after the microscope and on both sides

of the channel. These heating elements

create steam bubbles that push the

cells into the right channel. Sorting

with these jet flow generators takes

about 100 microseconds per cell. This

speed is unique, and is also the result

of not using any moving elements.

Our scientists have performed an

experiment in which the cell sorter had

to isolate monocytes from a PMBC-

sample (Peripheral Blood Mononuclear

Cell) with monocytes and lymphocytes.

The sorter, using the jet flow generators,

was able to move 88% of the cells to

the correct output channel. The purity

of the collected monocytes at the chip’s

exit was 99%. These are exceptional

results proving that the cell sorter does

what it has been designed for. One way

of further improving the accuracy of the

jet flow generators is adding a sensor

that communicates the exact position

and speed of a passing cell to the jet

flow generators.

The power of parallelization

This concept and prototype of a cell

sorter becomes extremely powerful if

you consider the parallelization that is

possible with the silicon technology.

The first prototype has one microfluidic

channel with a lens-free microscope

and with jet flow generators on both

sides of the channel – but it is fairly

straightforward to extend this design

to hundreds of channels that function

in parallel and thus can sort hundred

Figure 3: Silicon wafer holding 20 prototypes of the high-

throughput ‘cell sorter’ chip

Figure 4A: Lens free

digital holographic

microscopy captures the

interference of direct

laser light with light that

has passed through the

cell

Figure 4B: Demo

setup of the lens free

microscope

Figure 5: With the help of lens-free microscopy, three types of white

blood cells may be recognized in a blood sample

thousands and even millions of cells.

That way, it becomes possible to

attain an unseen throughput for cell

analysis and isolation. In our design,

the number of channels we can add

is limited by the chip area and related

cost (we estimate that a hundred

channels will take up a square

centimeter of silicon); by the power of

the laser of the lensfree microscope;

and by the computations needed

for the image recognition. Currently,

the researchers work to fabricate

a 5-channel sorter as a proof-of-

concept for the improved throughput

and parallel sorting.

About the author

Liesbet Lagae - R&D manager lifescience

technologies, imec

Liesbet Lagae is co-founder and currently

R&D program manager of the life science

technologies activities in imec. In this role,

she oversees the emerging R&D of all the

life science technologies activities at imec.

She holds a PhD degree from the KU

Leuven, Belgium for her work on Magnetic

Random Access Memories obtained under

an IWT grant. As a young group leader,

she has initiated the field of molecular

and cellular biochips based on magnetic,

plasmonic, electrical sensing principles

intelligently combined with fluidics to do

full diagnostic analysis at IMEC, Belgium.

She is also appointed as a professor in

nanobiophysics at the KU Leuven. She has

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