Sulfanilamides

In spite of the rationale on which the testing of dyestuffs as antibiotics rested subsequent research re vealed that the antibacterial properties of Prontosil had nothing at all to do with its being a dye In the body Prontosil undergoes a reductive cleavage of its azo linkage to form sulfanilamide which is the sub stance actually responsible for the observed biological activity This is why Prontosil is active in vivo but not in vitro... 

Bacteria require p-aminobenzoic acid to biosyn thesize folic acid a growth factor Structurally sul fanilamide resembles p-aminobenzoic acid and is mistaken for it by the bacteria Folic acid biosynthesis IS inhibited and bacterial growth is slowed suffi ciently to allow the body s natural defenses to effect a cure Because animals do not biosynthesize folic acid but obtain it in their food sulfanilamide halts the growth of bacteria without harm to the host... 

Many pharmaceutical compounds are weak acids or bases that can be analyzed by an aqueous or nonaqueous acid-base titration examples include salicylic acid, phenobarbital, caffeine, and sulfanilamide. Amino acids and proteins can be analyzed in glacial acetic acid, using HCIO4 as the titrant. For example, a procedure for determining the amount of nutritionally available protein has been developed that is based on an acid-base titration of lysine residues. ... 

The purity of a pharmaceutical preparation of sulfanilamide, C6H4N2O2S, can be determined by oxidizing the sulfur to SO2 and bubbling the SO2 through H2O2 to produce H2SO4. The acid is then titrated with a standard solution of NaOH to the bromothymol blue end point, where both of sulfuric acid s acidic protons have been neutralized. Calculate the purity of the preparation, given that a 0.5136-g sample required 48.13 mL of 0.1251 M NaOH. 

Since ah the sulfur in H2SO4 comes from sulfanilamide, we use a conservation of mass on sulfur to establish the following stoichiometric relationship. 

Making appropriate substitutions for the moles of sulfanilamide and moles of NaOH gives... 

Let s use a simple example to develop the rationale behind a one-way ANOVA calculation. The data in Table 14.7 show the results obtained by several analysts in determining the purity of a single pharmaceutical preparation of sulfanilamide. Each column in this table lists the results obtained by an individual analyst. For convenience, entries in the table are represented by the symbol where i identifies the analyst and j indicates the replicate number thus 3 5 is the fifth replicate for the third analyst (and is equal to 94.24%). The variability in the results shown in Table 14.7 arises from two sources indeterminate errors associated with the analytical procedure that are experienced equally by all analysts, and systematic or determinate errors introduced by the analysts. 

Results of Four Analysts for the % Purity of a Preparation of Sulfanilamide... 

Table 14.7 shows the results obtained by four analysts determining the purity of a pharmaceutical preparation of sulfanilamide. Determine if the difference in their results is significant at a = 0.05. If such a difference exists, estimate values... 

Sulfonamides derived from sulfanilamide (p-arninoben2enesulfonainide) are commonly referred to as sulfa dmgs. Although several dmg classes are characterized by the presence of a sulfonamide function, eg, hypoglycemics, carbonic anhydrase inhibitors, saluretics, and tubular transport inhibitors, the antibacterial sulfonamides have become classified as the sulfa dmgs. Therapeutically active derivatives are usually substituted on the N nitrogen the position is generally unsubstituted. These features are illustrated by the stmctures of sulfanilamide (1) and sulfadiazine (2)... 

Some related antibacteiials are also included with the sulfonamides. The azo dye, Piontosil (3) is metabolized to sulfanilamide in and was the piogenitoi of the sulfa dmgs. Also, the antibacteiial sulfones, eg, dapsone (4), are believed to act in a similai fashion on enzymes involved with synthesis of fohc acid, leading to bacterial growth inhibition. 

A monograph (1) covers the pioneering period of sulfa dmg development and describes over 5000 sulfanilamide derivatives, their preparation, properties, trade names, and biological testing. This review is remarkably complete through 1944. Several thousand additional derivatives have been made since, but no comparable coverage is available. A definitive account of medical appHcations up to 1960 has been pubHshed (2), and a review of experimental antibacterial aspects has been made (3). Chapters on general aspects of sulfonamides and sulfones have appeared (4,5). A review of the clinical efficacy of trimethoprim—sulfamethoxazole has been pubHshed (6). 

During the most active period of investigation of sulfanilamide derivatives, 1935—1944, for systemic bacterial infections, the antimycobacterial activity of 4,4 -dianainodiphenylsulfone [80-08-8] (DDS, dapsone) was discovered (14). Although neither this compound nor its derivatives proved to be clinically usehil for human tuberculosis, it did evolve into the most important type of compound for leprosy (15). The diacetyl derivative has also... 

N -Heterocyclic Sulfanilamides. The parent sulfanilamide is manufactured by the reaction of A/-acetylsulfanilyl chloride with excess concentrated aqueous ammonia, and hydrolysis of the product. Most heterocycHc amines are less reactive, and the condensation with the sulfonyl chloride is usually done in anhydrous media in the presence of an acid-binding agent. Use of anhydrous conditions avoids hydrolytic destmction of the sulfonyl chloride. The solvent and acid-binding functions are commonly filled by pyridine, or by mixtures of pyridine and acetone. Tertiary amines, such as triethylamine, may be substituted for pyridine. The majority of A/ -heterocycHc sulfanilamides are made by simple condensation with A/-acetylsulfanilyl chloride and hydrolysis. 

In a few cases, A/ -heterocycHc sulfanilamides have been prepared by the condensation of an active heterocycHc haHde with the sulfonamide nitrogen of sulfanilamide or its A/-acetyl derivative in the presence of an acid-binding agent. Sulfapyridine, sulfadiazine, and sulfapyrazine have been made by this method (1), but the most important appHcation is probably for the synthesis of sulfachlorapyridazine (9) and sulfamethoxypyridazine (10) (45). 

Nitrite can be deterrnined by reaction with sulfanilamide to form the diazo compound, which couples with /V-(1-naphthyl)ethylenediamine dihydrochloride to form an intensely colored red azo dye. Nitrate can be deterrnined in a similar manner after reduction to nitrite. Suitable reducing agents are cadmium filings or hydrazine. This method is useful at a nitrogen concentration of 10 -lO " M. 

The most commonly used methods for the preparation of pyridazinesulfonamides are the condensation of aminopyridazines with p-acylaminobenzenesulfonyl chloride and the reaction of halosubstituted pyridazines with sulfanilamide by fusion or in an appropriate solvent. 

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