* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Unit-7-Carboxylic-Acids-Phenols-Amines
Survey
Document related concepts
Transcript
Chem 150 Unit 7 - Organic Molecules II Carboxylic Acids, Phenols & Amines In this unit and the next we look at the chemical and physical properties of a variety of organic families, all of which play important roles in biochemistry. These include the carboxylic acids, phenols, amines and amides. We also look at a new type of stereoisomer that figures predominantly in biological chemistry; the optical isomer. Introduction The organic groups covered in this Unit all have important biological roles • Carboxylic acids • Fatty acids • Amino acids and proteins • Phenols • Colors and flavorings • Amino acids and proteins • Signal molecules • Amines • Amino acids and proteins • Signal molecules • Drugs • Amides • Amino acids and proteins 2 Carboxylic Acids Naming carboxylic acids • The IUPAC ending is -oic acid. 4 Question Give the IUPAC names for the following carboxylic acids: O A) CH3 CH2 CH2 CH2 C O B) HO C CH3 CH2 CH CH3 5 OH CH2 CH CH3 Carboxylic Acids • • 6 Carboxylic acid have high melting points Small carboxylic acids are quite soluble in water Carboxylic Acids Small (volatile) carboxylic acids have noticeable odors. • Ethanoic acid (acetic acid) vinegar O CH3 C • OH Butanoic acid (butyric acid) vomit, dirty socks O CH3 CH2 CH2 C • OH Hexanoic acid (caproic acid) goats, ripe cheese O CH3 CH2 CH2 CH2 CH2 C 7 OH Phenols Simplest phenol is phenol. • A hydroxyl group attached to a benzene ring. OH 8 Phenols All phenols contain hydroxyl groups attached to aromatic rings. 9 Phenols All phenols contain hydroxyl groups attached to aromatic rings. 10 These have 2 hydroxyl groups attached to a benzene ring 11 Carboxylic Acids & Phenols as Weak Acids Both carboxylic acids and phenols are weak acids pKa ≈ 5 O CH3 C OH + acid O CH3 C H2O base O + base H3O+ acid pKa ≈ 10 OH acid 12 + H2O base O base + H3O+ acid Carboxylic Acids & Phenols as Weak Acids The acidity of hydroxyl groups depend on what they are connected to: carboxylic acids phenols alcohols O C O acidic 13 H O weakly acidic H C O H non-acidic Carboxylic Acids & Phenols as Weak Acids • • At pH 7, the carboxylate ion of carboxylic acids predominate At pH 7, the phenol of phenol predominate O CH3 C O OH + acid CH3 C H2O base pKa ≈ 5 OH acid pH = 7 14 + H2O O base pH = 7 base pKa ≈ 10 H3O+ acid O base + + H3O+ acid Carboxylic Acids & Phenols as Weak Acids Strong bases can be used to convert carboxylic acids and phenols to their corresponding carboxylate and phenoxide ions 15 Carboxylic Acids & Phenols as Weak Acids Fatty acids are carboxylate ions at pH 7 • Fatty acids with less that 12 carbons are soluble in water • Fatty acids with greater than 12 carbons are amphipathic, and form micelles when mixed with water. 16 Carboxylic Acids & Phenols as Weak Acids IUPAC names for carboxylate ions: • Remove the “-ic acid” from the corresponding conjugate acids name and replace it with “-ate ion”. 17 Carboxylic Acids & Phenols as Weak Acids Examples: 18 Carboxylic Acids & Phenols, Other Reactions We have already seen how carboxylic acids and carboxylate ions can be made from from the hydrolysis of esters. • Base-catalyzed hydrolysis of esters: • 19 Acid-catalyzed hydrolysis of esters: Carboxylic Acids & Phenols, Other Reactions The acid-catalyzed hydrolysis of esters is reversible and can be used to make esters from carboxylic acids and alcohols: • Synthesis of esters from carboxylic acids and alcohols: 20 Carboxylic Acids & Phenols, Other Reactions A biologically important reaction involving carboxylic acids is the decarboxylation of α-keto and β-keto acids: 21 Carboxylic Acids & Phenols, Other Reactions The decarboxylation of β-keto acids produces ketones The decarboxylation of α-keto acids produces aldehydes 22 Carboxylic Acids & Phenols, Other Reactions The oxidation of hydroquinones is also an important biological reaction. • A chemical oxidation of hydroquinones can be carried out the oxidizing agent K2Cr2O7 (potassium dichromate) 23 Carboxylic Acids & Phenols, Other Reactions Example: • Coenzyme Q and the Electron Transport Chain 24 Carboxylic Acids & Phenols, Other Reactions Example: • Coenzyme Q and the Electron Transport Chain 25 Amines Amines are a nitrogen with one or more carbons attached: • Amines are classified based on the number of carbons that are attached to the nitrogen. • Primary amine (1°): 1 carbons • Secondary amine (2°): 2 carbons • Tertiary amine (3°): 3 carbons N 26 Amines It is possible for a fourth carbon to attach to the nitrogen • The nitrogen will take on a positive charge to become an ion. • Quaternary (4°) ammonium ions: 4 carbon atoms N 27 Amines 28 Amines The IUPAC names for 1°, 2°, and 3° amines. • Create the parent name by picking the longest chain of carbons that is attached to the nitrogen. • Replace the “-e” in the parent with the ending “-amine”. • Number the longest chain from the end that gets you to the the carbon to which the nitrogen is attached in the fewest number of carbons. • Use a numbered prefix to indicate which the carbon in the longest chain the nitrogen is bonded to. • If other substituents are attached to the nitrogen, list them and use the prefix “N-” to indicate that they are attached to the nitrogen. 29 Questions Give the IUPAC names for the following amines: CH3 A) CH3 CH2 CH CH3 CH2 CH NH2 N CH2 CH3 CH3 CH2 CH2 CH3 30 Questions Give the IUPAC names for the following amines: CH3 A) CH3 CH2 CH NH2 2-butanamine 2-butanamine CH3 CH2 CH N CH2 CH3 CH3 CH2 CH2 CH3 N-ethyl-N-propyl-2-butanamine 31 N-ethylN-propyl Amines For heterocyclic amines the nitrogen is part of a ring. • The ring can be either aromatic or not. • The nucleic acid nucleotide bases are good examples of hetoercyclic amines 32 Amines Hydrogen Bonding • 1° and 2° amines can serve as both a hydrogen bond donor and acceptor. • 3° amines can server as a hydrogen bond acceptors, but not donors. 33 Amines Hydrogen Bonding • 4° ammonium ion cannot form hydrogen bonds, but because they are charged, form ionic bonds: CH3 CH3 N CH3 34 CH3 Cl Amines The ability to hydrogen bond give amines moderately high boiling points and high solubilities in water. 35 Amines Another notable property of amines is their odor. • Like carboxylic acids, they can also produce foul odor. • The produce a “fishy” smell. • Examples of amines, whose names imply their odoriferous properties, include H2N putrescine 36 NH2 H2N NH2 cadaverine Amines as Weak Bases In Unit 6, while discussing the definitions of acids and bases, we saw that ammonia, NH3, is operationally a base • That is, when added to water ammonia causes the pH to rise above pH 7. NH3 (aq) • + H2O (l) NH4+ (aq) + Ammonia was the example we used to demonstrate the need for the Brønsted-Lowry definition of acids and bases. See the Unit 6 Elaboration Definitions of Acids and Bases - Part III: Brønsted-Lowry Definition 37 OH- (aq) Amines as Weak Bases Like ammonia, 1°, 2° and 3°, act as Brønsted-Lowry bases. H CH3 N H (aq) H methanamine (base) 38 + H2O (l) CH3 N H (aq) H methylammonium ion (acid) + OH- (aq) Amines as Weak Bases The conjugate acids are called ammonium ions • When placed in water, these ammonium ions will behave like acids. H CH3 N pKa - 10 H (aq) H methylammonium ion (acid) 39 + H2O (l) CH3 N H (aq) H methanamine (base) + H3O+ (aq) Amines as Weak Bases Because it is charged, the conjugate acid is even more soluble that the amine. • Many drugs are amines and are sold the ammonium salts, which are more readily absorbed, due to their increased solubility. • Ephedrine is used as a decongestant. CH3 CH CH OH N + CH3 HCl H CH OH ephedrine 40 CH CH N CH3 Cl- H ephedrine HCl CH3 CH H OH ephedrine 2 CH3 N H CH3 + H2SO4 CH CH3 H CH N OH ephedrine sulfate H CH3 SO422 Amines as Weak Bases Ephedrine is an example of an alkaloid. • Alkaloids are alkaline molecules that are derived from plants. • “alkaline” and another name for basic. • Ephedrine is isolated from the Chinese ma huang plant(Ephedra sinica)hyperlink CH3 CH CH OH ephedrine 41 CH3 N H CH3 CH2 CH N H methamphetamine CH3 Amides • • 42 When a carboxylic acid reacts with an amine it also produces and ammonium salt If the ammonium salt is then heated, an amide is produced. Amides Amides are important in biochemistry. • For example, amino acids are connected together to form proteins using amide groups. amino acid 43 Amides Amides can be hydrolyzed back to carboxylic acids and amines by heating them in the presence of an acid 44 Stereoisomers So far we have encountered two different types of isomers. • Constitutional Isomers • Stereoisomers • cis/trans isomers with alkenes and cycloalkanes, that arise from restricted rotation about bonds. There is one more type of stereoisomer, which is important in biochemistry. • optical isomers 45 Stereoisomers Optical isomers arise when a carbon atom has four different things attached to it. • These carbons are called chiral carbons. • The a molecule containing a chiral carbon is non superimposable on its mirror image. • The molecule and its mirror image are referred to as enantiomers 46 Stereoisomers 47 Stereoisomers 48 Stereoisomers 49 Stereoisomers 50 Stereoisomers 51 Stereoisomers When developing drugs that are chiral, it is important to look at the effects of both the enantiomers. O O H H N O NH O O O N NH O O R-thalidomide S-thalidomide is effective in treating morning sickness in pregnant women is a teratogen, causing birth defects R and S are another way of distinguishing enantiomers; R is the rectus (right) isomer, while S is the sinister (evil) isomer! 52 Stereoisomers When chiral molecules contain more than one chiral carbon, it is possible for two molecules to be stereoisomers without being mirror images. • Such molecules are referred to as diastereomers. CH3 C OH CH H ephedrine 53 CH3 N H C CH3 H CH OH N H pseudoephedrine CH3 Stereoisomers Each chiral carbon that a chiral molecule contains doubles the number of stereoisomers for that molecule. • Ephedrine has two chiral carbons, it therefore has 2 x 2 = 4 stereoisomers. • pseudoephedrine is one of 4 stereoisomers. CH3 C OH CH H ephedrine 54 CH3 N H C CH3 H CH OH N H pseudoephedrine CH3 The End