Store and read programs Genetic system By analogy with macroscopic devices, feasible molecular machines presumably include manipulators able to wield a variety of tools. Thermal vibrations in typical structures are a modest fraction of interatomic distances; thus, such tools can be positioned with atomic precision.
As present microtechnology 2 can lay down General electric term paper on a molecular scale 10 nm and molecular devices can respond to electric potentials through conformation changes, etc.
Further, by analogy with biological sensors, molecular scale instruments can evidently produce macroscopic signals, indicating the feasibility of feedback control in molecular manipulations.
Together, these arguments indicate the feasibility of devices able to move molecular objects, position them with atomic precision, apply forces to them to effect a change, and inspect them to verify that the change has indeed been accomplished.
It would be foolish to minimize the time and effort that will be required to develop the needed components and assemble them into such complex and versatile systems.
Still, given the components, the path seems clear. Ordinary chemical synthesis relies on thermal agitation to bring reactant molecules in solution together in the correct orientation and with sufficient energy to cause the desired reaction.
Enzyme-like molecular machines can hold reactants in the best relative positions as bonds are strained or polarized.
Like some enzymes, they can do work on reactant molecules to drive reactions not otherwise thermodynamically favored. These are clearly techniques of great power, yet the synthetic capabilities of systems based on polypeptide chains might seem limited by amino acid properties.
However, enzymes show that other molecular structures bound to the polypeptide such as metal ions and complex ring structures 11 can extend protein capabilities.
The range of such tools is large and greater than found in nature. Thus, the synthetic capabilities of enzymes set only a lower bound on the capabilities of engineered protein systems.
Indeed, as tool-wielding protein systems can control the chemical environment of a reaction site completely, they should be able, at a minimum, to duplicate the full range of moderate-temperature synthetic steps achieved by organic chemists.
Further, where chemists must resort to complex strategies to make or break specific bonds in large molecules, molecular machines can select individual bonds on the basis of position alone. Conventional organic chemistry can synthesize not only one- two- and three-dimensional covalent structures but also exotic strained and fused rings.
With the addition of controlled site-specific synthetic reactions, a broad range of large complex structures can doubtless be built.
Still, the synthetic abilities of protein machines will be limited by their need for a moderate temperature aqueous environment although applied forces can sometimes replace or exceed thermal agitation as a source of activation energy and reaction sites and reactive groups can be protected from the surrounding water, as in some enzymatic active sites.
These limits may be sidestepped by using the broad synthetic capabilities outlined above to build a second generation of molecular machinery whose components would not be coiled hydrated polypeptide chains but compact structures having three-dimensional covalent bonding.
There is no reason why such machines cannot be designed to operate at reduced pressure or extreme temperatures; synthesis can then involve highly reactive or even free radical intermediates, as well as the use of mechanical arms wielding molecular tools to strain and polarize existing bonds while new molecular groups are positioned and forced into place.
This may be done at high or low temperature as desired.
The class of structures that can be synthesized by such methods is clearly very large, and one may speculate that it includes most structures that might be of technological interest. Firmness of the argument The development path described above should lead to advanced molecular machinery capable of general synthesis operations.
As the results of this path can be shown to have consequences for the present, it is of interest to discuss the degree of confidence that should be placed in its feasibility. It might be argued that complex protein or nonprotein machines are impossible or useless, on the grounds that, if they were possible and useful, organisms would be using them.Your reference list should appear at the end of your paper.
It provides the information necessary for a reader to locate and retrieve any source you cite in the body of the paper. Welcome to the Restructuring Case for Westinghouse Electric Company LLC, et al. At first glance, the market’s ~8 percent rally on shares of General Electric (NYSE:GE) on June 26, , would signal an approval for the healthcare and oil services leslutinsduphoenix.com company will add $3.
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