size cancer cells are then presented. We demonstrate effects of the separatrix breakdown and the limit cycle formation on the operation of the cancer cell separation platform. By studying the flow of dilute cell suspensions over the cavities, we further develop the notion of the cavity capacity and the relative rate of cell accumulation as optimization criteria which connect the device geometry with the flow. Finally, we discuss the proper placement of multiple cavities inside a microchannel for improved cell entrapment.

Published

2018

2. Designing a Nitro-Induced Sutured Biomacromolecule to Engineer Electroconductive Adhesive Hydrogels

Author

Baidya, Avijit, primary, Ghovvati, Mahsa, additional, Lu, Cathy, additional, Naghsh-Nilchi, Hamed, additional, and Annabi, Nasim, additional

Published

2022

3. Scanning two-photon continuous flow lithography for synthesis of high-resolution 3D microparticles: erratum

Author

Shaw, Lucas A., primary, Chizari, Samira, additional, Shusteff, Maxim, additional, Naghsh-Nilchi, Hamed, additional, Di Carlo, Dino, additional, and Hopkins, Jonathan B., additional

Published

2018

4. Designing a Nitro-Induced Sutured Biomacromolecule to Engineer Electroconductive Adhesive Hydrogels

Author

Baidya, Avijit, Ghovvati, Mahsa, Lu, Cathy, Naghsh-Nilchi, Hamed, and Annabi, Nasim

Abstract

Nitro-functionality, with a large deficit of negative charge, embraces biological importance and has proven its therapeutic essence even in chemotherapy. Functionally, with its strong electron-withdrawing capability, nitro can manipulate the electron density of organic moieties and regulates cellular-biochemical reactions. However, the chemistry of nitro-functionality to introduce physiologically relevant macroscopic properties from the molecular skeleton is unknown. Therefore, herein, a neurotransmitter moiety, dopamine, was chemically modified with a nitro-group to explore its influence on synthesizing a multifunctional biomaterial for therapeutic applications. Chemically, while the nitro-group perturbed the aromatic electron density of nitrocatecholic domain, it facilitated the suturing of nitrocatechol moieties to regain its aromaticity through a radical transfer mechanism, forming a novel macromolecular structure. Incorporation of the sutured-nitrocatecholic strand (S-nCAT) in a gelatin-based hydrogel introduced an electroconductive microenvironment through the delocalization of π-electrons in S-nCAT, while maintaining its catechol-mediated adhesive property for tissue repairing/sealing. Meanwhile, the engineered hydrogel enriched with noncovalent interactions, demonstrated excellent mechano-physical properties to support tissue functions. Cytocompatibility of the bioadhesive was assessed with in vitroand in vivostudies, confirming its potential usage for biomedical applications. In conclusion, this novel chemical approach enabled designing a multifunctional biomaterial by manipulating the electronic properties of small bioactive molecules for various biomedical applications.

Published

2024

5. Engineered Nanotopographies Induce Transient Openings in the Nuclear Membrane.

Author

Sarikhani, Einollah, Patel, Vrund, Li, Zhi, Meganathan, Dhivya Pushpa, Rahmani, Keivan, Sadr, Leah, Hosseini, Ryan, Visda, Diether, Shukla, Shivani, Naghsh‐Nilchi, Hamed, Balaji, Adarsh, McMahon, Gillian, Chen, Shaoming, Schöneberg, Johannes, McHugh, Colleen A., Shi, Lingyan, and Jahed, Zeinab

Subjects

*NUCLEAR membranes, *DRUG delivery systems, *CELL membranes, *SURFACE topography, *VIRAL proteins

Abstract

Materials with engineered nano‐scale surface topographies, such as nanopillars, nanoneedles, and nanowires, mimic natural structures like viral spike proteins, enabling them to bypass biological barriers like the plasma membrane. These properties have led to applications in nanoelectronics for intracellular sensing and drug delivery platforms, some of which are already in clinical trials. Here, evidence is present that nanotopographic materials can induce transient openings in the nuclear membranes of various cell types without penetrating the cells, breaching the nucleo‐cytoplasmic barrier, and allowing uncontrolled molecular exchange across the nuclear membrane. These openings, induced by nanoscale curvature, are temporary and repaired through the Endosomal Sorting Complexes Required for Transport (ESCRT)‐mediated mechanisms. The findings suggest a potential for nano\topographic materials to temporarily breach the nuclear membrane with potential applications in direct nuclear sensing and delivery. [ABSTRACT FROM AUTHOR]

Published

2024