Tardigrades To Saturns Titan

Here in Book Club photos of Saturn’s moon shows there is a unique opportunity to relay video streaming where new modified Tardigreds "Water Bears" these would have an intelligence to allow them to have adaptable atomic structure able to communicate via signals. Humans have the ability to consider the exploration of live images of other worlds for private sale distribution, for example people would pay for to see live images of sea of Titan, Saturn’s Moon using exciting robotic exploitative works as seen in video below. Also could show daily live art shows on the surface of the moon even broadcasts asking several questions as thousands log on daily. As these complex robotics can reshape the surface of Titans Moon one of Saturn could be mapped out either for future colonisation or learning why you may ask moons? Well answer is gravitational pull isn’t as strong as it is easier to leave for earth and not hard to build complex quarters outposts. for example humans know very few resources on earths moon to make it viable makes for little business sense for the world to venture there. But as new technologies come about making television programs from their first origins. "Virgin Galactic" with many more to come funded by subscriptions use magazine these will be the first private operators into space so this brings down the cost as advertising revenues sore beyond ISS. This is a first docking station platform with its fifty pieces been shunted by America so god bless NASA and USA, but there will be in future space survival telescopes in circular orbits waiting for earth to orbit the sun. This is get a greater understanding as to planetary effects on the sun echo balance as it travels quite quick true deep space. Perhaps a laboratory will give Tardigrades new abilities, as this creature in laboratory can have exploitative capabilities for example electronic transfer of visual data. Though many will not want to astatine this formation or dare to fantasize its artistic applications, mainly because of human phobia to developing “a space species” it would be first small step for man in the learning curve of how to dominate a potential habitat for Human endeavour its always interesting to look at reproductive generative cycle it’s kind of non descriptive but highly mobile and monitored in restricted location the water bear kind of cute aquatic creature that can live on the moon of Titan. Here at Book Club transport to and from moon shaped planets can now be simplified here is a short definition of how this may occur. the velocity of the electron in orbit to the speed of light. FSC = v / c = 1 / 137 = 0.73%v = 0.73% * c where c = 186,000 miles per second. v = 4,888,080 miles per hour. The electron is traveling almost 5 million mile per hour around the nucleus of the atom. FSC is the ratio of the velocity of the electron in orbit to the speed of light an electron is traveling at But, the image needs to be a wave not just a single particle, in orbit traveling at that speed. FCS defines the interactions of all electrically charged particles for example to power a space ship to make it commutable within a few hours needs to be powered off from a polar flux maybe from earth, electrons, muons, and photons. These fine structure are at a constant that shows up in these equations is directly proportional to the velocity of light and the electric charge particles. Also combining Researchers at MIT in Boston have revealed a new technique that can place sensors inside Tardigrades tissue. To control the three-dimensional shape of engineered tissue, researchers grow cells on tiny, sponge-like scaffolds. A 3-D tissue scaffold containing tiny sensors - researchers say it could be used to implant medical sensors into patients by 'growing' them into tissue. The team also grew blood vessels with embedded electronic sensors and showed that they could be used to measure pH changes within and outside the vessels using Tardigrades. A team of researchers from MIT, Harvard University and Boston Hospital has now added a new element to tissue scaffolds: electronic sensors. These sensors, made of silicon nano wires, could be used to monitor electrical activity in the tissue surrounding the scaffold, control drug release or screen drug candidates for their effects on the beating of heart tissue. We are very excited about this study,' Robert Langer, the David H. Koch Institute Professor at MIT and a senior author of the paper said. It brings us one step closer to someday creating a tissue-engineered heart, and it shows how novel nano materials can play a role in this field. The researchers built their new scaffold out of epoxy, a nontoxic material that can take on a porous, 3-D structure. Silicon nano wires embedded in the scaffold carry electrical signals to and from cells grown within the structure. The scaffold is not just a mechanical support for cells, it contains multiple sensors. We seed cells into the scaffold and eventually it becomes a 3-D engineered tissue ready for directive communication. Here in Book Club the project leader Tian told us the team chose silicon nano wires for electronic sensors because they are small, stable, can be safely implanted into living tissue and are more electrically sensitive than metal electrodes. The nano wires, which range in diameter from 30 to 80 nano meters (about 1,000 times smaller than a human hair), can detect voltages less than one-thousandth of a watt, which is the level of electricity that might be seen in a cell. Cyborgs such as in Robocop have long been a staple of sci-fi films. Now researchers at MIT have made a big step towards making them reality. In the Nature Materials study, the researchers used their scaffolds to grow cardiac, neural and muscle tissue. Using the engineered cardiac tissue, the researchers were able to monitor cells’ response to noradrenalin, a stimulant that typically increases heart rate. Gordana Vunjak-Novakovic, a professor of biomedical engineering at Columbia University, says the work could help address a great need to engineer cells that respond to electrical stimuli, which may advance the treatment of cardiac and neurological disease. This is a beautiful example of how nano electronics can be combined with tissue engineering to monitor the behaviour of cells,' says Vunjak-Novakovic.