CS277248B6 - Method of quantitative evaluation of the effect of antibacterial agents "in vitro" - Google Patents
Method of quantitative evaluation of the effect of antibacterial agents "in vitro" Download PDFInfo
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Abstract
Za vhodných rastových podmienok sa paralelné porovnává rast a rozmnožovanie kontrolnej a různými koncentráciami antimikrobiálnej látky ovplyvnených bakteriálnych kultrúr. Na kvantitativné hodnotenie životnosti a rastových vlastností baktérií sa do kultivačného prostredia přidá vo vodě rozpustná sol tetrazóliového farbiva, výhodné 3-(4,5-dimetyltiazol-2-yl)-2,5-difenyltetrazolium bromid v konečnej koncentrácii 0,005 až 5,0 g/1, výhodné 0,25 g/1, redukcia přidaného tetrazoliového farbiva prebieha vo všetkých kultúrach paralelné a presne ohraničenú dobu, výhodné 15 minút, po ktorej sa reakcia ukončí a vo vodě rozpustný farebný produkt sa solubilizuje přidáním zmesi detergentů a organického rozpúštadla, množstvo vytvořeného farebného produktu sa kvantitativné určí spektrofotometricky, výhodné v oblasti jeho absorpčné- ;ho maxima, a podlá množstva vytvořeného farebného produktu sa určí koncentrácia ;a antimikrobiálnej látky potřebná pre dosiahnutie požadovaného bakteriostatické- ho, alebo bakteriocídneho účinku na vyšet řovánu kultúru mikroorganizmov.Under appropriate growth conditions, the growth and reproduction of the control and bacterial cultures affected by various concentrations of antimicrobial substances are compared in parallel. For quantitative evaluation of the viability and growth properties of bacteria, a water-soluble salt of a tetrazolium dye is added to the culture medium, preferably 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide in a final concentration of 0.005 to 5.0 g/l, preferably 0.25 g/l, the reduction of the added tetrazolium dye takes place in all cultures in parallel and for a precisely defined period of time, preferably 15 minutes, after which the reaction is terminated and the water-soluble colored product is solubilized by adding a mixture of detergents and an organic solvent, the amount of the formed colored product is quantitatively determined spectrophotometrically, preferably in the region of its absorption maximum, and the concentration of the antimicrobial substance necessary to achieve the desired bacteriostatic or bactericidal effect on the culture of microorganisms under investigation is determined based on the amount of the formed colored product.
Description
1 CS 277248 B61 CS 277248 B6
Vynález sa týká postupu na "in vitro" hodnotenie účinkuantibakteriálnych látok na základe merania kvantitativných zmienrastu a rozmnožovania baktérií pomocou spektrofotometrickej meto-dy, pri ktorej množstvo za určitý čas živými organizmami vytvoře-né farebného produktu priamo závisí od ich počtu a metabolickejaktivity.BACKGROUND OF THE INVENTION The present invention relates to a process for "in vitro" evaluation of antibacterial activity by measuring the quantitative variation and multiplication of bacteria by a spectrophotometric method in which the color product produced by the living organisms depends directly on their number and metabolic activity.
Hodnotenie počtu, rastu a rozmnožovania baktérií "in vitro"sa v praxi často využívá pri posudzovaní účinnosti antimikrobiál-nych látok. Jednou zo základných požiadaviek kladených na takétostanovenie je popři přesnosti a jednoduchosti aj jeho rýchlosú.In vitro evaluation of the number, growth and reproduction of bacteria is often used in assessing the efficacy of antimicrobials. One of the basic requirements for such a provision is its speed and accuracy as well as simplicity.
Pre rýchle stanovenie počtu, rastu a rozmnožovania baktériísa doposiaí vyvinulo niekolko postupov: 1. Priame mechanické, alebo elektronické počítanie častíc (Pring-le, J.R. Mor, J.R.: Methods for monitoring the growth of yeastcultures and for dealing with the dumping problém. Methods Cell.Biol., XI, 1975, 153-168). 2. Fotometrické meranie zmien zákalu (turbidimetria), aleborozptylu světla (nefelometria) prechádzajúceho suspenziou bakté-rií (Koch, A.L.: Theory of the angular dependence of light scat-tered by bacteria and similar-sized biological objects. J. Theor.Biol., 18, 1968, 133-156). 3. Meranie zmien elektrickéj impedancie v kultúře rastúcichmikroorganizmov (Ur. A., Brown, D.F.J.: Rapid detection of bacte-rial activity using impedance measurement. J. Biomed. Eng., 9,1974, 18-20, patent US 4528270). 4. Mikrokalorické meranie v kultúře rastúcich mikroorganizmov(Binford, J.S., Binford, L.S., Adler, P.: A semiautomated mikcro-calorimetric měthod of antibiotic sensitivity testing. Am. J.Clin. Pathol., 59, 1973, 86-94). 5. Meranie změny pH spósobenej skvasovaním glukózy v nepufrovanomkultivačnom médiu (čs. patent 215861), 6. Meranie množstva živými baktériami vytvořeného ATP (Karl,D.M.: Cellular nucleotide measurements and applications in micro-bial ecology, Microbiol. Rev., 44, 1980, 739-796). 7. Radiometrické metody (De Blanc, J.J., Charache, P., Wagner, H.N.: Automatic radiometric measurement of antibiotic effect onbacterial growth. Antimicrob. Agents Chemother., 2, 1972,360—366). 8. Kvantitativné meranie množstva enzýmov uvolněných rastúcimibaktériami do kultivačného prostredia pomocou fluorogénnychsubstrátov (Philips, I., Waren, C., Waterworth, P.M. : Determina—tion of antibiotic sensitivities by Sensititre systém. J. Clin.Pathol., 31, 1978, 531-535).To quickly determine the number, growth and reproduction of bacteria, several techniques have been developed to date: 1. Direct mechanical or electronic particle counting (Pringle, JR Mor, JR: Methods for monitoring the growth of yeastcultures and for dealing with the dumping problem. Biol., XI, 1975, 153-168). 2. Photometric measurement of turbidimetry, but also light scattering (nephelometry) passing through a bacterial suspension (Koch, AL: Theory of Angular Dependence of Light Scatter by Bacteria and similar-sized biological objects. J. Theor. Biol. , 18, 1968, 133-156). 3. Measurement of electrical impedance changes in culture of growing microorganisms (Ur. A., Brown, D.F.J .: Rapid detection of bacterial activity using impedance measurement. J. Biomed. Eng., 9,1974, 18-20, U.S. Patent 4,528,270). 4. Microcaloric measurement in culture of growing microorganisms (Binford, JS, Binford, LS, Adler, P .: A microscopic microscopic calorimetry of antibiotic sensitivity testing. Am. J. Clin. Pathol., 59, 1973, 86-94) . 5. Measurement of pH change due to glucose fermentation in unbuffered culture medium (U.S. Pat. No. 215861); 6. Measurement of live bacteria produced by ATP (Karl, DM: Cellular nucleotide measurements and applications in micro-binary ecology, Microbiol. Rev., 44, 1980) , 739-796). 7. Radiometric methods (De Blanc, J.J., Charache, P., Wagner, H.N .: Automatic radiometric measurement of antibiotic effect on bacterial growth. Antimicrob. Agents Chemother., 2, 1972, 360-366). 8. Quantitative measurement of the amount of enzymes released by growing bacteria in the culture medium by fluorogenic substrates (Philips, I., Waren, C., Waterworth, PM: Determination of antibiotic sensitivities by Sensititre system. J. Clin. Pathol., 31, 1978, 531 -535).
Metody podlá uvedených príkladov majú viaceré nedostatky, ktoré spočívajú najma v nutnosti používal suspenziu mikroorganiz- mov o hustotě až 3 x 108/ml (postupy 2,4), zložitosti postupu a prácnosti metody (1, 4, 6), požiadavke na zložité vyhodnocova- CS 277248 B6 2 cie zariadenie (3, 4,, 6, 7, 8), nutnosti pracoval s radioaktív-nymi látkami (7) a komplikovanom rozlišeni medzi stupňom meranejaktívnej odpovede od pozadia a nešpecifických artefaktov (8).The methods according to the examples have several drawbacks, which are mainly due to the necessity to use a suspension of microorganisms with a density of up to 3 x 10 8 / ml (procedures 2.4), the complexity of the procedure and the labor of the method (1, 4, 6), the requirement for complex evaluation CS 277248 B6 2, the need to work with radioactive substances (7) and a complicated distinction between the degree of active response from the background and non-specific artefacts (8).
Uvedené nedostatky odstraňuje postup kvantitativného hodno-tenia účinku antibakteriálnych látok "in vitro" podía vynálezu,ktorý spočívá v kvantitatívnom hodnotení zmien počtu, rastua rozmnožovania živých, metabolicky aktívnych baktériálnych buni-ek na základe nimi spósobenej redukcie soli tetrazóliového farbi-va. Pri reakcii, ktorá prebieha výlučné v živých buňkách, dochád-za k interakcii medzi tetrazóliovou solou a cytochrómovým systé-mom bakteriálnej buňky, pričom sa tetrazóliová sol redukuje zavzniku farebného produktu, ktorého množstvo je úměrné počtu a me—tabolickej aktivity přítomných baktériálnych buniek. K výhodám postupu podlá vynálezu v porovnaní s doterajšimiprístupmi patří vysoká citlivost (na stanovenie stačí už hustota bakteriálnej suspenzie 2 x 104/ml), reakcie prebieha výlučnév živých buňkách, minimálny potřebný reakčný čas sa podlá metabo-lickej aktivity pre váčšinu baktérií pohybuje v rozmedzí 1 až 30minút. .Metodický postup je jednoduchý a nevyžaduje žiadne sepa-račné kroky, co spolu so spektrofotometrickým spósobom vyhodnoco-vania vytvára vhodné podmienky pre jednoduchú automatizáciu.Finančně náklady na stanovenie sú nižšie než pri porovnatelnýchmetodách.The above-mentioned drawbacks are eliminated by the quantitative evaluation of the effect of antibacterial agents "in vitro" according to the invention, which consists in quantifying the changes in the number, growth and reproduction of live, metabolically active bacterial cells based on the reduction of the tetrazolium dye salt. In a reaction that occurs exclusively in living cells, there is an interaction between the tetrazolium salt and the cytochrome system of the bacterial cell, whereby the tetrazolium salt is reduced to the color product, the amount of which is proportional to the number and metabolic activity of the bacterial cells present. Advantages of the process according to the invention compared to the previous approaches include high sensitivity (the density of the bacterial suspension of 2 x 10 4 / ml is sufficient for the determination), the reaction proceeds exclusively in living cells, the minimum required reaction time is 1 within the metabolic activity of most bacteria up to 30 minutes. The method is simple and requires no separation steps, which, together with the spectrophotometric method of evaluation, create the right conditions for simple automation. The cost of the determination is financially lower than for comparable methods.
Možnosti použitia postupu podlá vynálezu sú objasněné napríkladoch rýchleho stanovenia citlivosti baktérie Escherichiacoli na rožne koncentrácie bakteriostatického antibiotika tetra-cyklinu. (A) a bakteriocídneho antibiotika s rýchlym nástupomúčinkom kolicínu (B). Příklad A. Hodnotenie antibakteriálneho účinku tetracyklínu.The possibilities of using the process of the invention are explained, for example, by the rapid determination of the susceptibility of the Escherichiacoli bacterium to the bacteriostatic antibiotic tetra-cyclin. (A) and bacteriocidal antibiotic with rapid onset colicin (B). Example A. Evaluation of antibacterial effect of tetracycline.
Do jednotlivých jamiek mikrotestovej platničky s 96 jamkamis plochým dnom sa napipetuje 100 ul bojónu podláMueller-Hintonovej, s klesajúcimi koncentráciami tetracyklínu(256, 128, 64, 32, 16, 8, 4, 2, 1, 0,5 a 0 ug/ml). V tomto bujónesa připraví suspenzia z 18 hodinovej kultúry baktérie Escherichia coli o hustotě IxlO6 baktérií/ml. Do jamiek s antibiotikom sapřidá 100 ul bakteriálnej suspenzie, čím sá dosiahnu výslednékoncentrácie antibiotika 128, 64, 32, 16, 8, 4, 2, 1, 0,5 0,25a 0 ug/ml. Kontrolně jamka obsahuje namiesto bakteriálnej suspen-zie len čistý Mueller-Hintonovej bujón. Platnička sa umiestni do termostatu a inkubuje pri 35 °C 120 minút. Po inkubácii sa dovšetkých jamiek přidá; 20 ul 3-(4,5-dimetylthiazol-2-yl)-2,5-dife-nyl tetrazolium bromidu vo fyziologickom roztoku, koncentrácia2,5 mg/ml) a inkubuje sa dalších 15 minút v termostate pri 35 ’C. Potom sa do všetkých jamiek přidá 50 ul solubilizačnéhoroztoku (20% SDS v 50% vodnom roztoku Μ,Ν-dimetylformamidu, pHupravené HC1 a kyselinou octovou na 4,7). Obsah j amiek sa premie- ša. a platničky sa inkubujú. dalších 5 minút pri 35 "C. Absorbanciav jednotlivých jamkách sa zmeria pomocou spektrofotometra (ELISA;readerj pri 550 nm (specifická absorbancia) a pri 630 nm (nešpe—Pipette 100 µl of Muller-Hinton, 100 µl / well, with decreasing tetracycline concentrations (256, 128, 64, 32, 16, 8, 4, 2, 1, 0.5 and 0 µg / ml) into individual wells of a 96-well flat bottom microtest plate. ). In this broth, a suspension of 18 hour culture of Escherichia coli bacteria at a density of 1x10 6 bacteria / ml is prepared. 100 µl of bacterial suspension is added to the antibiotic wells to give a final antibiotic concentration of 128, 64, 32, 16, 8, 4, 2, 1, 0.5 0.25 and 0 µg / ml. The control well contains only pure Mueller-Hinton broth instead of bacterial suspension. The plate is placed in a thermostat and incubated at 35 ° C for 120 minutes. After incubation, most wells are added; 20 µl of 3- (4,5-dimethylthiazol-2-yl) -2,5-diphenyl tetrazolium bromide in 2.5 mg / ml saline and incubate for an additional 15 minutes in a 35 ° C thermostate. Then 50 µl of solubilization solution (20% SDS in 50% aqueous solution of Ν, β-dimethylformamide, pH adjusted with HCl and acetic acid to 4.7) is added to all wells. The amine content is mixed. and the plates are incubated. additional 5 minutes at 35 ° C. Measure the absorbance of each well using a spectrophotometer (ELISA; reader at 550 nm (specific absorbance) and at 630 nm (non-impact)
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| CS904549A CS277248B6 (en) | 1990-09-19 | 1990-09-19 | Method of quantitative evaluation of the effect of antibacterial agents "in vitro" |
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| CS277248B6 true CS277248B6 (en) | 1992-12-16 |
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