High‐Throughput Inertial Focusing of Micrometer‐ and Sub‐Micrometer‐Sized Particles Separation
Advanced Science, 2017 The ability to study individual bacteria or subcellular organelles using inertial microfluidics is still nascent. This is due, in no small part, to the significant challenges associated with concentrating and separating specific sizes of micrometer and ...
Lei Wang, David S. Dandy
doaj +1 more source
Organoid Brain‐Machine‐Interface Devices for Central Nervous System Repair
Advanced Science, EarlyView.We envision organoid brain‐machine‐interface (Organoid‐BMI) devices as new biohybrid bidirectional communication pathways to connect the human CNS and the external world for personalized CNS repair and regeneration. ABSTRACT Central nervous system (CNS) repair and regeneration suffer from tremendous clinical challenges due to current limitations in ...
Yantao Xing +10 more
wiley +1 more source
Decoding Undesirable Inflammatory Responses of Nucleic Acid‐Delivering Lipid Nanoparticles
Advanced Science, EarlyView.Lipid nanoparticles (LNPs) enable efficient nucleic acid delivery, but their immunogenicity is a double‐edged sword. This review explores LNP‐driven innate and adaptive immunity, covering lipid components, endosomal escape, and nucleic acid sensing.
Ruimin Hu +6 more
wiley +1 more source
Numerical investigation of the formation and stability of homogeneous pairs of soft particles in inertial microfluidics. [PDF]
J Fluid Mech, 2022 Owen B, Krüger T.
europepmc +1 more source
Developing Micro/Nanostructured Fluidic Mixing Technology for Biomedical Applications
Advanced Science, EarlyView.This review critically evaluates how micro/nanostructured mixing technologies are redefining biomedical research. By synergizing fundamental analysis, numerical modeling, structural design, and external field manipulation, these systems attain unprecedented control over mass transport.
Junkai Wang +3 more
wiley +1 more source
Isolation of Circulating Tumor Cells from Seminal Fluid of Patients with Prostate Cancer Using Inertial Microfluidics. [PDF]
Cancers (Basel), 2022 Rzhevskiy AS +13 more
europepmc +1 more source
A Piezo‐Mimetic Ionic Hydrogel Harnessing Joint Motion for Cartilage Repair
Advanced Science, EarlyView.A piezo‐mimetic ionic hydrogel converts mechanical deformation into bioactive ionic currents via stress‐induced asymmetric ion migration. Coupled with sustained Mg2+ release, this mechano‐electrochemical platform bridges mechanical loading and cellular signaling, enabling load‐adaptive stimulation and enhanced cartilage regeneration. ABSTRACT Articular
Chenyuan Gao +14 more
wiley +1 more source
Membrane-free water filtration using inertial microfluidics
, 2020 Membrane filtration is a key water treatment process to remove micron-sized particulates. However, it is prone to clogging that leads to significant pressure loss and decrease in filtration efficiency.
Chua, Nicholas Wei Xiong
core
<i>Giardia</i> purification from fecal samples using rigid spiral inertial microfluidics. [PDF]
Biomicrofluidics, 2022 Ding L +4 more
europepmc +1 more source
Pressurized photobonding for 3D-printed inertial and droplet microfluidics
Lab on a ChipPress-cure rapidly bonds SLA-printed microfluidics with sub-100 μm fidelity, multi-height 3D routing, and >300 psi operation, enabling dense droplet arrays, inertial focusing with spacing control, viscous micromixing.
Vivek Rajasenan +6 more
openaire +2 more sources