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Mikrofluidische

Mikrofluidische, or microfluidics, is the science and technology of controlling and analyzing fluids at sub-millimeter scales. It deals with fluids typically organized in channels 10 to 1000 micrometers wide, handling microliter to picoliter volumes. The flow regime is usually laminar, with Reynolds numbers well below 1, enabling precise, predictable fluid handling and rapid heat and mass transfer at small scales. Key approaches include continuous-flow microfluidics, where fluids travel through networks of microchannels, and droplet-based systems, where discrete droplets act as individual reaction vessels. Digital microfluidics, based on electrowetting, manipulates droplets on an array of electrodes. Devices are commonly fabricated by soft lithography using PDMS, as well as glass or silicon microfabrication methods; integrated valves, pumps, and sensors enable automation and complex workflows.

Applications span medical diagnostics, point-of-care testing, DNA analysis and sequencing, single-cell studies, chemical synthesis, drug discovery,

History and outlook: microfluidics emerged from chemistry, biology and engineering in the late 1980s and 1990s,

and
environmental
monitoring.
Advantages
include
dramatically
reduced
reagent
consumption,
shorter
analysis
times,
parallelization,
and
the
potential
for
portable
lab-on-a-chip
systems.
Challenges
involve
fabrication
costs
and
variability,
material
compatibility
and
adsorption
of
biomolecules,
channel
clogging
and
fouling,
robust
packaging,
user-friendly
interfaces,
and
regulatory
acceptance
for
clinical
use.
Standardization
and
interfacing
with
conventional
instruments
remain
active
areas
of
development.
with
early
contributions
from
researchers
such
as
Manz
and
Whitesides,
leading
to
rapid
growth
in
research
and
commercialization.
Future
directions
include
deeper
integration
with
sensors
and
electronics,
3D-printed
microfluidic
parts,
organ-on-a-chip
models,
and
increasingly
autonomous,
AI-guided
fluidic
workflows.