BigBrain: An Ultrahigh-Resolution 3D Human Brain Model

For more information please refer to:
- Science, 21 JUNE 2013 VOL 340 p.1472 (sciencemag.org)
cbrain.mcgill.ca"

Preparation of brain micro-slices for BigBrain project

Scientists create the world's first high-definition 3D model of a HUMAN BRAIN

dailymail.co.uk

Looking at the Invisible

Can you hear the unhearable? Can you see the unseeable? 

Common sens says no, adding "of course not".

Well check this out as it might give you access to what you thought impossible, therefore enrich your cerebral connections, and perhaps widen your fields of perception.


 New camera makes seeing the "invisible" possible 

"A group of researchers at Missouri University of Science and Technology in Rolla has developed a handheld camera that uses microwave signals to non-destructively peek inside materials and structures in real time." MissouriSandT 

news.mst.edu

Impossible colors

"Impossible colors are hues that can only be perceived under specific conditions. 
Examples of impossible colors are bluish-yellow and reddish-green.
This does not mean the muddy brown color created when mixing red and green paints, or the green color from yellow and blue, but completely unique "new" colors."  wikipedia.org


Have you ever seen the color bluish yellow?

Some people may be able to see the color "yellow-blue" in this image. Allow your eyes to cross until both + symbols are on top of each other.

 A graph or how the brain interprets color.

Hue scale 0—360°

Scientific America

"Impossible" Colors: See Hues That Can't Exist

"Red and green are called opponent colors because people normally cannot see redness and greenness simultaneously in a single color. The same is true for yellow and blue.

Researchers have long regarded color opponency to be hardwired in the brain, completely forbidding perception of reddish green or yellowish blue.

Under special circumstances, though, people can see the “forbidden” colors, suggesting that color opponency in the brain has a softwired stage that can be disabled.

In flickering light, people see a variety of geometric hallucinations with properties suggestive of a geometric opponency that pits concentric circles in opposition to fan shapes."

 scientificamerican.com

3d-today.org/search/label/optic

Now Comes Flesh Printing

Now 3D printing which started a few decades ago, has kept this name albeit not a printing act anymore but a construction for which a more appropriate term would be welcome.

In fact, the access to that third dimension is opening new horizons in many fields and will certainly develop in domains that are, still now, unimaginable, such as architecture.

Yes, as it is just a matter of scale and proper building material, we shall see, together with technologies yet unknown, and others already developping such as automation and robotics, the birth of new concepts.

Already, at smaller scales, we see materials being used and adapted to various purposes from the traditional sculpture, to biological matter, while on the other hand, research on stem cells allows us to foresee new domains that, yesterday, belonged to science fiction.

In 1962, Marshall Mc Luhan published his book "The Gutenberg Galaxy" in which he brilliantly forecasts the prevalence of electronic media to the detriment of printed media.

In fact what he calls "the Marconi galaxy" developped widely even though printed matter was still going on and developping as well.

He regarded wireless means of communication (and therefor created the word "media") as the future, a new era.

Little did he know (and could not imagine) the wide spread of computers, personal computers and the tremendous explosion of digital technologies.

Neither could-he conceive the birth of 3D!

Text by © Armand Dauré 

More about him:

The Gutenberg Galaxy en.wikipedia.org

De humani corporis fabrica libri septem (On the fabric of the human body in seven books) is a textbook of human anatomy written by Andreas Vesalius (1514–1564) in 1543. 

wikipedia.org

Printable organs

Using modified inkjet printers into 3d printers, scientists are producing three-dimensional living biological tissue. The printer cartridges are washed out and filled with a suspension of living cells and a "smart gel". Alternating patterns of the smart gel and living cells are printed using a standard print nozzle. The cells fuse together to form tissue, and tube formation has been demonstrated with ovarian hamster cells. When finished, the gel is cooled and washed away, leaving behind only the live cells.
The gel is heat sensitive - solidifying at 32 degrees celsius and liquifying at 20 degrees

en.wikipedia.org

 What is the Bio-Printing?

The bio-printer is the product of nScrypt Inc. It is a fully computer-controlled delivery device. Three-dimensional printing is achieved by the movable x-y stage and three z-directional printing heads. Two of these are used to print the bio-ink particles, which are extruded from a bio-cartridge (a micropipette filled with bioink particles) by the positive displacement of a piston within the micropipette. The third unit is pressure operated and is used to print the bio-paper/substrate (e.g. collagen gel). Each extruder is equipped with a camera, providing full visual control of printing.

What is the Tensiometer?

The parallel plate compression device allows determining tissue surface tension and characteristic elastic and viscous parameters. A spherical cell aggregate (A) is placed between the lower (LCP) and upper (UCP) compression plates, in the inner chamber filled with tisssue culture medium. A water jacket, the outer chamber (OC) heats up the system to maintain 37C physiological temperature. The upper plate hangs from a nickel-chromium wire (NCW) attached to an electrobalance (B) that monitors the force applied to the aggregate. Raising the lower compression plate compresses the cell aggregate. This deformation is maintained throughout the compression to measure force dissipation under constant strain. Equilibrium is reestablished through a biphasic relaxation process; the equilibrium force and the geometric parameters are used to calculate the tissue surface tension via the Laplace-Young equation. Viscoelastic properties are determined employing the full relaxation curve.

What is the Magnetic Tweezers?

The magnetic tweezers allows measuring intracellular and cell-level viscoelastic parameters. It is a 2-coil design, capable of generating a constant magnetic gradient (and implicitly a constant magnetic force) over a surface exceeding 4x105 square microns. It is a miniaturized Faraday balance mounted on the stage of an inverted Olympus IX-70 microscope. The force (in the range of 1-1000 pN) is applied unidirectionally, in the horizontal plane, through paramagnetic beads attached to the biological sample. The bead motion under magnetic force is recorded and the trajectory is determined with sub-pixel accuracy by an in-house developed particle tracking program. Physical parameters are determined from the analysis of the bead trajectory.

 How to print a human organ?

Organ Printing: Future of Rapid Prototyping in Tissue Engineering

 

 How to print a organ by Vladimir Mironov

 PDF: organprint.missouri.edu

BBC News
Dr. Vladimir Mironov explains organ printing technology. (2009)

US researchers at Cornell University have engineered an ear made of silicone using a 3D printer, which they hope will one day be capable of producing functional human body parts.

LINKS:

organprint.missouri.edu

Hod Lipson: mae.cornell.edu

Sober men can't walk straight

3D TODAY: Sober men can't walk straight: http://bit.ly/hIxXYA