An image of mouse ear
skin acquired by multiphoton microscopy showing hair follicles (green), blood
vessels (red) and collagen fibers (blue)
A novel live-cell
imaging technique offers new opportunities to understanding immune responses in
the skin
Biologists
often use a technique called multi-photon imaging to examine live cells. The
technique is unique in that it uses multiple photons of high wavelengths to
stimulate fluorescent labels, causing them to emit light. It is superior to
more conventional fluorescence imaging techniques, such as confocal microscopy,
as it has a higher spatial resolution and enables greater depth of penetration
into tissues. Lai Guan Ng at the A*STAR Singapore Immunology Network and co-workers1
have extended the capability of multi-photon imaging further so that it can now
be used to directly visualize immune responses in skin.
The
skin is known to have two layers: the dermis and the epidermis. The epidermis
is predominantly avascular, containing specialized skin cells called
keratinocytes, whereas the underlying dermis contains highly vascularized
lymphatic vessels. Conventional fluorescence microscopy only allows imaging
into the epidermis and limited structures of the dermis below. The multi-photon
imaging technique developed by Ng and his team offers simultaneous imaging of
multiple cellular and structural components through the epidermis and into the
dermis (see image).
The
researchers provide a step-by-step guide to preparing a live mouse ear skin
model which can be used to probe skin response to localized injury or disease
over several hours. They placed a glass slide over the ear, which acts as a
window through which to observe the tissue without surgery. The mouse ear is a
good site for imaging because it requires minimal pre-treatment and is easily
accessible.
The
researchers could take images more quickly — for example, on a per-second basis
— by adjusting various experimental parameters, thereby enabling them to study
fast-moving cells such as rolling leukocytes.
The
researchers recommend albino mice to prevent any artifacts arising from
photodamage to the skin. They provide a comprehensive checklist for preparation
of the ear for imaging to ensure that the integrity of the blood vessels is not
being compromised. They also describe a protocol to induce local laser injury,
the biological response of which can then be studied. The protocol has a
troubleshooting section that can be used to resolve problems that others may
encounter when they come to repeat the experiment.
So
far, the researchers have used their approach to study a variety of skin
conditions, for example, parasitic infection, T-cell lymphoma migration and
neutrophil response to sterile injury amongst others.
“We
envision that this approach will not only continue to unravel new knowledge
relating to the skin immune system, but also gradually become a standard
approach for assessing drug delivery as well as percutaneous and intradermal
vaccine applications in preclinical studies,” says Ng.
The A*STAR-affiliated researcher contributing to this
research is from the Singapore
Immunology Network
References
- Li, J. L.-Y. et al. Intravital multiphoton imaging of
immune responses in the mouse ear skin. Nature Protocols 7,
221–234 (2012). | article
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