Redplanet44 - Untitled

What doesn't tear you makes you doper

Substitutional defects ( 2 ) are point defects in which an impurity atom takes the place of a native atom within the crystal lattice. Semiconductors often intentionally add substitional defects through doping, such as adding boron or phosphorous to silicon to create an n- or p-type semiconductor, and certain alloys include extraneous elements to create substitional defects for solution hardening purposes.

Image source.

So the other night during D&D, I had the sudden thoughts that:

1) Binary files are 1s and 0s

2) Knitting has knit stitches and purl stitches

You could represent binary data in knitting, as a pattern of knits and purls…

You can knit Doom.

However, after crunching some more numbers:

The compressed Doom installer binary is 2.93 MB. Assuming you are using sock weight yarn, with 7 stitches per inch, results in knitted doom being…

3322 square feet

Factoring it out…302 people, each knitting a relatively reasonable 11 square feet, could knit Doom.

Tumour Markers

Chemical biomarkers that can be elevated by the presence of one or more types of cancer,  produced directly by the tumour or by non-tumour cells as a response to the presence of a tumour. Really great tests as can use just blood/urine, but aren’t the most specific and false positives do occur.

Alpha-fetoprotein (AFP) 

Glycoprotein synthesised in yolk sac, the foetal liver, and gut - will be high in a foetus and during pregnancy. 

<10 ng/mL is normal for adults

>500 ng/mL could indicate liver tumour

Normally:

Produced primarily by the liver in a developing foetus 

Thought to be a foetal form of albumin

suppress lymphocyte activation and antibody production in adults (immune suppressant)

Binds bilirubin, fatty acids, hormones and metals

In cancer:

Detects hepatocarcinoma (liver cancer)

Risk factors: haemochromotosis, hep B, alcoholism - cell repair and growth from this damage leads to cancers

Present in non-pathogenic liver proliferation, including the growth and repair response to the above. This makes it hard to differentiate - AFP levels can be raised in patients with liver cancer risk factors due to the factors themselves, not a cancer. Not very diagnostic!! Used in combination with other tests/factors. Sensitivity and specificity ~75%

Other hepatocellular carcinoma markers:

γGT (γ-glutamyltransferase) - biliary damage

AFP mRNA (not always together with AFP! Might not be activated)

γGT mRNA elevated

Raised cytokines (IL-8, VEGF, TGF-B1) 

ALT and AST elevated - liver disease

Carcinoembryonic antigen (CEA)

a set of highly related glycoproteins involved in cell adhesion. Potentially associated with innate immune system.

Normally:

produced in gastrointestinal tissue during foetal development 

production stops before birth

present only at very low levels in the blood of healthy adults. 

Cancer:

Elevated in almost all patients with colorectal cancer

Can monitor recurrence of cancer (when compared to previous test results for that patient) with a sensitivity of 80% and specificity of 70%

levels may also be raised in gastric, pancreatic, lung, breast and medullary thyroid carcinomas

also some non-neoplastic (not cancer) conditions like ulcerative colitis, liver disease, pancreatitis,  COPD, Crohn’s disease, hypothyroidism - again, high risk groups for colorectal cancer - not a diagnostic test

Levels elevated in smokers.

Carbohydrate antigens (CA)

Including:

CA 19-9 - Pancreas

CA 15-3 Breast

CA 50 - Colorectal

CA 125 - ovarian

Levels rise only in disease states and particularly cancer, but will not rise in all patients.

Part 2 coming soon!

Skin gel allows wounds to heal without leaving a scar

A team of researchers at Huazhong University of Science and Technology has developed a silk protein-based gel that they claim allows for skin healing without scarring. In their paper published in the journal Biomaterials Science, the group describes their gel and how well it works.

Scarring due to a skin injury is not just unsightly—for many, it can also be a painful reminder of a wound. For these reasons, scientists have sought a way to heal wounds without scarring. In this new effort, the team in China claims to have found such a solution—a sericin hydrogel.

The gel used by the researchers was based on a silk protein—the researchers extracted sericin from silk fibers and then used a UV light and a photoinitiator to cross-link the protein chains. The result was a gel that adhered well to cells and did not trigger much of an immune response. The researchers note that it also has adjustable mechanical properties. They explain that the gel allows for scar-free healing by inhibiting inflammation and by promoting the development of new blood vessels. It was also found to regulate TGF-β growth factors, which resulted in stem cells being routed to the injury site allowing new skin to develop, rather than scar tissue.

Read more.

(via MIT researchers turn water into ‘calm’ computer interfaces)

…The Tangible Media Group demonstrated a way to precisely transport droplets of liquid across a surface back in January, which it called “programmable droplets.” The system is essentially just a printed circuit board, coated with a low-friction material, with a grid of copper wiring on top. By programmatically controlling the electric field of the grid, the team is able to change the shape of polarizable liquid droplets and move them around the surface. The precise control is such that droplets can be both merged and split.

Moving on from the underlying technology, the team is now focused on showing how we might leverage the system to create, play and communicate through natural materials…

Smart ink adds new dimensions to 3-D printing

Researchers at Dartmouth College have developed a smart ink that turns 3D-printed structures into objects that can change shape and color. The innovation promises to add even more functionality to 3D printing and could pave the way to a new generation of printed material.

The advancement in the area of form-changing intelligent printing - also known as 4D printing - provides a low-cost alternative to printing precision parts for uses in areas ranging from biomedicine to the energy industry.

“This technique gives life to 3D-printed objects,” said Chenfeng Ke, an assistant professor of chemistry at Dartmouth. “While many 3D-printed structures are just shapes that don’t reflect the molecular properties of the material, these inks bring functional molecules to the 3D printing world. We can now print smart objects for a variety of uses.”

Many 3D printing protocols rely on photo-curing resins and result in hard plastic objects with rigid, but random molecular architectures. The new process allows designers to retain specific molecular alignments and functions in a material and converts those structures for use in 3D printing.

Read more.

Carrying and releasing nanoscale cargo with ‘nanowrappers’

This holiday season, scientists at the Center for Functional Nanomaterials (CFN) – a U.S. Department of Energy Office of Science User Facility at Brookhaven National Laboratory – have wrapped a box of a different kind. Using a one-step chemical synthesis method, they engineered hollow metallic nanosized boxes with cube-shaped pores at the corners and demonstrated how these “nanowrappers” can be used to carry and release DNA-coated nanoparticles in a controlled way. The research is reported in a paper published on Dec. 12 in ACS Central Science, a journal of the American Chemical Society (ACS).

“Imagine you have a box but you can only use the outside and not the inside,” said co-author Oleg Gang, leader of the CFN Soft and Bio Nanomaterials Group. “This is how we’ve been dealing with nanoparticles. Most nanoparticle assembly or synthesis methods produce solid nanostructures. We need methods to engineer the internal space of these structures.”

“Compared to their solid counterparts, hollow nanostructures have different optical and chemical properties that we would like to use for biomedical, sensing, and catalytic applications,” added corresponding author Fang Lu, a scientist in Gang’s group. “In addition, we can introduce surface openings in the hollow structures where materials such as drugs, biological molecules, and even nanoparticles can enter and exit, depending on the surrounding environment.”

Read more.

And also math is a common language for spanish and chinese people. The original esperanto :)

Cooking With Neil DeGrasse Tyson

Breakthrough in blending metals—precise control of multimetallic one-nanometer cluster formation achieved

Researchers in Japan have found a way to create innovative materials by blending metals with precision control. Their approach, based on a concept called atom hybridization, opens up an unexplored area of chemistry that could lead to the development of advanced functional materials.

Multimetallic clusters—typically composed of three or more metals—are garnering attention as they exhibit properties that cannot be attained by single-metal materials. If a variety of metal elements are freely blended, it is expected that as-yet-unknown substances are discovered and highly-functional materials are developed. So far, no one had reported the multimetallic clusters blended with more than four metal elements so far because of unfavorable separation of different metals. One idea to overcome this difficulty is miniaturization of cluster sizes to one-nanometer scale, which forces the different metals to be blended in a small space. However, there was no way to realize this idea.

Read more.