LISTSERV 16.0 - PARKINSN Archives

Fascinating that you found this in Popular Mechanics! I am not a number, I am an Erector-Set! (remember those?)

-----Original Message-----
From: Parkinson's Information Exchange Network [mailto:[log in to unmask]] On Behalf Of Nic Marais
Sent: Tuesday, October 12, 2010 12:48 PM
To: [log in to unmask]
Subject: Nerve-cell regeneration quest is fast tracked

http://www.popularmechanics.co.za/content/news/singlepage.asp?key=1080

12 October 2010
Nerve-cell regeneration quest is fast tracked


Scientists have long sought the ability to regenerate nerve cells, or
neurons, which could offer a new way to treat spinal-cord damage as
well as neurological diseases such as Alzheimer�s or Parkinson�s. Many
chemicals can regenerate neurons grown in Petri dishes in the lab, but
it�s difficult and time-consuming to identify those chemicals that
work in live animals, which is critical for developing drugs for
humans.

Engineers at the Massachusetts Institute of Technology (MIT) have now
used a new microchip technology to rapidly test potential drugs on
tiny worms called C. elegans, which are often used in studies of the
nervous system. Using the new technology, associate professor Mehmet
Fatih Yanik and his colleagues rapidly performed laser surgery,
delivered drugs and imaged the resulting neuron regrowth in thousands
of live animals.

�Our technology helps researchers rapidly identify promising chemicals
that can then be tested in mammals and perhaps even in humans,� says
Yanik. Using this technique, the researchers have already identified
one promising class of neuronal regenerators.

The paper will appear in the online edition of the Proceedings of the
National Academy of Sciences the week of 11 October.

Rapid analysis
C. elegans is a useful model organism for neuron regeneration because
it is optically transparent, and its entire neural network is known.
Yanik and colleagues had previously developed a femtosecond laser
nanosurgery technique which allowed them to cut and observe
regeneration of individual axons � long extensions of neurons that
send signals to neighbouring cells. Their femtosecond laser
nanosurgery technique uses tightly-focused infrared laser pulses that
are shorter than billionth of a second. This allows the laser to
penetrate deep into the animals without damaging the tissues on its
way, until the laser beam hits its final target.

In the PNAS study, the researchers used their microchip technology to
rapidly cut the axons of single neurons that sense touch. Moving
single worms from their incubation well to an imaging microchip,
immobilising them and performing laser surgery takes only about 20
seconds, which allows thousands of surgeries to be performed in a
short period of time.

After laser surgery, each worm is returned to its incubation well and
treated with a different chemical compound. C. elegans neurons can
partially regrow without help, which allowed Yanik�s team to look for
drugs that can either enhance or inhibit this regrowth. After two or
three days, the researchers imaged each worm to see if the drugs had
any effect.

The MIT team found that a compound called staurosporine, which
inhibits certain enzymes known as PKC kinases, had the strongest
inhibitory effect. In a follow-up study, they tested some compounds
that activate these kinases, and found that one of them stimulated
regeneration of neurons significantly. Some of Yanik�s students are
now testing those compounds on neurons derived from human embryonic
stem cells.

The new technology represents a significant advance in the level of
automation that can be achieved in C. elegans studies, says Michael
Bastiani, professor of biology at the University of Utah. �Using
�classical� handling techniques you can cut and assay at most 100
animals per day,� he says. �Yanik's automated system seems like it
could increase throughput by at least 10-fold over that number.� He
points out that one potential limitation of the system is that it
might not pick up the effects of neural regenerators that can�t
penetrate the worm�s cuticle, a thick outer layer that surrounds the
skin.

However, chemicals can still be taken up through the worms� digestive
tract, which is an important test for checking whether chemicals would
work on live animals, says Yanik.

This microchip technology can also be used to screen compounds for
their effects on other diseases such as Alzheimer�s, Parkinson�s and
ALS, says Yanik.

----------------------------------------------------------------------
To sign-off Parkinsn send a message to: mailto:[log in to unmask]
In the body of the message put: signoff parkinsn

----------------------------------------------------------------------
To sign-off Parkinsn send a message to: mailto:[log in to unmask]
In the body of the message put: signoff parkinsn