This gives rise to hydrogen bonds H-bonds between the water molecules Figure 7.5, which means that water is a liquid at room temper-ature and pressure, whereas the much heavier carbon di
Trang 1Micro Total Analysis Systems 161
(CCl4), there will be a dipole setup with the chlorine atoms being slightly more
negative than the carbon atoms, i.e., the bonds will be polarized
This effect is very important in water, where the bonds between hydrogen and
oxygen are polarized This gives rise to hydrogen bonds (H-bonds) between the
water molecules (Figure 7.5), which means that water is a liquid at room
temper-ature and pressure, whereas the much heavier carbon dioxide molecule is a gas
7.2.1.2 pH
In an aqueous solution (i.e., when substances are dissolved in water), things are
never constant Water molecules themselves are continually breaking up and
recombining, although most of them will remain as molecules for the majority
of the time As with all chemical equations, however, an equilibrium is set up:
The degree to which this reaction is shifted to the right-hand side of the
equation is shown by the pH, which is a logarithmic measure of the concentration
of hydrogen ions in the solution Pure water has a pH of 7 A pH of less than 7
means that the solution is hydrogen-ion-rich and therefore acidic A pH of more
than 7 means that it is hydrogen-ion-poor (and thus rich in hydroxide, OH−, ions)
or alkaline Compounds that dissolve readily in water, giving up hydrogen ions,
therefore form acids Hydrogen chloride (HCl) is one example of a gas that forms
a strong acid when dissolved in water
Potassium hydroxide (KOH, see Equation 7.4), when dissolved in water, releases
hydroxide ions and so forms an alkaline solution (alkali-forming compounds are
called bases) Potassium hydroxide and hydrogen chloride react in solution:
KOH (s) + HCl (aq) → KCl (aq) + H2O (l) (7.9) (Acid plus base forms a salt plus water.) The states of the different compounds
are given in brackets A solid powder of potassium hydroxide is dissolved in an
FIGURE 7.5 Hydrogen-bonding in water The small hydrogen atoms in a molecule form
weak bonds with larger oxygen atoms in adjacent molecules.
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aqueous solution of hydrogen chloride, giving rise to an aqueous solution of
potassium chloride and water (a liquid)
7.2.2 O RGANIC C HEMISTRY
Carbon is the most versatile of all the elements and forms many complex
mole-cules Organic chemistry is the name given to the study of carbon chemistry,
because it is this chemistry that is the basis of life on this planet The basic form
is the long-chain saturated hydrocarbon, the alkane Table 7.2 shows the chemical
formula, name, and bond structure of the first few alkanes
It is important to note that the structures shown in Table 7.2 are merely
two-dimensional representations of three-dimensional structures (Figure 7.6)
TABLE 7.2
Chemical Composition, Name, and Bond Structure — Methane
to Hexane
Chemical formula Name Bond structure
H
| H-C-H
| H
C 2 H 6 Ethane
H H
| | H-C-C-H
| |
H H
C 3 H 8 Propane
H H H
| | | H-C-C-C-H
| | |
H H H
C 4 H 10 Butane
H H H H
| | | | H-C-C-C-C-H
| | | |
H H H H
C 5 H 12 Pentane
H H H H H
| | | | | H-C-C-C-C-C-H
| | | | |
H H H H H
C 6 H 14 Hexane
H H H H H H
| | | | | | H-C-C-C-C-C-C-H
| | | | | |
H H H H H H
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Unsaturated hydrocarbons are those containing a double (-ene) or triple (-yne)
bond between carbon atoms (Figure 7.8) Also, as shown in Figure 7.7, the carbon
atoms can form a variety of ring structures (cyclic molecules) as well as long chains
Table 7.3 lists a variety of different functional groups that can add on to a
hydrocarbon molecule to change its chemistry, and Figure 7.9 illustrates some
different kinds of stereoisomers (molecules that have the same chemical and
structural formula but different arrangements of bonds in space)
7.2.2.1 Polymers
Carbon compounds can contain very long chains of carbon atoms, plastics being
one such example The molecules of plastics are made of repeats of many smaller
identical units The common plastic polythene (actually, polyethene) is composed
of many ethene molecules (Equation 7.10) In the presence of a strong catalyst (which
is something that assists in a reaction without being consumed itself), the double
bond between carbon atoms is opened out, enabling two molecules to join This
leaves two more bonds at the end of the chain, encouraging more molecules to join,
and so on, until something causes the chain to stop growing (running out of ethene
molecules, for instance) One consequence of this is that the molecules in a plastic
will be of different lengths, depending on when the chains stopped growing:
nCH2 = CH2(g) → –(CH2–CH2)–n (7.10) Polymers can also form through chemical reactions between two small
precursor materials Nylon 66 is formed by a reaction between a diamine
(hexane-1,6-diamine) and a dicarboxylic acid (hexane-1,6-dioic acid):
nH2N(CH2)6NH2+ nHOOC(CH2)4COOH → –(HN(CH2)6NHOC(CH2)4CO)–n+ 2nH2O (7.11)
FIGURE 7.8 (a) Ethene, (b) ethyne.
Cross-Linking
The properties of a polymer can be further controlled by adding agents that
join chains together; this is known as cross-linking The physical properties
will depend on the amount of the chemical that is added, which controls the
amount of cross-linking that occurs Rubbers are a good example of the
application of cross-linking; many are very soft in their pure state, but
increas-ing the crosslinkincreas-ing makes them harder and chemically more resilient
H C C H
C C
DK3182_C007.fm Page 164 Thursday, January 19, 2006 11:17 AM
Trang 4Silicones are important engineering materials (not just for MEMS) because they are chemically relatively inert and stable with changes in temperature Silicones are not naturally occurring polymers, unlike long-chain carbon mole-cules, and have to be manufactured
7.2.3 B IOCHEMISTRY
Because organic chemistry has developed from its original definition as the chemistry of compounds found in living things to encompass the entirety of carbon-based chemistry, biochemistry has developed to encompass this original area: the molecules found in living organisms and how they work together Different molecules in the cells of living organisms perform different func-tions These include, among others, the following:
• Storage of genetic information (which encodes instructions for making different proteins — it apparently stores all the information required
to make an organism)
• Replication of genetic information
• Translation of genetic information into proteins
• Formation of structural elements (membranes and skeletal components, and also molecular machines)
• Energy storage
• Signaling (enabling the cell to react to different environmental condi-tions)
• Communication (with other cells)
• Catalysts
This section will introduce three of the major classes of large molecules in the cell — proteins, lipids, carbohydrates — and the nucleic acids The two nucleic acids, deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) are the molecules that store genetic information (DNA) and translate it into proteins (RNA) Proteins are the workhorses in the cell: they form structures, such as the skeleton, molecular motors, molecular machines, and signaling systems They also participate in or catalyze the reactions used to build (synthesize) other molecules (anabolism) and break down molecules (catabolism)
One of the main tasks for lipids in the cell is the formation of membranes within the cell as well as those that form the outer skins of cells The cell is not, as it may
Silanes
The small molecules of silicon chemistry are silanes (or organosilanes if they involve carbon atoms) The simplest molecule of them all is silane itself:
SiH4 Compare this formula with that for methane, CH4
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first appear, a number of interconnected reaction chambers (analogous to an indus-trial chemical plant, where chemicals enter at various points and are pumped through pipes into different reaction vessels, at different temperatures and pressures, until the desired chemical product emerges at the other end) It is much more analogous
to a manufacturing plant with robots moving various components around and assem-bling them into larger parts A lot of this work takes place on membranes (or by proteins embedded in membranes) Additionally, small molecules (or ions) can be pumped across membranes as required, larger molecules can be made to flip from one side of a membrane to the other, and membranes can even be formed into spherical vesicles, which then detach and can carry a particular cargo to another part
of the cell The main components of these membranes are lipids
Probably the best known carbohydrate is sugar, which is an energy store The use of carbohydrate as a structural component is most obvious in plants, where the fibrous cell walls are formed from a carbohydrate (cellulose), and the exo-skeletons of insects (chitin) Carbohydrates also combine with proteins, forming glycoproteins, which take on various tasks In humans, they are evident (on a common day-to-day basis) as mucopolysaccharides, which form syrupy or gel-like mixtures in water (mucus)
7.2.3.1 Proteins
Proteins are complex polymers composed of amino acids — small organic mol-ecules that incorporate an amino group (–NH2) and a carboxyl group (–COOH) (see Table 7.3) The amino group of one amino acid in the protein reacts with the carboxyl group of the next forming a peptide bond; proteins are, therefore, also called polypeptides Although there are a vast number of possible amino acids, there are only 20 that are encoded for in DNA and commonly found in proteins (they can, however, be modified after being incorporated into the protein) These are:
• Arginine
• Asparagine
• Aspartic acid
• Glutamic acid
• Histadine
• Isoleucine
• Lysine
• Phenylalanine
• Proline
• Serine
Trang 6• Threonine
• Tyrosine
• Valine
The basic form of 19 of the common amino acids is shown in Figure 7.11 Proline is the exception to the rule The fundamental (primary) structure of a protein, then, is in the form of a chain of amino acids, with a backbone of peptide bonds from which project different side chains
It was noted in Subsection 7.2.1.1 that different molecules are polarized to different extents This is true of the amino acid side chains in proteins Related
to this, it can be seen that different side chains are more or less hydrophobic (do not mix with water); this is important because water is a very small molecule compared to most biological molecules, and as a result, a single protein may be surrounded by thousands of water molecules The polarized side chains and hydrophobic side chains cause the protein molecule to fold up on itself, the degree
of folding being restricted by the flexibility of the bonds between amino acids in the chain This gives rise to a further level of structure within the protein molecule itself — the secondary structure
The features of the secondary structure can generally be classified as either helices, sheets, loops, or turns A helix occurs when amino acids along the backbone of the protein coil up A sheet occurs when several lengths of amino acid chains run parallel to one another Helices and sheets are normally intercon-nected by short turns or may have longer chains (loops) between them
It is, however, the way that these features fold in on themselves — the tertiary structure — that gives the biggest clue to what a protein does This determines the shape of the protein and how charge is distributed over its surface Proteins may be designed to bond very specifically to particular molecules or to hold two molecules close together in order to catalyze the reaction between them Alter-natively, the addition or removal of a phosphate group may radically alter the shape of the molecule, enabling it to act as a motor, for instance
There is a further level of structure — the quaternary structure — in which different polypeptides come together to form very complex structures (protein machines) and the individual protein molecules are not covalently bonded together, although they act as one unit A simple example of this is in the protein coats that some viruses use for protection outside the cell These are formed of many identical protein subunits that come together to form a regular geometric structure
FIGURE 7.11 Form of 19 of 20 common amino acids; R is a unique side chain.
O +H3N C R H
O −
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7.2.3.2 Nucleic Acids
Nucleic acids are polymers formed of nucleotides Nucleotides are formed of bases joined to a sugar residue that has a phosphate group attached The two nucleic acids commonly found in living organisms are DNA and RNA The component parts of these are:
• Bases: uracil (U), cytosine (C), thymine (T), adenine (A), and guanine (G), Uracil is found in DNA but is replaced by thymine in RNA
• Sugar: ribose or deoxyribose
The different bases are termed purines or pyramidines, depending on their structure (see Figure 7.12); ribose and deoxyribose differ by the presence or absence of an oxygen atom (see Figure 7.13) The assembly of the whole into a
FIGURE 7.12 The five bases: (a) uracil, (b) cytosine, (c) thymine, (d) adenine, (e) guanine. Molecular Mass
The molecular weights of proteins and other macromolecules, such as nucleic
acids, are usually given in daltons (Da) A Dalton is 1/12 the mass of a 12C atom Proteins have molecular weights ranging from about 5,000 to over 1,000,000 Da
FIGURE 7.13 (a) β -D-Ribofuranose, (b) β -D-2-deoxyibofuranose.
O H
O N
N
H
O H
NH2 N
H
O N
N
N
NH2 N
H N N
N
O N
H N N
H2N H
(d)
(c)
(e)
HOCH2O
OH HO
OH HOCH2O
HO OH
Trang 8chain via phosphate residues (PO43 −) is illustrated in Figure 7.14 Note that in these figures, carbon and hydrogen atoms have been left out for clarity If bonds have been shown without atoms being labeled, it is assumed to be a carbon atom with the appropriate number of hydrogen atoms Additionally, the term “base” is also used ambiguously when referring to the complete base–sugar structure in the DNA or RNA molecule itself
In the cell, information is stored in the DNA, which is chemically more stable than RNA The key to information storage in DNA is that each purine base forms hydrogen bonds with a particular pyramidine base: cytosine pairs with guanine and uracil (or thymine) pairs with adenine (see Figure 7.15) This means that two complementary strands of DNA can bind together, which they do, forming a double-helical structure When the cell divides (to reproduce), one strand goes
to one daughter cell and the other strand goes to the other daughter cell The complementary strands are then rebuilt
FIGURE 7.14 Nucleic acid chain (DNA).
DNA Strand Direction
Single DNA strands have two ends, the 3 end and the 5 end; the terminology arises from the standard nomenclature for the carbon atoms in the sugar ring When synthesizing a long strand of DNA, the 3 (sugar) carbon atom of the next base will attach to the 5 (sugar) carbon atom of the base at the 5 end of the chain In double-stranded DNA, the 5 end of one molecule pairs up with the 5 end of the other
HO
CH2O N O
P O
O−
O−
CH2O N O
P O
O− O
CH2O N O
P O
O−
O
O N N
NH2
NH2
N
N
NH2
O N
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as such, are doubly relevant to this book because the formation of membranes and artificial vesicles (liposomes) are of interest from the point of view of nanotech-nology Other lipids include waxes, sphingolipids, glycolipids, and lipoproteins
7.2.3.3.1 Fats
Fats are formed by the reaction of a carboxylic acid with glycerol (Figure 7.16) Any of the three hydroxyl groups may undergo this reaction, forming a monoglyc-eride (only one), diglycmonoglyc-eride (two), or triglycmonoglyc-eride (all three) The carboxylic
acids that are found to form fats in nature are termed fatty acids.
Fats are further classified as saturated or unsaturated, depending on whether they contain only single carbon–carbon bonds or not
7.2.3.3.2 Phospholipids
Phospholipids are lipids that have one or more phosphate (PO4−) residues The commonest form is the phosphoglyceride (see Figure 7.17) The phospholipids are amphipathic compounds, having a polar head (the phosphate residue) and a non-polar tail As a result, in water, the heads tend to dissolve and the tails to aggregate This gives rise to three basic structures in water (Figure 7.18) The lipid bilayer is the basic form of lipid membrane, with the polar heads facing out toward water and the nonpolar tails in the center This can fold into a spherical liposome, but if there are very few molecules involved, then a micelle will form instead
TABLE 7.4
Codons
Trang 107.3 APPLICATIONS OF MICROENGINEERED
DEVICES IN CHEMISTRY AND BIOCHEMISTRY
The characteristics of microengineered devices and systems, relevant to chemical and biochemical applications, are:
• Small size; this means small volumes (so only small quantities of reagent are required), the ratio of surface area to volume is high, laminar flow in small capillaries may cause problems when mixing, small distances for reagents to diffuse, and low thermal mass (rapid heating and cooling)
• Reproducible dimensions and mass production This raises the possi-bility of disposable devices
• Massively parallel systems are possible
• On-chip processing of data
Of course, these are not necessarily advantages A high surface-area-to-volume ratio can be advantageous if part of the process involves molecules becoming attached to the walls of the device but can be a disadvantage if a channel has to be flushed clean during the process
The following subsections summarize some of the general procedures involved in chemistry and biochemistry that may be helped by miniaturization
FIGURE 7.20 Glucose: (a) straight chain, (b) cyclic.
FIGURE 7.21 Part of a cellulose chain.
H
H2OHC
OH OH H OH
HOCH2 H H
H
H H OH
OH HO
HO
C C
C O
HOCH2 OH OH HOCH2
OH OH
HOCH2 OH OH
HOCH2 OH OH
O
O
O
O
O
O
O
O