Lactic anhydride

Lactamide has been prepared by the action of gaseous ammonia on ethyl lactate 3 and from lactic anhydride 4 and gaseous ammonia. It has been made also by the action of ammonia gas on lactide.5 The amide was obtained in excellent yields by treatment of the acetone condensation product of lactic acid with ammonia.6 Amides have been prepared by the reaction of liquid ammonia with esters at temperatures varying from — 330 to... 

Properties Colorless or yellowish syrupy liquid odorless hygroscopic. Bp 122C (15 mm Hg), mp 18C, d 1.2. Miscible with water, alcohol, glycerol, and furfural insoluble in chloroform, petroleum ether, carbon disulfide. Cannot be distilled at atmospheric pressure without decomposition when concentrated above 50% it is partially converted to lactic anhydride. It has one asymmetric carbon and two enantiomorphic isomers. The commercial form is a racemic mixture. 

Many of the physical properties are not affected by the optical composition, with the important exception of the melting poiat of the crystalline acid, which is estimated to be 52.7—52.8°C for either optically pure isomer, whereas the reported melting poiat of the racemic mixture ranges from 17 to 33°C (6). The boiling poiat of anhydrous lactic acid has been reported by several authors it was primarily obtained duriag fractionation of lactic acid from its self-esterification product, the dimer lactoyUactic acid [26811-96-1]. The difference between the boiling poiats of racemic and optically active isomers of lactic acid is probably very small (6). The uv spectra of lactic acid and dilactide [95-96-5] which is the cycHc anhydride from two lactic acid molecules, as expected show no chromophores at wavelengths above 250 nm, and lactic acid and dilactide have extinction coefficients of 28 and 111 at 215 nm and 225 nm, respectively (9,10). The iafrared spectra of lactic acid and its derivatives have been extensively studied and a summary is available (6). 

Substitution at the Alcohol Group. Acylation of the OH group by acylating agents such as acid chlorides or anhydrides is one of the important high yielding substitution reactions at the OH group of lactic acid and its functional derivatives. AUphatic, aromatic, and other substituted derivatives can be produced. 

In order to become useful dmg delivery devices, biodegradable polymers must be formable into desired shapes of appropriate size, have adequate dimensional stability and appropriate strength-loss characteristics, be completely biodegradable, and be sterilizahle (70). The polymers most often studied for biodegradable dmg delivery applications are carboxylic acid derivatives such as polyamides poly(a-hydroxy acids) such as poly(lactic acid) [26100-51-6] and poly(glycolic acid) [26124-68-5], cross-linked polyesters poly(orthoesters) poly anhydrides and poly(alkyl 2-cyanoacrylates). The relative stabiUty of hydrolytically labile linkages ia these polymers (70) is as follows ... 

Bls(Chollne)-Naphthalene-1 JS-Disulfonate Lactic Acid Anhydride Diacetate... 

In the reaction of lactic acid to form pyruvic acid over the iron phosphate catalysts, formation of a new compound was observed. As the extent of reaction increased, the amount of pyruvic acid increased to a maximum and then decreased, while that of the new compound increased steadily. It was therefore concluded that the new compound is formed from pyruvic acid in parallel with acetic acid and CO2. According to gas-mass analyses, the molecular weight was determined as 112. However, there are many compounds with molecular weigth of 112. After the NMR analyses and X-ray diffraction analyses for the single crystal, the new compound was determined to be citraconic anhydride, i.e., mono-methyl maleic anhydride. 

Since formation of citraconic anhydride from pyruvic acid is one of "acid to acid type" transformations, such as reactions from isobutyric acid to methacrylic acid and from lactic acid to pyruvic acid, the required catalysts must be acidic [11). If the catalysts are basic, it may be impossible to obtained acidic products, because basic catalysts activate selectively acidic molecules and, as a result, they show a very high activity for the decomposition of acidic products [11]. 

I. 4-methoxyacetophenone (30 //moles) was added as an internal standard. The reaction was stopped after 2 hours by partitioning the mixture between methylene chloride and saturated sodium bicarbonate solution. The aqueous layer was twice extracted with methylene chloride and the extracts combined. The products were analyzed by GC after acetylation with excess 1 1 acetic anhydride/pyridine for 24 hours at room temperature. The oxidations of anisyl alcohol, in the presence of veratryl alcohol or 1,4-dimethoxybenzene, were performed as indicated in Table III and IV in 6 ml of phosphate buffer (pH 3.0). Other conditions were the same as for the oxidation of veratryl alcohol described above. TDCSPPFeCl remaining after the reaction was estimated from its Soret band absorption before and after the reaction. For the decolorization of Poly B-411 (IV) by TDCSPPFeCl and mCPBA, 25 //moles of mCPBA were added to 25 ml 0.05% Poly B-411 containing 0.01 //moles TDCSPPFeCl, 25 //moles of manganese sulfate and 1.5 mmoles of lactic acid buffered at pH 4.5. The decolorization of Poly B-411 was followed by the decrease in absorption at 596 nm. For the electrochemical decolorization of Poly B-411 in the presence of veratryl alcohol, a two-compartment cell was used. A glassy carbon plate was used as the anode, a platinum plate as the auxiliary electrode, and a silver wire as the reference electrode. The potential was controlled at 0.900 V. Poly B-411 (50 ml, 0.005%) in pH 3 buffer was added to the anode compartment and pH 3 buffer was added to the cathode compartment to the same level. The decolorization of Poly B-411 was followed by the change in absorbance at 596 nm and the simultaneous oxidation of veratryl alcohol was followed at 310 nm. The same electrochemical apparatus was used for the decolorization of Poly B-411 adsorbed onto filter paper. Tetrabutylammonium perchlorate (TBAP) was used as supporting electrolyte when methylene chloride was the solvent. 

Formation of Seeondary Aeida.—By tho action of the pbos-phoras chlorides or of phosphoric anhydride upon the ethereal salts of secondary acids of the lactic scries, the elements of water are removed and the ethereal salts of the acrylic secon> dary division of acids produced —... 

The o-carboxy anhydride of (d,l) lactic acid (4.0 mmol) was dissolved in 1.7 ml CH2CI2 and then treated with 4-dimethylamine pyridine (0.018 mmol) at an [anhydride]/[amine] ratio of 220. The mixture was reacted for 30 minutes at 25 °C and then concentrated. The product was isolated in 98% yield having an Mn of 30,400 Da with a polydispersity of 1.18. Duplicate and triplicate polymerizations were also performed and M s and polydispersities were found to be 30,300 and 34,900 Da with polydispersities of 1.18 and 1.13, respectively. 

In addition to the more or less popular methods of depsipeptide synthesis discussed vide supra, there are also a limited number of complementary and effective synthetic procedures that have been described for this purpose. Among these, the well-known method of symmetric anhydrides from N-protected amino acids has to be considered. This method has found successful use in the esterification of hydroxy acids in the presence of some catalyst additives. Initially, the addition of pyridine11091 or 1-hydroxybenzotriazole in pyridine1 101 to a symmetric anhydride was utilized for ester bond formation. As an example, Katakai has prepared a number of didepsipeptides in 85-96% yield by means of a 2-nitrophenylsulfenyl /V-carboxy anhydride with lactic acid derivatives in the presence of pyridine.1 09 ... 

Bis(choline)-naphthalene-1,5-disulfonate Lactic acid anhydride diacetate... 

As pointed out by Heller (2), polymer erosion can be controlled by the following three types of mechanisms (1) water-soluble polymers insolubilized by hydrolytically unstable cross-links (2) water-insoluble polymers solubilized by hydrolysis, ionization, or protonation of pendant groups (3) hydrophobic polymers solubilized by backbone cleavage to small water soluble molecules. These mechanisms represent extreme cases the actual erosion may occur by a combination of mechanisms. In addition to poly (lactic acid), poly (glycolic acid), and lactic/glycolic acid copolymers, other commonly used bioerodible/biodegradable polymers include polyorthoesters, polycaprolactone, polyaminoacids, polyanhydrides, and half esters of methyl vinyl ether-maleic anhydride copolymers (3). 

Reactions of 3-substituted 2-(lV-phenylaminomethyl)piperazines with a slight excess of ethyl 2-chloroacetate under reflux afforded mixtures of 9-substituted 2-phenylperhydropyrido[l,2-a]pyrazin-3- and -4-ones, which could be separated by column chromatography [72JCS(P2)1374], When 2-[(3-trifluoromethylphenyl)aminomethyl]piperidine was heated with optically active ethyl 2-chloropropionate (87MIP1 91TA231), or lactic acid ethyl ester methanesulphonate (91TA231), the product was a C-9a epimeric mixture of 2-(3-trifluoromethylphenyl)-4-methylperhydropyrido[l,2-fl]-pyrazin-3-ones. The reaction between yV-methyl-2-piperidine-carboxamide and hydroxymaleic anhydride in pyridine resulted in 2,3-dimethyl-3-hydroxyperhydropyrido[l,2-a]pyrazine-l,4-dione (74CB2804). 

The study by Determan et al. [224] focuses on the effects of polymer degradation products on the primary, secondary, and tertiary structure of TT, OVA, and lysozyme after incubation for 0 or 20 days in the presence of ester (lactic acid and glycolic acid) and anhydride [sebacic acid and l,6-bis(p-carboxyphenoxy)hexane] monomers. The structure and antigenicity or enzymatic activity of each protein in the presence of each monomer was quantified. SDS-PAGE, circular dichroism, and fluorescence spectroscopy were used to assess/evaluate the primary, secondary, and tertiary structures of the proteins, respectively. ELISA was used to measure changes in the antigenicity of TT and OVA and a fluorescence-based assay was used to determine the enzymatic activity of lysozyme. TT toxoid was found to be the most stable in the presence of anhydride monomers, while OVA was most stable in the... 

Polyanhydride Nanoparticles Polyanhydrides have been more commonly used to prepare microparticles than nanoparticles. However, the technology is adaptable for nanoparticles. The transfection efficiency of firefly luciferase DNA was enhanced when delivered in nanoparticles prepared from polyanhydride-lactic acid blends, demonstrating the potential application in gene delivery [120], The degradation and elimination of polyanhydrides have been reviewed [97], In vivo, the anhydride bond degrades to form diacid monomers that are eliminated from the body. 

By bacterial fermentation the calcium salt of lactic acid is decomposed into salts of simpler acids, e.g,y propionic, bulyric and valeric. As an acid lactic acid yields an ethyl ester with ethyl alcohol and as an alcohol it yields, with acetic anhydride, an acetyl derivative. The latter compound results from the putrefaction of muscular tissue, as this contains both lactic and acetic acid. 

Levo Lactic Acid.— Levo lactic acid was first obtained by the fermentation of cane sugar by specific bacteria. It is levo rotatory but, like the dextro acid, the rotation of its salts and its anhydride is reversed, being dextro rotatory. The levo lactic acid and also the dextro acid may be obtained by splitting the inactive acid into its optical components by means of its strychnine salt. 

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