China Largest Manufacturer factory sales Vancomycin CAS 1404-90-6 CAS NO.1404-90-6

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Vancomycin Basic information Overview Indication and Administration Pharmacodynamic Brand Name(s) in US Mode of action Resistance issue Side effects References Product Name: Vancomycin Synonyms: Vancomycin (base and/or unspecified salts);VANCOMYCIN;Vancomycin Base;(3S,6R,7R,22R,23S,26S,36R,38aR)-3-(2-Amino-2-oxoethyl)-44-[[2-O-(3-amino-2,3,6-trideoxy-3-C-methyl-α-L-lyxo-hexopyranosyl)-β-D-glucopyranosyl]oxy]-10,19-dichloro-2,3,4,5,6,7,23,24,25,26,36,37,38,38a-tetradecahydro-7,22,28,30,32-pentahydroxy-6-[[(2R)-4-methyl-2-(methylamino)-1-oxopentyl]amino]-2,5,24,38,39-pentaoxo-22H-8,11:18,21-Dietheno-23,36-(iminomethano)-13,16:31,35-dimetheno-1H,16H-[1,6,9]oxadiazacyclohexadecino[4,5-m][10,2,16]benzoxadiazacyclotetracosine-26-carboxylic acid;Vancomycin USP/EP/BP;demethylvancomycin USP/EP/BP;Vancomycin,USP，≥950μg/mg;vancomycin hcl vancocin CAS: 1404-90-6 MF: C66H75Cl2N9O24 MW: 1449.25 EINECS: 215-772-6 Product Categories:   Mol File: 1404-90-6.mol   Vancomycin Chemical Properties Melting point  >274°C (dec.) density  1.2882 (rough estimate) refractive index  1.7350 (estimate) storage temp.  2-8°C solubility  DMSO (Slightly) pka pKa 2.18±0.08(H2O t = 25.0±0.1 I = 0.2 (NaCl) N2 atmosphere) (Uncertain);7.75±0.02(H2O t = 25.0±0.1 I = 0.2 (NaCl) N2 atmosphere) (Uncertain);8.89±0.01(H2O t = 25.0±0.1 I = 0.2 (NaCl) N2 atmosphere) (Uncertain) form  Solid color  Off-White Stability: Hygroscopic CAS DataBase Reference 1404-90-6(CAS DataBase Reference)   Safety Information Hazardous Substances Data 1404-90-6(Hazardous Substances Data) MSDS Information   Vancomycin Usage And Synthesis Overview Vancomycin is a complex tricyclic glycopeptide antibiotic produced by Streptococcus orientalis[1, 2]. Vancomycin was first discovered from a soil sample in the interior jungle of Borneo in the 1950s, and its usage was very limited due to the presence of impurities that caused toxicities in the earlier preparations. However, the use of vancomycin was reconsidered after the emergence of methicillin-resistant Staphylococci in the 1970s, and its usage increased from the 1980s after purer preparations were made in late 1970s[3]. Now, vancomycin has become the most common injectable drug of choice to treat methicillin-resistant Staphylococci species and drug resistant Enterococcus species[4]. Figure 1 The chemical structure of vancomycin VCM is generally prescribed to combat severe infections caused by Gram-positive bacteria, to fight microorganisms that are resistant to other antimicrobial agents or still indicated to patients who are allergic to penicillins and cephalosporins[1, 5]. As a consequence, it is very much used in intensive care units (ICU) for the treatment of not only hospital infections and sepsis, but also of pneumonia cases, empyema, endocarditis, osteomyelitis, soft tissue abscesses among others[1, 6, 7]. This drug is not the first-choice agent owing to its adverse effects like hypotension and tachycardia, phlebitis, nephrotoxicity, ototoxicity[7], hypersensibility reactions, chills, exanthema and fever1, and the fact that peripheral IV complications are a major concern[8]. The literature reveals that the use of inappropriate doses and prolonged therapyes increase the risk of toxicity that, in turn, favors the onset of adverse effects[9-11]. Therefore, the people who use antibiotics in animals and humans must be vigilant about the adverse. Therefore, the people who use antibiotics in animals and humans must be vigilant about the adverse effects and the proper doses—especially in case of last-line antibiotics such as vancomycin. 3 doses; however, higher doses may be prescribed1. Although the established pediatric doses vary according to the age range described below[1, 3], no consensus has been reached regarding the adequate dose of vancomycin for children. Indication and Administration Vancomycin is active against most strains of Clostridia, resistant strains), coagulase-negative Staphylococci, and Viridans group Staphylococci and Enterococci. Vancomycin is not effective against Gram-negative bacteria[12]. Vancomycin is one of the antibiotics of last resort, used only after treatment with other antibiotics has failed in the treatment of life-threatening infections by Gram-positive bacteria. Even though vancomycin has great potential in treating infections in animals, the use of vancomycin in veterinary medicine is limited because it is expensive and requires continuous intravenous infusion[13]. Powdered vancomycin is reconstituted in sterile water, which results in a dark-colored solution, and it is further diluted in 5% dextrose or saline when it is administered. The reconstituted solution is stable for 14 days either at room temperature or in a refrigerator. Additionally, 125 mg and 250 mg vancomycin tablets are available for oral administration[14].  Pharmacodynamic The factors that affect the activity of vancomycin are its tissue distribution, its protein-binding, inoculum size, and resistant organisms. The volume of distribution in humans is 0.4–1 L/kg; in dogs, 0.4–5.5 L/kg[15]. The binding of vancomycin to protein has a range from 10% to 50%. A 1–8-fold increase in the minimum inhibitory concentration (MIC) has been shown in several in vitro assessments as a result of the presence of albumin, whereas the presence of serum has had a more variable effect[16]. It is evident in an in vitro pharmacodynamic model that the time taken to kill is longer when the inoculum size is high (9.5 log10 CFU/g) compared to a moderate inoculum (5.5 log10 CFU/g): 48 versus 72 h, respectively, for both the methicillin sensitive Staphylococci and methicillin-resistant Staphylococci organisms isolated from human patients[16,17]. Vancomycin penetrates into most body spaces, and the penetrability is dependent on the degree of inflammation present. The concentration of vancomycin in different body spaces is different[18]. The inflamed meninges improve the penetration of vancomycin into the cerebral spinal fluid, with reported concentrations of 6.4–11.1 mg/L, whereas uninflamed meninges have resulted in low concentrations of 0–3.45 mg/L in humans[19]. Furthermore, it has been shown in a rabbit model that a high concentration of vancomycin is present in the cerebral spinal fluid of inflamed meninges[20]. Therapeutic concentrations of vancomycin in ascitic, pericardial, pleural, and synovial fluids are greater than 2.5 mg/L in humans[21]. More than 80% and 50% of a vancomycin dose is excreted unchanged in the urine (mostly by way of glomerular filtration) within 24 h after administration in humans and dogs, respectively, and the concentration of vancomycin in liver tissue and bile is below detectable levels. Vancomycin has a distribution phase of 30 min to 1 h. The half-life of vancomycin in patients with normal creatinine clearance in humans is about 6 h; dogs, 2 h; horses, 3 h[22]. Brand Name(s) in US Vancocin, Vancoled Mode of action The mechanism of action of this antimicrobial agent is via the inhibition of bacterial cell wall biosynthesis or, more specifically, the inhibition of peptidoglycan biosynthesis. It is, therefore, bactericidal for reproductive bacteria[1]. The bacterial cell wall contains peptidoglycan that encircles the whole bacteria. In Gram-positive bacteria this substance is more significantly present, and it forms large and insoluble layers on the outer part of the cell membrane, totaling up to 40 layers which consist of multiple skeletons of amino sugars: N-acetylglucosamine and N-acetylmuramic[24]. The latter contains lateral short peptide residues with cross-links, which form a high-level resistant polymeric chain. The drug inhibits this polymerization or the transglycosylase reaction once it binds with high affinity to the C-terminal D-alanyl D-alanine residues of lipid-linked cell wall precursors and blocks the linkage to the glycopeptide polymer1. As a result, it hinders the cross-links of peptides from binding to tetrapeptide side chains; namely, it prevents its linkage to the growing tip of the peptidoglycan[24]. Resistance issue Antibiotic use either as therapy, in the prevention of bacterial diseases, or as performance enhancers has resulted in antibiotic-resistant microorganisms in pathogens and among bacteria of the endogenous microflora of animals. Antibiotic-resistant bacteria present in animals can be transmitted to humans via contact or via the food chain. Furthermore, resistance genes of animal bacteria can be transferred to human pathogens in the intestinal flora of humans. The development of intermediate and high levels of resistance to vancomycin for Staphylococcus aureus was reported for the first time in Japan in 1997[25]. According to guidelines of the Clinical Laboratory Standards Institute, susceptibility break points of vancomycin are <4 mcg/mL for Enterococcus, <1 mcg/mL for Streptococcus, and <4 mcg/mL for Staphylococcus. However, in 2006, the vancomycin MIC breakpoints for S. aureus were lowered to 2 ug/mL for “susceptible”, 4–8 ug/mL for “intermediate”, and 16 ug/mL for “resistant”[26]. Enterococci should be regularly tested in vitro for susceptibility to vancomycin for determination of MIC. Enterococci are deemed susceptible to vancomycin if MICs are <4 ug/mL; they are considered as intermediate level resistance to vancomycin if MICs are 8 to 16 ug/mL; and as complete resistance to vancomycin if MICs are >16 ug/mL. Side effects Prolonged intravenous use of vancomycin may cause neutropenia, thrombophlebitis, rash, fever, anemia, thrombocytopenia, and ototoxic reactions in humans and animals. Vancomycin should be administered intravenously in diluted form, because it is highly irritable for the tissues. It may cause local phlebitis at the site of injection in animals[14]. Vancomycin should be infused for over 1h to reduce the risk of the histamine release-associated “red man” syndrome in humans. It is advised not to administer intravenous rapidly, so as to avoid acute adverse reaction in animals[4]. The major drawback of vancomycin usage is auditory damage in humans; however, tinnitus and deafness might improve once the treatment is ceased. In addition to that, nausea, chills, phlebitis, severe hypotension, wheezing, dyspnoea, urticaria, and pruritus have been observed with the treatment of vancomycin in humans[27–30]. In some instances, neutropenia was detected with prolonged therapy[31]. There is a potential for nephrotoxicity and ototoxicity with vancomycin in animals[32]. Toxicities are minimal in vancomycin monotherapy at conventional dosages of 1 g (15 mg/kg) every 12 h in humans[33]. However, increased incidence of nephrotoxicity has been established with doses of 4 g/day or higher. As a result of elevated dosage, serum concentrations may increase, which may lead to toxicity[34]. Vancomycin increases the risk of nephrotoxicity in humans with drugs such as amphotericin, capreomycin, cyclosporine, cisplatin, colistimethate, polymyxins, and tacrolimus. References GUPTA A, BIYANI M, KHAIRA A. Vancomycin nephrotoxicity: myths and facts. Neth J Med 2011; 69: 379-383. DEHORITY W. Use of vancomycin in pediatrics. Pediatr Infect Dis J 2010; 29: 462-464. Moellering, R.C., Jr. Vancomycin: A 50-year reassessment. Clin. Infect. Dis. 2006, 42, S3–S4. Mark, G.P. Saunders Handbook of Veterinary Drugs Small and Large Animal, 3rd ed.; Saunders: Philadelphia, PA, USA, 2011. HICKS RW, HERNANDEZ J. Perioperative pharmacology: a focus on vancomycin. AORN J 2011; 93: 593-599. PLAN O, CAMBONIE G, BARBOTTE E, MEYER P, DEVINE C, MILESI C, PIDOUX O, BADR O, PICAUD JC. Arch Dis Child Fetal Neonatal 2008; 93: 418-421. BADRAN EF, SHAMAYLEH A, IRSHAID YM. Int J Clin Pharmacol Ther 2011; 49: 252-257. ROSZELL S, JONES C. J Infusion Nurs 2010; 33: 112-118. NUNN MO, CORALLO CE, AUBRON C, POOLE S, DOOLEY MJ, CHENG AC. Ann Pharmacother 2011; 45: 757-763. PRITCHARD L, BAKER C, LEGGETT J, SEHDEV P, BROWN A, BAYLEY BK. Am J Med 2010; 123: 1143-1149. KHOTAEI GT, JAM S, SEYED AS, MOTAMED F, NEJAT F, TAGHI M, ASHTIANI H, IZADYAR M. Acta Med Iran 2010; 48: 91-94. Bennett, P.N.; Brown, M.J. Vancomycin, Clinical Pharmacology, 9th ed.; Churchill Livingstone: London, UK, 2000. John, F.P.; Baggot, J.D.; Walker, R.D. Glycopeptides: Vancomycin, Teicoplanin, and Avoparcin, Antimicrobial Therapy in Veterinary Medicine, 3rd ed.; Blackwell Publishing Professional: Ames, IA, USA, 2000. Levison, M.E.; Levison, J.H. Infect. Dis. Clin. N. Am. 2009, 23, 791–815. Cantu, T.G.; Dick, J.D.; Elliott, D.E.; Humphrey, R.L.; Kornhauser, D.M. Protein binding of vancomycin in a patient with immunoglobulin A myeloma. Antimicrob. Agents Chemother. 1990, 34, 1459–1461. Micek, S.T. Clin. Infect. Dis. 2007, 45, S184–S190. Koteva, K.; Hong, H.L.; Wang, X.D.; Nazi, I.; Hughes, D.; Naldrett, M.J.; Buttner, M.J.; Wright, G.D. A. Nat. Chem. Biol. 2010, 6, 327–329. Albanese, J.; Leone, M.; Bruguerolle, B.; Ayem, M.L.; Lacarelle, B.; Martin, C. Antimicrob. Agents Chemother. 2000, 44, 1356–1358. Nau, R.; Sörgel, F.; Eiffert, H. Clin. Microbiol. Rev. 2010, 23, 858–883. Matzneller, P.; Burian, A.; Zeitlinger, M.; Sauermann, R. Pharmacology 2016, 97, 233–244. Forouzesh, A.; Moise, P.A.; Sakoulas, G. Vancomycin ototoxicity: A reevaluation in an era of increasing doses. Antimicrob. Agents Chemother. 2009, 53, 2483–2486. CHAMBERS HF. Antimicrobial agents: Protein Synthesis Inhibitors and miscellaneous antibacterial agents. In: Goodman and Gilman's the pharmacological basis of therapeutics 11th edition. Edited by Joel G. Hardman, Lee E. Limbird. New York, McGraw-Hill, 2010; pp. 1074-1077. Chen, C.Y.; Huang, Y.C. Review: New epidemiology of Staphylococcus aureus infection in Asia. Clin. Microbiol. Infect. 2014, 20, 605–623. Tenover, F.C., Jr.; Moellering, R.C. Clin. Infect. Dis. 2007, 44, 1208–1215. Brummett, R.E.; Fox, K.E. Antimicrob. Agents Chemother. 1989, 33, 791–796. Elting, L.S.; Rubenstein, E.B.; Kurtin, D.; Rolston, K.V.; Fangtang, J.; Martin, C.G.; Raad, I.I.; Whimbey, E.E.; Manzullo, E.; Bodey, G.P. Mississippi mud in the 1990s: Risks and outcomes of vancomycin-associated toxicity in general oncology practice. Cancer 1998, 83, 2597–2607. Stanley, D.; McGrath, B.J.; Lamp, K.C.; Rybak, M.J. Pharmacotherapy 1994, 14, 35–39. Tange, R.A.; Kieviet, H.L.; Marle, J.V.; Sjoback, D.B.; Ring,W. An experimental study of vancomycin-induced cochlear damage. Arch. Otorhinolaryngol. 1989, 246, 67–70. Pai, M.P.; Mercier, R.C.; Koster, S.A. Epidemiology of vancomycin-induced neutropenia in patients receiving home intravenous infusion therapy. Ann. Pharmacother. 2006, 40, 224–228. Bishop, T. Vancomycin. In The Veterinary Formulary, 6th ed.; Pharmaceutical Press: London, UK, 2005. Ray, A.S.; Haikal, A.; Hammoud, K.A.; Yu, S.L. Vancomycin and the Risk of AKI: A Systematic Review and Meta-Analysis. CJASN 2016, 11, 2132–2140. Bailie, G.R.; Neal, D. Vancomycin ototoxicity and nephrotoxicity. Med. Toxicol. Advers. Drug Exp. 1988, 3, 376–386. Description Vancomycin is produced by fermentation of Amycol atopsis orientalis (formerly Nocardi a orientalis). It has been available for approximately 40 years, but its popularity has increased significantly with the emergence of MRSA in the early 1980s. Chemically, vancomycin has a glycosy lated hexapeptide chain that is rich in unusual amino acids, many of which contain aromatic rings cross-linked by aryl ether bonds into a rigid molecular framework. Originator Vancocin,Lilly,US,1958 Uses Antibacterial. Uses Vancomycin is used for serious bacterial infections caused by microorganisms sensitive to this drug when penicillins and cephalosporins are ineffective for diseases such as sepsis, endocarditis, pneumonia, pulmonary abscess, osteomyelitis, meningitis, and enterocolitis, or when penicillins and cephalosporins cannot be tolerated by patients. Vancomycin is the drug of choice for infections caused by methicillin-resistant forms of S. aureus, S. epidermidus, and other coagulase-negative staphylococci, as well as for endocarditis, diphtherioid infections, and for patients very sick with colitis caused by C. difficile. A synonym of this drug is vancocin. Definition ChEBI: A complex glycopeptide from Streptomyces orientalis. It inhibits a specific step in the synthesis of the peptidoglycan layer in the Gram-positive bacteria Staphylococcus aureus and Clostridium difficile. Manufacturing Process An agar slant is prepared containing the following ingredients: 20 grams starch, 1 gram asparagine, 3 grams beef extract, 20 grams agar, and 1 liter water. The slant is inoculated with spores of S. orientalis, Strain M43-05865, and is incubated for about 10 days at 30°C. The medium is then covered with sterile distilled water and scraped to loosen the spores. The resulting suspension of spores is preserved for further use in the process. A liquid nutrient culture medium is prepared containing the following ingredients: 15 grams glucose, 15 grams soybean meal, 5 grams corn steep solids, 2 grams sodium chloride, 2 grams calcium carbonate, and 1 liter water. The medium is sterilized at 120°C for about 30 minutes in a suitable flask and cooled. 10 ml of a spore suspension prepared as set forth above are used to inoculate the medium. The inoculated medium is shaken for 48 hours at 26°C on a reciprocating shaker having a 2-inch stroke, at 110 rpm. The fermented culture medium which comprises a vegetative inoculum is used to inoculate a nutrient culture medium containing the following ingredients: 20 grams blackstrap molasses, 5 grams soybean peptone, 10 grams glucose, 20 grams sucrose, 2.5 grams calcium carbonate, and 1 liter water. The medium is placed in a container having a suitable excess capacity in order to insure the presence of sufficient oxygen and is sterilized by heating at 120°C for about 30 minutes. When cool, the medium is inoculated with about 25 ml of a vegetative inoculum as described above, and the culture is then shaken for about 80 hours at 26°C. The pH of the medium at the beginning of fermentation ranges from about 6.5 to about 7.0 and the final pH is about 7.0 to about 8.0. A fermentation broth thus obtained contained about 180 μg of vancomycin per ml. Brand name Vancocin Hydrochloride (ViroPharma); Vancoled (Baxter Healthcare); Vancor (Pharmacia & Upjohn). Therapeutic Function Antibacterial Acquired resistance Only very recently, despite decades of intensive use, have some vancomycin-resistant bacteria emerged (vancomycin-resistant enterococcus [VRE] and vancomycin-resistant Staphylococcus aureus) [VRSA]. It is alleged that these resistant strains emerged as a consequence of the agricultural use of avoparcin, a structurally related antibiotic that has not found use for human infections in the United States but was used in Europe before its recent ban. The mechanism of resistance appears to be alteration of the target D-alanyl-D-alanine units on the peptidoglycan cell wall precursors to D-alanyl-D-lactate. This results in lowered affinity for vancomycin due to lack of a key hydrogen bonding interaction. It is greatly feared that this form of resistance will become common in the bacteria for which vancomycin is presently the last sure hope for successful chemotherapy. If so, such infection would become untreatable. These resistant strains are not yet common in clinically relevant strains, but most authorities believe that this is only a question of time. Vancomycin-intermediate S.aureus, also called glycoprotein-intermediate S.aureus (VISA), also has been reported. It appears to be resistant because of a thickened peptidoglycan layer. Mechanism of action Vancomycin is a bacterial cell wall biosynthesis inhibitor. Evidence suggests that the active species is a homodimer of two vancomycin units. The binding site for its target is a peptide-lined cleft having high affinity for acetyl-D-alanyl-D-alanine and related peptides through five hydrogen bonds. It inhibits both transglycosylases (inhibiting the linking between muramic acid and acetyl glucosamine units) and transpeptidase (inhibiting peptide cross-linking) activities in cell wall biosynthesis. Thus, vancomycin functions like a peptide receptor and interrupts bacterial cell wall biosynthesis at the same step as the β-lactams do, but by a different mechanism. By covering the substrate for cell wall transamidase, it prevents cross-linking resulting in osmotically defective cell walls. Clinical Use Although a number of adverse effects can result from IV infusion, vancomycin has negligible oral activity. It can be used orally for action in the GI tract, especially in cases of Cl ostri di um difficile overgrowth. The useful spectrum is restricted to Gram-positive pathogens, with particular utility against multiply-resistant, coagulase-negative staphylococci and MRSA, which causes septicemias, endocarditis, skin and soft-tissue infections, and infections associated with venous catheters. Clinical Use Vancomycin was discovered, developed, and approved by the US Food and Drug Administration in the 1950s. In 1956, it was introduced in the USA as a possible treatment for infections due to penicillinresistant S. aureus, but it was not used widely because of toxicity and the nearly simultaneous development of semisynthetic antibiotics and cephalosporins. Thus, its main indication was the treatment of serious Gram-positive infections in penicillin-allergic patients. In clinical practice, however, nafcillin remained the treatment of choice for staphylococcal bacteremia, largely because it had failure rates of only 4%. With the appearance of methicillin-resistant S. aureus and coagulase-negative staphylococci, vancomycin became the drug of choice for these infections. With the recognition and/or emergence of S. aureus strains (generally MRSA isolates) with reduced susceptibility to vancomycin 586 Glycopeptides and Lipopeptides, vancomycin efficacy may be less in some clinical situations than previously reported – especially in serious deep-seated infections, such as endocarditis and prosthetic device infections. This is demonstrated by increased mortality seen in patients with MRSA infection and markedly attenuated vancomycin efficacy caused by vancomycin heteroresistance in S. aureus. Resistance of S. aureus to vancomycin can be a continuous phenomenon, rather than a categorical one. Thus, this has resulted in some clinical microbiology laboratories having difficulty identifying S. aureus strains that have reduced vancomycin susceptibility based on standard laboratory susceptibility testing methodology. A better understanding is still needed of the pharmacodynamic relationship between vancomycin and MRSA as relates to optimal dosing strategies, including consideration of loading doses.  Clinical Use Vancomycin was discovered, developed, and approved by the US Food and Drug Administration in the 1950s. In 1956, it was introduced in the USA as a possible treatment for infections due to penicillinresistant S. aureus, but it was not used widely because of toxicity and the nearly simultaneous development of semisynthetic antibiotics and cephalosporins. Thus, its main indication was the treatment of serious Gram-positive infections in penicillin-allergic patients. In clinical practice, however, nafcillin remained the treatment of choice for staphylococcal bacteremia, largely because it had failure rates of only 4%. With the appearance of methicillin-resistant S. aureus and coagulase-negative staphylococci, vancomycin became the drug of choice for these infections. With the recognition and/or emergence of S. aureus strains (generally MRSA isolates) with reduced susceptibility to vancomycin 586 Glycopeptides and Lipopeptides, vancomycin efficacy may be less in some clinical situations than previously reported – especially in serious deep-seated infections, such as endocarditis and prosthetic device infections. This is demonstrated by increased mortality seen in patients with MRSA infection and markedly attenuated vancomycin efficacy caused by vancomycin heteroresistance in S. aureus. Resistance of S. aureus to vancomycin can be a continuous phenomenon, rather than a categorical one. Thus, this has resulted in some clinical microbiology laboratories having difficulty identifying S. aureus strains that have reduced vancomycin susceptibility based on standard laboratory susceptibility testing methodology. A better understanding is still needed of the pharmacodynamic relationship between vancomycin and MRSA as relates to optimal dosing strategies, including consideration of loading doses.  Side effects Vancomycin is highly associated with adverse infusion-related events. These are especially prevalent with higher doses and a rapid infusion rate. A rapid infusion rate has been shown to cause anaphylactoid reactions, including hypotension, wheezing, dyspnea, urticaria, and pruritus. A significant drug rash (the so-called red man syndrome) also can occur. These events are much less frequent with a slower infusion rate. In addition to the danger of infusion-related events, higher doses of vancomycin can cause nephrotoxicity and auditory nerve damage. The risk of these effects is increased with elevated, prolonged concentrations, so vancomycin use should be monitored, especially in patients with decreased renal function. The ototoxicity may be transient or permanent and more commonly occurs in patients receiving high doses, patients with underlying hearing loss, and patients being treated concomitantly with other ototoxic agents (i.e., aminoglycosides). Drug interactions Potentially hazardous interactions with other drugs Antibacterials: increased risk of nephrotoxicity and ototoxicity with aminoglycosides, capreomycin or colismethate sodium; increased risk of nephrotoxicity with polymyxins. Ciclosporin: variable response; increased risk of nephrotoxicity. Diuretics: increased risk of ototoxicity with loop diuretics. Muscle relaxants: enhanced effects of suxamethonium. Tacrolimus: possible increased risk of nephrotoxicity Metabolism Little or no metabolism of vancomycin is thought to take place. It is excreted unchanged by the kidneys, mostly by glomerular filtration. There is a small amount of nonrenal clearance, although the mechanism for this has not been determined.   Vancomycin Preparation Products And Raw materials Raw materials Vancomycin, 28,30,32-tri-O-2-propenyl-N3'',56-bis[(2-propenyloxy)carbonyl]-, 2-propenyl ester-->DesvancosaMinyl VancoMycin Preparation Products AC-LYS(AC)-D-ALA-D-ALA-OH

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Leader Biochemical Group is a large leader incorporated industry manufacturers and suppliers of advanced refined raw materials From the year of 1996 when our factory was put into production to year of 2020, our group has successively invested in more than 52 factories with shares and subordinates.We focus on manufacture Pharm & chemicals, functional active ingredients, nutritional Ingredients, health care products, cosmetics, pharmaceutical and refined feed, oil, natural plant ingredients industries to provide top quality of GMP standards products.All the invested factories' product lines cover API and intermediates, vitamins, amino acids, plant extracts, daily chemical products, cosmetics raw materials, nutrition and health care products, food additives, feed additives, essential oil products, fine chemical products and agricultural chemical raw materials And flavors and fragrances. Especially in the field of vitamins, amino acids, pharmaceutical raw materials and cosmetic raw materials, we have more than 20 years of production and sales experience. All products meet the requirements of high international export standards and have been recognized by customers all over the world. Our manufacture basement & R&D center located in National Aerospace Economic & Technical Development Zone Xi`an Shaanxi China. Now not only relying on self-cultivation and development as well as maintains good cooperative relations with many famous research institutes and universities in China. Now, we have closely cooperation with Shanghai Institute of Organic Chemistry of Chinese Academy of Science, Beijing Institute of Material Medical of Chinese Academy of Medical Science, China Pharmaceutical University, Zhejiang University. Closely cooperation with them not only integrating Science and technology resources, but also increasing the R&D speed and improving our R&D power. Offering Powerful Tech supporting Platform for group development. Keep serve the manufacture and the market as the R&D central task, focus on the technical research.  Now there are 3 technology R & D platforms including biological extract, microorganism fermentation and chemical synthesis, and can independently research and develop kinds of difficult APIs and pharmaceutical intermediates. With the strong support of China State Institute of Pharmaceutical Industry (hereinafter short for CSIPI), earlier known as Shanghai Institute of Pharmaceutical Industry (SIPI), we have unique advantages in the R & D and industrialization of high-grade, precision and advanced products.  Now our Group technical force is abundant, existing staff more that 1000 people, senior professional and technical staff accounted for more than 50% of the total number of employees, including 15 PhD research and development personnel, 5 master′ S degree in technical and management personnel 9 people. We have advanced equipment like fermentation equipment and technology also extraction, isolation, purification, synthesis with rich production experience and strict quality control system, According to the GMP required, quickly transforming the R&D results to industrial production in time, it is our advantages and our products are exported to North and South America, Europe, Middle East, Africa, and other five continents and scale the forefront in the nation, won good international reputation.  We believe only good quality can bring good cooperation, quality is our key spirit during our production, we are warmly welcome clients and partner from all over the world contact us for everlasting cooperation, Leader will be your strong, sincere and reliable partner in China.

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Vancomycin Basic information Overview Indication and Administration Pharmacodynamic Brand Name(s) in US Mode of action Resistance issue Side effects References Product Name: Vancomycin Synonyms: Vancomycin (base and/or unspecified salts);VANCOMYCIN;Vancomycin Base;(3S,6R,7R,22R,23S,26S,36R,38aR)-3-(2-Amino-2-oxoethyl)-44-[[2-O-(3-amino-2,3,6-trideoxy-3-C-methyl-α-L-lyxo-hexopyranosyl)-β-D-glucopyranosyl]oxy]-10,19-dichloro-2,3,4,5,6,7,23,24,25,26,36,37,38,38a-tetradecahydro-7,22,28,30,32-pentahydroxy-6-[[(2R)-4-methyl-2-(methylamino)-1-oxopentyl]amino]-2,5,24,38,39-pentaoxo-22H-8,11:18,21-Dietheno-23,36-(iminomethano)-13,16:31,35-dimetheno-1H,16H-[1,6,9]oxadiazacyclohexadecino[4,5-m][10,2,16]benzoxadiazacyclotetracosine-26-carboxylic acid;Vancomycin USP/EP/BP;demethylvancomycin USP/EP/BP;Vancomycin,USP，≥950μg/mg;vancomycin hcl vancocin CAS: 1404-90-6 MF: C66H75Cl2N9O24 MW: 1449.25 EINECS: 215-772-6 Product Categories:   Mol File: 1404-90-6.mol   Vancomycin Chemical Properties Melting point  >274°C (dec.) density  1.2882 (rough estimate) refractive index  1.7350 (estimate) storage temp.  2-8°C solubility  DMSO (Slightly) pka pKa 2.18±0.08(H2O t = 25.0±0.1 I = 0.2 (NaCl) N2 atmosphere) (Uncertain);7.75±0.02(H2O t = 25.0±0.1 I = 0.2 (NaCl) N2 atmosphere) (Uncertain);8.89±0.01(H2O t = 25.0±0.1 I = 0.2 (NaCl) N2 atmosphere) (Uncertain) form  Solid color  Off-White Stability: Hygroscopic CAS DataBase Reference 1404-90-6(CAS DataBase Reference)   Safety Information Hazardous Substances Data 1404-90-6(Hazardous Substances Data) MSDS Information   Vancomycin Usage And Synthesis Overview Vancomycin is a complex tricyclic glycopeptide antibiotic produced by Streptococcus orientalis[1, 2]. Vancomycin was first discovered from a soil sample in the interior jungle of Borneo in the 1950s, and its usage was very limited due to the presence of impurities that caused toxicities in the earlier preparations. However, the use of vancomycin was reconsidered after the emergence of methicillin-resistant Staphylococci in the 1970s, and its usage increased from the 1980s after purer preparations were made in late 1970s[3]. Now, vancomycin has become the most common injectable drug of choice to treat methicillin-resistant Staphylococci species and drug resistant Enterococcus species[4]. Figure 1 The chemical structure of vancomycin VCM is generally prescribed to combat severe infections caused by Gram-positive bacteria, to fight microorganisms that are resistant to other antimicrobial agents or still indicated to patients who are allergic to penicillins and cephalosporins[1, 5]. As a consequence, it is very much used in intensive care units (ICU) for the treatment of not only hospital infections and sepsis, but also of pneumonia cases, empyema, endocarditis, osteomyelitis, soft tissue abscesses among others[1, 6, 7]. This drug is not the first-choice agent owing to its adverse effects like hypotension and tachycardia, phlebitis, nephrotoxicity, ototoxicity[7], hypersensibility reactions, chills, exanthema and fever1, and the fact that peripheral IV complications are a major concern[8]. The literature reveals that the use of inappropriate doses and prolonged therapyes increase the risk of toxicity that, in turn, favors the onset of adverse effects[9-11]. Therefore, the people who use antibiotics in animals and humans must be vigilant about the adverse. Therefore, the people who use antibiotics in animals and humans must be vigilant about the adverse effects and the proper doses—especially in case of last-line antibiotics such as vancomycin. 3 doses; however, higher doses may be prescribed1. Although the established pediatric doses vary according to the age range described below[1, 3], no consensus has been reached regarding the adequate dose of vancomycin for children. Indication and Administration Vancomycin is active against most strains of Clostridia, resistant strains), coagulase-negative Staphylococci, and Viridans group Staphylococci and Enterococci. Vancomycin is not effective against Gram-negative bacteria[12]. Vancomycin is one of the antibiotics of last resort, used only after treatment with other antibiotics has failed in the treatment of life-threatening infections by Gram-positive bacteria. Even though vancomycin has great potential in treating infections in animals, the use of vancomycin in veterinary medicine is limited because it is expensive and requires continuous intravenous infusion[13]. Powdered vancomycin is reconstituted in sterile water, which results in a dark-colored solution, and it is further diluted in 5% dextrose or saline when it is administered. The reconstituted solution is stable for 14 days either at room temperature or in a refrigerator. Additionally, 125 mg and 250 mg vancomycin tablets are available for oral administration[14].  Pharmacodynamic The factors that affect the activity of vancomycin are its tissue distribution, its protein-binding, inoculum size, and resistant organisms. The volume of distribution in humans is 0.4–1 L/kg; in dogs, 0.4–5.5 L/kg[15]. The binding of vancomycin to protein has a range from 10% to 50%. A 1–8-fold increase in the minimum inhibitory concentration (MIC) has been shown in several in vitro assessments as a result of the presence of albumin, whereas the presence of serum has had a more variable effect[16]. It is evident in an in vitro pharmacodynamic model that the time taken to kill is longer when the inoculum size is high (9.5 log10 CFU/g) compared to a moderate inoculum (5.5 log10 CFU/g): 48 versus 72 h, respectively, for both the methicillin sensitive Staphylococci and methicillin-resistant Staphylococci organisms isolated from human patients[16,17]. Vancomycin penetrates into most body spaces, and the penetrability is dependent on the degree of inflammation present. The concentration of vancomycin in different body spaces is different[18]. The inflamed meninges improve the penetration of vancomycin into the cerebral spinal fluid, with reported concentrations of 6.4–11.1 mg/L, whereas uninflamed meninges have resulted in low concentrations of 0–3.45 mg/L in humans[19]. Furthermore, it has been shown in a rabbit model that a high concentration of vancomycin is present in the cerebral spinal fluid of inflamed meninges[20]. Therapeutic concentrations of vancomycin in ascitic, pericardial, pleural, and synovial fluids are greater than 2.5 mg/L in humans[21]. More than 80% and 50% of a vancomycin dose is excreted unchanged in the urine (mostly by way of glomerular filtration) within 24 h after administration in humans and dogs, respectively, and the concentration of vancomycin in liver tissue and bile is below detectable levels. Vancomycin has a distribution phase of 30 min to 1 h. The half-life of vancomycin in patients with normal creatinine clearance in humans is about 6 h; dogs, 2 h; horses, 3 h[22]. Brand Name(s) in US Vancocin, Vancoled Mode of action The mechanism of action of this antimicrobial agent is via the inhibition of bacterial cell wall biosynthesis or, more specifically, the inhibition of peptidoglycan biosynthesis. It is, therefore, bactericidal for reproductive bacteria[1]. The bacterial cell wall contains peptidoglycan that encircles the whole bacteria. In Gram-positive bacteria this substance is more significantly present, and it forms large and insoluble layers on the outer part of the cell membrane, totaling up to 40 layers which consist of multiple skeletons of amino sugars: N-acetylglucosamine and N-acetylmuramic[24]. The latter contains lateral short peptide residues with cross-links, which form a high-level resistant polymeric chain. The drug inhibits this polymerization or the transglycosylase reaction once it binds with high affinity to the C-terminal D-alanyl D-alanine residues of lipid-linked cell wall precursors and blocks the linkage to the glycopeptide polymer1. As a result, it hinders the cross-links of peptides from binding to tetrapeptide side chains; namely, it prevents its linkage to the growing tip of the peptidoglycan[24]. Resistance issue Antibiotic use either as therapy, in the prevention of bacterial diseases, or as performance enhancers has resulted in antibiotic-resistant microorganisms in pathogens and among bacteria of the endogenous microflora of animals. Antibiotic-resistant bacteria present in animals can be transmitted to humans via contact or via the food chain. Furthermore, resistance genes of animal bacteria can be transferred to human pathogens in the intestinal flora of humans. The development of intermediate and high levels of resistance to vancomycin for Staphylococcus aureus was reported for the first time in Japan in 1997[25]. According to guidelines of the Clinical Laboratory Standards Institute, susceptibility break points of vancomycin are <4 mcg/mL for Enterococcus, <1 mcg/mL for Streptococcus, and <4 mcg/mL for Staphylococcus. However, in 2006, the vancomycin MIC breakpoints for S. aureus were lowered to 2 ug/mL for “susceptible”, 4–8 ug/mL for “intermediate”, and 16 ug/mL for “resistant”[26]. Enterococci should be regularly tested in vitro for susceptibility to vancomycin for determination of MIC. Enterococci are deemed susceptible to vancomycin if MICs are <4 ug/mL; they are considered as intermediate level resistance to vancomycin if MICs are 8 to 16 ug/mL; and as complete resistance to vancomycin if MICs are >16 ug/mL. Side effects Prolonged intravenous use of vancomycin may cause neutropenia, thrombophlebitis, rash, fever, anemia, thrombocytopenia, and ototoxic reactions in humans and animals. Vancomycin should be administered intravenously in diluted form, because it is highly irritable for the tissues. It may cause local phlebitis at the site of injection in animals[14]. Vancomycin should be infused for over 1h to reduce the risk of the histamine release-associated “red man” syndrome in humans. It is advised not to administer intravenous rapidly, so as to avoid acute adverse reaction in animals[4]. The major drawback of vancomycin usage is auditory damage in humans; however, tinnitus and deafness might improve once the treatment is ceased. In addition to that, nausea, chills, phlebitis, severe hypotension, wheezing, dyspnoea, urticaria, and pruritus have been observed with the treatment of vancomycin in humans[27–30]. In some instances, neutropenia was detected with prolonged therapy[31]. There is a potential for nephrotoxicity and ototoxicity with vancomycin in animals[32]. Toxicities are minimal in vancomycin monotherapy at conventional dosages of 1 g (15 mg/kg) every 12 h in humans[33]. However, increased incidence of nephrotoxicity has been established with doses of 4 g/day or higher. As a result of elevated dosage, serum concentrations may increase, which may lead to toxicity[34]. Vancomycin increases the risk of nephrotoxicity in humans with drugs such as amphotericin, capreomycin, cyclosporine, cisplatin, colistimethate, polymyxins, and tacrolimus. References GUPTA A, BIYANI M, KHAIRA A. Vancomycin nephrotoxicity: myths and facts. Neth J Med 2011; 69: 379-383. DEHORITY W. Use of vancomycin in pediatrics. Pediatr Infect Dis J 2010; 29: 462-464. Moellering, R.C., Jr. Vancomycin: A 50-year reassessment. Clin. Infect. Dis. 2006, 42, S3–S4. Mark, G.P. Saunders Handbook of Veterinary Drugs Small and Large Animal, 3rd ed.; Saunders: Philadelphia, PA, USA, 2011. HICKS RW, HERNANDEZ J. Perioperative pharmacology: a focus on vancomycin. AORN J 2011; 93: 593-599. PLAN O, CAMBONIE G, BARBOTTE E, MEYER P, DEVINE C, MILESI C, PIDOUX O, BADR O, PICAUD JC. Arch Dis Child Fetal Neonatal 2008; 93: 418-421. BADRAN EF, SHAMAYLEH A, IRSHAID YM. Int J Clin Pharmacol Ther 2011; 49: 252-257. ROSZELL S, JONES C. J Infusion Nurs 2010; 33: 112-118. NUNN MO, CORALLO CE, AUBRON C, POOLE S, DOOLEY MJ, CHENG AC. Ann Pharmacother 2011; 45: 757-763. PRITCHARD L, BAKER C, LEGGETT J, SEHDEV P, BROWN A, BAYLEY BK. Am J Med 2010; 123: 1143-1149. KHOTAEI GT, JAM S, SEYED AS, MOTAMED F, NEJAT F, TAGHI M, ASHTIANI H, IZADYAR M. Acta Med Iran 2010; 48: 91-94. Bennett, P.N.; Brown, M.J. Vancomycin, Clinical Pharmacology, 9th ed.; Churchill Livingstone: London, UK, 2000. John, F.P.; Baggot, J.D.; Walker, R.D. Glycopeptides: Vancomycin, Teicoplanin, and Avoparcin, Antimicrobial Therapy in Veterinary Medicine, 3rd ed.; Blackwell Publishing Professional: Ames, IA, USA, 2000. Levison, M.E.; Levison, J.H. Infect. Dis. Clin. N. Am. 2009, 23, 791–815. Cantu, T.G.; Dick, J.D.; Elliott, D.E.; Humphrey, R.L.; Kornhauser, D.M. Protein binding of vancomycin in a patient with immunoglobulin A myeloma. Antimicrob. Agents Chemother. 1990, 34, 1459–1461. Micek, S.T. Clin. Infect. Dis. 2007, 45, S184–S190. Koteva, K.; Hong, H.L.; Wang, X.D.; Nazi, I.; Hughes, D.; Naldrett, M.J.; Buttner, M.J.; Wright, G.D. A. Nat. Chem. Biol. 2010, 6, 327–329. Albanese, J.; Leone, M.; Bruguerolle, B.; Ayem, M.L.; Lacarelle, B.; Martin, C. Antimicrob. Agents Chemother. 2000, 44, 1356–1358. Nau, R.; Sörgel, F.; Eiffert, H. Clin. Microbiol. Rev. 2010, 23, 858–883. Matzneller, P.; Burian, A.; Zeitlinger, M.; Sauermann, R. Pharmacology 2016, 97, 233–244. Forouzesh, A.; Moise, P.A.; Sakoulas, G. Vancomycin ototoxicity: A reevaluation in an era of increasing doses. Antimicrob. Agents Chemother. 2009, 53, 2483–2486. CHAMBERS HF. Antimicrobial agents: Protein Synthesis Inhibitors and miscellaneous antibacterial agents. In: Goodman and Gilman's the pharmacological basis of therapeutics 11th edition. Edited by Joel G. Hardman, Lee E. Limbird. New York, McGraw-Hill, 2010; pp. 1074-1077. Chen, C.Y.; Huang, Y.C. Review: New epidemiology of Staphylococcus aureus infection in Asia. Clin. Microbiol. Infect. 2014, 20, 605–623. Tenover, F.C., Jr.; Moellering, R.C. Clin. Infect. Dis. 2007, 44, 1208–1215. Brummett, R.E.; Fox, K.E. Antimicrob. Agents Chemother. 1989, 33, 791–796. Elting, L.S.; Rubenstein, E.B.; Kurtin, D.; Rolston, K.V.; Fangtang, J.; Martin, C.G.; Raad, I.I.; Whimbey, E.E.; Manzullo, E.; Bodey, G.P. Mississippi mud in the 1990s: Risks and outcomes of vancomycin-associated toxicity in general oncology practice. Cancer 1998, 83, 2597–2607. Stanley, D.; McGrath, B.J.; Lamp, K.C.; Rybak, M.J. Pharmacotherapy 1994, 14, 35–39. Tange, R.A.; Kieviet, H.L.; Marle, J.V.; Sjoback, D.B.; Ring,W. An experimental study of vancomycin-induced cochlear damage. Arch. Otorhinolaryngol. 1989, 246, 67–70. Pai, M.P.; Mercier, R.C.; Koster, S.A. Epidemiology of vancomycin-induced neutropenia in patients receiving home intravenous infusion therapy. Ann. Pharmacother. 2006, 40, 224–228. Bishop, T. Vancomycin. In The Veterinary Formulary, 6th ed.; Pharmaceutical Press: London, UK, 2005. Ray, A.S.; Haikal, A.; Hammoud, K.A.; Yu, S.L. Vancomycin and the Risk of AKI: A Systematic Review and Meta-Analysis. CJASN 2016, 11, 2132–2140. Bailie, G.R.; Neal, D. Vancomycin ototoxicity and nephrotoxicity. Med. Toxicol. Advers. Drug Exp. 1988, 3, 376–386. Description Vancomycin is produced by fermentation of Amycol atopsis orientalis (formerly Nocardi a orientalis). It has been available for approximately 40 years, but its popularity has increased significantly with the emergence of MRSA in the early 1980s. Chemically, vancomycin has a glycosy lated hexapeptide chain that is rich in unusual amino acids, many of which contain aromatic rings cross-linked by aryl ether bonds into a rigid molecular framework. Originator Vancocin,Lilly,US,1958 Uses Antibacterial. Uses Vancomycin is used for serious bacterial infections caused by microorganisms sensitive to this drug when penicillins and cephalosporins are ineffective for diseases such as sepsis, endocarditis, pneumonia, pulmonary abscess, osteomyelitis, meningitis, and enterocolitis, or when penicillins and cephalosporins cannot be tolerated by patients. Vancomycin is the drug of choice for infections caused by methicillin-resistant forms of S. aureus, S. epidermidus, and other coagulase-negative staphylococci, as well as for endocarditis, diphtherioid infections, and for patients very sick with colitis caused by C. difficile. A synonym of this drug is vancocin. Definition ChEBI: A complex glycopeptide from Streptomyces orientalis. It inhibits a specific step in the synthesis of the peptidoglycan layer in the Gram-positive bacteria Staphylococcus aureus and Clostridium difficile. Manufacturing Process An agar slant is prepared containing the following ingredients: 20 grams starch, 1 gram asparagine, 3 grams beef extract, 20 grams agar, and 1 liter water. The slant is inoculated with spores of S. orientalis, Strain M43-05865, and is incubated for about 10 days at 30°C. The medium is then covered with sterile distilled water and scraped to loosen the spores. The resulting suspension of spores is preserved for further use in the process. A liquid nutrient culture medium is prepared containing the following ingredients: 15 grams glucose, 15 grams soybean meal, 5 grams corn steep solids, 2 grams sodium chloride, 2 grams calcium carbonate, and 1 liter water. The medium is sterilized at 120°C for about 30 minutes in a suitable flask and cooled. 10 ml of a spore suspension prepared as set forth above are used to inoculate the medium. The inoculated medium is shaken for 48 hours at 26°C on a reciprocating shaker having a 2-inch stroke, at 110 rpm. The fermented culture medium which comprises a vegetative inoculum is used to inoculate a nutrient culture medium containing the following ingredients: 20 grams blackstrap molasses, 5 grams soybean peptone, 10 grams glucose, 20 grams sucrose, 2.5 grams calcium carbonate, and 1 liter water. The medium is placed in a container having a suitable excess capacity in order to insure the presence of sufficient oxygen and is sterilized by heating at 120°C for about 30 minutes. When cool, the medium is inoculated with about 25 ml of a vegetative inoculum as described above, and the culture is then shaken for about 80 hours at 26°C. The pH of the medium at the beginning of fermentation ranges from about 6.5 to about 7.0 and the final pH is about 7.0 to about 8.0. A fermentation broth thus obtained contained about 180 μg of vancomycin per ml. Brand name Vancocin Hydrochloride (ViroPharma); Vancoled (Baxter Healthcare); Vancor (Pharmacia & Upjohn). Therapeutic Function Antibacterial Acquired resistance Only very recently, despite decades of intensive use, have some vancomycin-resistant bacteria emerged (vancomycin-resistant enterococcus [VRE] and vancomycin-resistant Staphylococcus aureus) [VRSA]. It is alleged that these resistant strains emerged as a consequence of the agricultural use of avoparcin, a structurally related antibiotic that has not found use for human infections in the United States but was used in Europe before its recent ban. The mechanism of resistance appears to be alteration of the target D-alanyl-D-alanine units on the peptidoglycan cell wall precursors to D-alanyl-D-lactate. This results in lowered affinity for vancomycin due to lack of a key hydrogen bonding interaction. It is greatly feared that this form of resistance will become common in the bacteria for which vancomycin is presently the last sure hope for successful chemotherapy. If so, such infection would become untreatable. These resistant strains are not yet common in clinically relevant strains, but most authorities believe that this is only a question of time. Vancomycin-intermediate S.aureus, also called glycoprotein-intermediate S.aureus (VISA), also has been reported. It appears to be resistant because of a thickened peptidoglycan layer. Mechanism of action Vancomycin is a bacterial cell wall biosynthesis inhibitor. Evidence suggests that the active species is a homodimer of two vancomycin units. The binding site for its target is a peptide-lined cleft having high affinity for acetyl-D-alanyl-D-alanine and related peptides through five hydrogen bonds. It inhibits both transglycosylases (inhibiting the linking between muramic acid and acetyl glucosamine units) and transpeptidase (inhibiting peptide cross-linking) activities in cell wall biosynthesis. Thus, vancomycin functions like a peptide receptor and interrupts bacterial cell wall biosynthesis at the same step as the β-lactams do, but by a different mechanism. By covering the substrate for cell wall transamidase, it prevents cross-linking resulting in osmotically defective cell walls. Clinical Use Although a number of adverse effects can result from IV infusion, vancomycin has negligible oral activity. It can be used orally for action in the GI tract, especially in cases of Cl ostri di um difficile overgrowth. The useful spectrum is restricted to Gram-positive pathogens, with particular utility against multiply-resistant, coagulase-negative staphylococci and MRSA, which causes septicemias, endocarditis, skin and soft-tissue infections, and infections associated with venous catheters. Clinical Use Vancomycin was discovered, developed, and approved by the US Food and Drug Administration in the 1950s. In 1956, it was introduced in the USA as a possible treatment for infections due to penicillinresistant S. aureus, but it was not used widely because of toxicity and the nearly simultaneous development of semisynthetic antibiotics and cephalosporins. Thus, its main indication was the treatment of serious Gram-positive infections in penicillin-allergic patients. In clinical practice, however, nafcillin remained the treatment of choice for staphylococcal bacteremia, largely because it had failure rates of only 4%. With the appearance of methicillin-resistant S. aureus and coagulase-negative staphylococci, vancomycin became the drug of choice for these infections. With the recognition and/or emergence of S. aureus strains (generally MRSA isolates) with reduced susceptibility to vancomycin 586 Glycopeptides and Lipopeptides, vancomycin efficacy may be less in some clinical situations than previously reported – especially in serious deep-seated infections, such as endocarditis and prosthetic device infections. This is demonstrated by increased mortality seen in patients with MRSA infection and markedly attenuated vancomycin efficacy caused by vancomycin heteroresistance in S. aureus. Resistance of S. aureus to vancomycin can be a continuous phenomenon, rather than a categorical one. Thus, this has resulted in some clinical microbiology laboratories having difficulty identifying S. aureus strains that have reduced vancomycin susceptibility based on standard laboratory susceptibility testing methodology. A better understanding is still needed of the pharmacodynamic relationship between vancomycin and MRSA as relates to optimal dosing strategies, including consideration of loading doses.  Clinical Use Vancomycin was discovered, developed, and approved by the US Food and Drug Administration in the 1950s. In 1956, it was introduced in the USA as a possible treatment for infections due to penicillinresistant S. aureus, but it was not used widely because of toxicity and the nearly simultaneous development of semisynthetic antibiotics and cephalosporins. Thus, its main indication was the treatment of serious Gram-positive infections in penicillin-allergic patients. In clinical practice, however, nafcillin remained the treatment of choice for staphylococcal bacteremia, largely because it had failure rates of only 4%. With the appearance of methicillin-resistant S. aureus and coagulase-negative staphylococci, vancomycin became the drug of choice for these infections. With the recognition and/or emergence of S. aureus strains (generally MRSA isolates) with reduced susceptibility to vancomycin 586 Glycopeptides and Lipopeptides, vancomycin efficacy may be less in some clinical situations than previously reported – especially in serious deep-seated infections, such as endocarditis and prosthetic device infections. This is demonstrated by increased mortality seen in patients with MRSA infection and markedly attenuated vancomycin efficacy caused by vancomycin heteroresistance in S. aureus. Resistance of S. aureus to vancomycin can be a continuous phenomenon, rather than a categorical one. Thus, this has resulted in some clinical microbiology laboratories having difficulty identifying S. aureus strains that have reduced vancomycin susceptibility based on standard laboratory susceptibility testing methodology. A better understanding is still needed of the pharmacodynamic relationship between vancomycin and MRSA as relates to optimal dosing strategies, including consideration of loading doses.  Side effects Vancomycin is highly associated with adverse infusion-related events. These are especially prevalent with higher doses and a rapid infusion rate. A rapid infusion rate has been shown to cause anaphylactoid reactions, including hypotension, wheezing, dyspnea, urticaria, and pruritus. A significant drug rash (the so-called red man syndrome) also can occur. These events are much less frequent with a slower infusion rate. In addition to the danger of infusion-related events, higher doses of vancomycin can cause nephrotoxicity and auditory nerve damage. The risk of these effects is increased with elevated, prolonged concentrations, so vancomycin use should be monitored, especially in patients with decreased renal function. The ototoxicity may be transient or permanent and more commonly occurs in patients receiving high doses, patients with underlying hearing loss, and patients being treated concomitantly with other ototoxic agents (i.e., aminoglycosides). Drug interactions Potentially hazardous interactions with other drugs Antibacterials: increased risk of nephrotoxicity and ototoxicity with aminoglycosides, capreomycin or colismethate sodium; increased risk of nephrotoxicity with polymyxins. Ciclosporin: variable response; increased risk of nephrotoxicity. Diuretics: increased risk of ototoxicity with loop diuretics. Muscle relaxants: enhanced effects of suxamethonium. Tacrolimus: possible increased risk of nephrotoxicity Metabolism Little or no metabolism of vancomycin is thought to take place. It is excreted unchanged by the kidneys, mostly by glomerular filtration. There is a small amount of nonrenal clearance, although the mechanism for this has not been determined.   Vancomycin Preparation Products And Raw materials Raw materials Vancomycin, 28,30,32-tri-O-2-propenyl-N3'',56-bis[(2-propenyloxy)carbonyl]-, 2-propenyl ester-->DesvancosaMinyl VancoMycin Preparation Products AC-LYS(AC)-D-ALA-D-ALA-OH