Changes in the cell size of Brevundimonas diminuta using different growth agitation rates

Brevundimonas diminuta (ATCC 19146) is a standard organism for validation of sterilizing-grade membrane filters. Cell size is critical for the determination of retention characteristics of 0.2 micron rated membrane filters. In this study, cell size changes of B. diminuta cultured under different physiologic states and variable agitations at 50, 100 and 200 rpm were measured by a particle size analyzer and scanning electron microscope (SEM). The smallest cells were obtained at initial stationary phase in saline lactose broth (SLB) as a shaking culture at 50 rpm. Cells grown under agitation at 50, 100 and 200 rpm showed an increase of specific growth rate (mu), about 2.9, 3.6 and 3.6 fold, respectively, compared to the non-agitated cells in SLB media. These results suggested that the cell size decreased proportionally with increase of the specific growth rate (mu) in SLB. These size changes were associated with penetration through a 0.2 micron rated cellulose acetate filter. A scale-down filtration system was developed and performed bacterial challenge test and bubble point test with cells cultured in SLB. Cells grown under agitation conditions in SLB were not retained by 0.2 micron rated membrane filter.     

Method for qualifying microbial removal performance of 0.1 micron rated filters. Part III: bacterial challenge tests on 0.2/0.22 and 0.1 micron rated filter cartridges with Hydrogenophaga (formerly Pseudomonas) pseudoflava.

We have previously reported on the preliminary characterization of Hydrogenophaga (formerly Pseudomonas) pseudoflava for potential use as a standard challenge organism to qualify 0.1 microm rated filters. This article reports on the retention efficiencies of a large panel of 0.2/0.22 microm and 0.1 microm rated filter cartridges for H. pseudoflava (ATCC 700892) versus the retention capabilities of the same filters for Brevundimonas diminuta (ATCC 19146). A total of thirty-two 0.2/0.22 microm rated filter cartridges, spanning nine different "sterilizing grade" filter types from four different filter manufacturers, were challenged with H. pseudoflava at challenge levels exceeding 10(7) cfu/cm2. H. pseudoflava was shown to penetrate every 0.2/0.22 microm rated filter tested, with log titer reduction (LTR) values ranging from 3.5 to 7.7 logs. H. pseudoflava was shown to be more penetrative than B. diminuta under the same challenge conditions. B. diminuta was fully retained by nineteen of the twenty 0.2/0.22 microm rated filters that were challenged with both organisms. In the case of 0.1 microm rated filters, eighteen filter cartridges, spanning five different filter types from three manufacturers were tested. H. pseudoflava was consistently retained by four out of the five filter types tested, with LTR values in excess of 11.5 to 12.2 logs. The 0.1 microm rated filter type that was penetrated by H. pseudoflava has been previously demonstrated to be not fully retentive for naturally occurring bacteria. The data show that H. pseudoflava penetrates 0.2/0.22 microm rated filters just as readily as B. diminuta penetrates 0.45 microm rated filters. In addition, titer reductions provided by 0.2/0.22 microm rated filters for H. pseudoflava are comparable to those reported for A. laidlawii mycoplasma, albeit under different conditions. This study demonstrates that H. pseudoflava meets all criteria for use as a standard organism for qualifying the microbial removal performance of 0.1 microm rated filters for enhanced sterility assurance.     

Method for qualifying microbial removal performance of 0.1 micron rated filters. Part II: preliminary characterization of Hydrogenophaga (formerly Pseudomonas) pseudoflava for use as a standard challenge organism to qualify 0.1 micron rated filters.

In this article, we report on the preliminary characterization of Hydrogenophaga (formerly Pseudomonas) pseudoflava for potential use as a standard challenge organism to qualify 0.1 microm rated filters. Filter-cloned H. pseudoflava (ATCC 700892) was easily cultured in a low nutrient broth (R2A broth) under standard laboratory conditions, reaching high titers of 10(8)-10(9) cfu/mL within 48-65 hours of incubation at 25+/-5 degrees C. Under these conditions, H. pseudoflava is a rod-shaped bacterium, averaging 0.25+/-0.03 microm by 1.65+/-0.35 microm, and appears to be smaller than Brevundimonas diminuta in width (0.31+/-0.03 microm), but somewhat longer in length (0.88+/-0.19 microm), which may partly explain the observed penetration. In total, thirty-five 0.2/0.22 microm rated filter discs, spanning five different "sterilizing grade" filter types from two different filter manufacturers were challenged with H. pseudoflava. In all cases, H. pseudoflava was shown to consistently penetrate every 0.2/0.22 microm rated filter disc tested. These tests also spanned three different challenge durations, including short-term challenges (30-40 minutes), and two different challenge fluids. The use of serial (double) 0.22 mm rated filters, which is a common industry practice to reduce the prefiltration bioburden to the final "sterilizing" filter, was also shown to be inadequate to fully retain H. pseudoflava under the challenge condition used. In contrast, two different 0.1 microm rated filter types functionally qualified with a specified high titer reduction claim for Acholeplasma laidlawii, were shown to consistently and fully retain H. pseudoflava, and retention by these two filter types was shown to be robust and independent of the challenge duration.     

Application of membrane filtration for removal of diminutive bioburden organisms in pharmaceutical products and processes

In this report, we present results of a recent investigation in our laboratories demonstrated the effect of process conditions and/or drug product composition on the ability of 0.2 micron and 0.22 micron sterilizing grade filters to fully retain Ralstonia (formerly Burkholderia, formerly Pseudomonas) pickettii. R. pickettii is a opportunistic pathogen widely distributed in nature as well as clinical specimens and there have been several reports of nosocomial infections due to intrinsic manufacture-related R. pickettii contamination in filter-sterilized parenteral fluids. This study documents the penetration of 0.2 micron nylon 66 and 0.22 micron modified PVDF sterilizing grade filters by R. pickettii (grown and challenged) in a drug solution under conditions that simulated a pharmaceutical filling operation. Penetration was not observed for every filter disc tested, and this may be explained, in part, by the stochastic nature (i.e., governed by the rules of probability) of the retention mechanisms involved. Scanning electron microscopy revealed significant changes in the microorganism's size and morphology as a result of exposure to the drug solution; these changes are consistent with those reported for bacteria subjected to nutrient deprivation. The SEM analyses of R. pickettii challenge suspensions in the drug solution showed that the average cell length decreased from 1.25 +/- 0.27 microns to 0.84 +/- 0.17 micron between zero and 24 hours. In addition, significant changes were observed in the size (length) distributions, with approximately 35% of the cells at 24 hours being smaller than any cell observed at the start of the challenge. These data suggest that the significant reduction in bioburden size and morphology that occurred as a result of exposure to the drug solution may play a role in the reduced ability of the 0.2 micron and 0.22 micron filters tested in this study to retain these organisms. Under the same test conditions where penetration of 0.2/0.22 micron filters was observed, 0.1 micron rated membrane filters qualified with both B. diminuta and Acholeplasma laidlawii mycoplasma consistently provided sterile effluent. Bacterial penetration of 0.2 (or 0.22) micron sterilizing grade filters was not observed under identical test conditions with either R. pickettii in a standardized solution (saline lactose broth) routinely used in challenge testing filters, or with the standard test organism, B. diminuta, in the drug solution. This study thus supports the renewed emphasis on both product- and process specific validation as well as routine bioburden monitoring expressed by regulatory agencies, and the use of enhanced bacterial removal efficiency 0.1 micron rated filters to provide enhanced sterility assurance in pharmaceutical processes.     

Retention of water-borne bacteria by membrane filters. Part I: Bacterial challenge tests on 0.2 and 0.22 micron rated filters

The results of bacterial challenge tests conducted on several 0.2 and 0.22 micron rated "sterilizing grade" filter cartridge types with bacteria from a natural water source are presented. Eight different 0.2/0.22 micron rated "sterilizing grade" filter types from four different filter manufacturers, claimed to be capable of retaining Brevundimonas diminuta at a challenge level of 10(7) CFU/cm2, were tested. The filters tested included nylon 6.6 and polyamide filters from two manufacturers, modified or hydrophilic PVDF filters from two manufacturers, modified or asymmetric PES filters from three manufacturers, and cellulose acetate filters from a single manufacturer. Consistent bacterial penetration was observed, over the 18-24 h challenge period, for all twenty-five integral 0.2 and 0.22 micron rated filter cartridges tested, at challenge levels of about 10(1)-10(4) CFU/cm2, indicating that natural waterborne bacteria were more penetrative than B. diminuta. The observed penetration was thus qualitatively independent of filter media type or manufacturer. These results add to the growing body of evidence that shows 0.2 and 0.22 micron rated filters may not remove all microorganisms under all conditions. These results further establish that bacterial penetration of 0.2/0.22 micron rated filters is not limited just to (1) specific membrane types, or (2) extended duration challenges (> 24 h), or (3) extremely high challenge levels, or (4) bacteria that can only exist in a penetrative state in an artificial laboratory setting.     

Microbial retention characteristics of sterilizing-grade membrane filters with alginate substituted for oil-based products

For oil-based products, FDA recommends substitution of the oil with a compound which has similar viscosity and physical characteristics. In this study, a substitute for oil-based products was screened by measuring the viscosity and filterability, and examined for the presence of cell clumps in the various test fluids using an optical microscopy. The viscosity of the test fluids measured in the range of about 60-75 cP. Brevundimonas diminuta (formerly Pseudomonas diminuta), a standard challenge test organism for validation of 0.2 micron rated membrane filters, formed clumps in oils (corn, olive, sesame, and soybean) and polyethylene glycol (PEG, Molecular Weight (MW) = 400 and 1,000). During the viability test, cells suspended in 80% glycerol showed a ten-fold mortality rate after an exposure for 6 hours, but there was no significant change in viability in alginate (low, medium, and high viscosity) for 24 hours. These results suggested that alginate is better suited as a substitute for oil-based products than 80% glycerol. Since high viscosity fluids take longer to filter, the glycerol mortality rate would influence the challenge test negatively. A scaled-down filtration system has been developed for the described trials, and the bacterial challenge and bubble point tests have been performed in 1.6% alginate (66.7 cP), which was the choice of carrier fluid.     

Method for qualifying microbial removal performance of 0.1 micron rated filters. Part IV: Retention of hydrogenophaga pseudoflava (ATCC 700892) and Ralstonia pickettii (ATCC 700591) by 0.2 and 0.22 micron rated filters

Ralstonia pickettii has emerged as a bioburden microorganism of considerable importance in pharmaceutical processes utilizing conventional 0.2 or 0.22 micron rated "sterilizing grade" filters. In this article, we re-evaluated and studied the retention efficiencies of 0.2 micron rated nylon 6.6 and 0.22 microns rated modified polyvinylidene fluoride (PVDF) filters for Hydrogenophaga pseudoflava (ATCC 700892) and R. pickettii (ATCC 700591). Out of a total of forty-four 0.2/0.22 micron rated filters discs tested in this study (spanning different challenge fluids, different challenge conditions, and different filter types), H. pseudoflava penetration was observed for every filter disc tested. Log titer reduction (LTR) values ranged from 0.3 to 2.0 logs for 20-48 hour challenges conducted in Water for Injection (WFI), and 3.8-7.1 logs for 6-hour challenges conducted in Minimal Media Davis (MMD). For 0.2 micron nylon 6.6 filter discs, penetration by R. pickettii was observed only in WFI challenges and was dependent on the culture and challenge conditions used. Penetration by R. pickettii was also restricted to only those membrane discs that were very close to the filter manufacturer's production integrity test (the Quantitative Bubble Point, QBP, test) limit. Where R. pickettii penetration was observed, LTR values were significantly higher than those observed for H. pseudoflava with the same filter discs. This study: 1) supports the use of H. pseudoflava as a worst-case challenge model for R. pickettii in process- and product-specific bacterial retention testing; 2) provides experimental evidence, for the first time, for the need to include filter membrane lots that have a physical integrity test value at or near the filter manufacturer's production (lower) limit in these tests; and 3) demonstrates how a standardized membrane integrity test (such as the QBP test) can be used select such "worst-case" membranes and to verify the inclusion of such "worst-case" membranes in these tests, thus serving as the link between the membrane disc used in bacterial retention validation testing and the production process filter.     

Retention of water-borne bacteria by membrane filters. Part II: Scanning electron microscopy (SEM) and fatty acid methyl ester (FAME) characterization of bacterial species recovered downstream of 0.2/0.22 micron rated filters

The results of scanning electron microscopic (SEM) and fatty acid methyl ester (FAME) characterization of the bacterial species shown to penetrate conventional 0.2/0.22 micron rated "sterilizing grade" filters are presented. SEM data suggest that retention of bacteria by these filters appears to be strongly influenced by the morphology, and especially the width of bacteria and less so by length. When the bacterial cell width is small, less than 0.3 micron or so, the cell length does not appear to limit the ability to penetrate 0.2/0.22 micron rated filters. As the bacterial width increases, there is also a strong, almost exponential, decrease in the allowable length for penetration, with most penetrative cells tending to be coccoid beyond a width of 0.5 micron. Significant percentages of the bacteria (40-50%) that were observed downstream of these filters were larger than B. diminuta, the standard organism used to qualify 0.2/0.22 micron rated filters. The average sizes of natural waterborne bacteria that penetrated the filters tested were 20-40% larger in width, and 40-70% larger in length, compared to B. diminuta. These results indicate that size exclusion is not the sole mechanism governing bacterial retention. All isolates identified via FAME analyses were common environmental or ubiquitous organisms, and some, such as Acidovorax sp. and Hydrogenophaga pseudoflava, have also been isolated from pharmaceutical water systems. Most of the bacteria recovered downstream of 0.2/0.22 micron rated filters were gram negative, oxidase positive, motile, nonfermentors.     

Retention of water-borne bacteria by membrane filters. Part III: Bacterial challenge tests on 0.1 micron rated filters

Clear performance differences were observed between different 0.1 micron rated filters in terms of their microbial removal efficiency when challenged with naturally occurring waterborne bacteria from a water source. Penetration occurred with three 0.1 micron rated "sterilizing grade" filter types tested, from three different filter manufacturers, that did not have a specific high titer reduction claim for Acholeplasma laidlawii. Bacteria shown to penetrate these 0.1 micron rated filters were quite similar to those recovered downstream of 0.2.0.22 micron rated filters (described in Part II). All of the isolates identified via FAME analyses were common environmental or ubiquitous organisms, and some, such as Acidovorax sp. and Hydrogenophaga pseudoflava, have also been isolated from pharmaceutical water systems. In contrast, four different 0.1 micron rated "sterilizing grade" filter types from two different manufacturers, which had been qualified with both B. diminuta and A. laidlawii, consistently produced sterile effluents under similar test conditions. This study thus highlights the need for an industry or regulatory standard method of defining the microbial removal performance of 0.1 micron rated filters, and supports the use of functionally qualified 0.1 micron rated filters as sterilizing grade filters in pharmaceutical operations for enhanced sterility assurance.     

Impact of tubing material on the failure of product-specific bubble points of sterilizing-grade filters

The following study was conducted to determine the effect of different preservatives commonly used in the biopharmaceutical industry on the product-specific bubble point of sterilizing-grade filters when used to filter product processed with different types of tubing. The preservatives tested were 0.25% phenol, m-cresol, and benzyl alcohol. The tubing tested was Sani-Pure (platinum-cured silicone tubing), Versilic (peroxide-cured silicone tubing), C-Flex, Pharmed, and Cole-Parmer (BioPharm silicone tubing). The product-specific bubble point values of sterilizing grade filters were measured after the recirculation of product through the filter and tubing of different types of materials for a total contact time of 15 h. When silicone tubing was used, the post-recirculation product-specific bubble point was suppressed on average 13 psig when compared to the pre- recirculation product-specific bubble point. Suppression was also observed with C-Flex, but to a much lesser extent than with silicone tubing. Suppression was not observed with Pharmed or BioPharm tubing. Alcohol extractions performed on the filters that experienced suppressed bubble points followed by Fourier transform infrared spectroscopy analysis indicated the filters contained poly(dimethylsiloxane). Direct addition of poly(dimethlysiloxane) to solutions filtered through sterilizing-grade filters suppressed the filter bubble points when tested for integrity. Silicone oils most likely reduced the surface tension of the pores in the membrane, resulting in the ability of air (or nitrogen) to pass more freely through the membrane, causing suppressed bubble point test values. The results of these studies indicate that product-specific bubble point of a filter determined with only product may not reflect the true bubble point for preservative-containing products that are recirculated or contacted with certain tubing for 15 h or greater. In addition, tubing material placed in contact with products containing preservatives should be evaluated for impact to the product-specific bubble point when being utilized with sterilizing-grade filters.     

Method for qualifying microbial removal performance of 0.1 micron rated filters. Part I: characterization of water isolates for potential use as standard challenge organisms to qualify 0.1 micron rated filters.

Although 0.1 microm rated filters intended for pharmaceutical sterilization applications have been commercially available for at least 15 years, there is no industry-wide standard for qualifying the microbial removal performance of these filters. In this article, we report on the bacterial challenge methodology used to screen four bacterial species for potential utility as a standard challenge organism to qualify 0.1 microm rated filters. These isolates were, in their natural state, demonstrated to penetrate 0.2/0.22 microm rated filters in prior studies. In the screening challenges described in this study, three out of these four candidates tested demonstrated consistent penetration of one 0.22 microm rated filter type tested (when cultured in a low nutrient medium under standard laboratory conditions). These included 6204-22 (FAME ID Acidovorax avenae citrulli), 6266-15 (FAME ID Comamonas acidovorans), and 6266-34 (FAME ID Hydrogenophaga pseudoflava). Of these, H. pseudoflava (6266-34) was chosen for additional experiments with other 0.2 microm rated filter membranes. In total, seventeen 0.2 and 0.22 microm rated filter discs, spanning five different "sterilizing grade" filter types from three different filter manufacturers were tested. H. pseudoflava penetration was observed for every filter tested. Under the same challenge conditions, H. pseudoflava was consistently retained by a 0.1 microm rated hydrophilic PVDF (polyvinylidenefluoride) filter with a specified high titer reduction claim for Acholeplasma laidlawii. In order to ensure selection of the most stable penetrative phenotype (i.e., select for nonrevertants), H. pseudoflava was subjected to three rounds of "filter cloning," and these results are described herein. The advantages of using H. pseudoflava for qualifying the microbial removal performance of 0.1 microm rated filters are also discussed.     

Evaluation of the MicroWorks, Inc. Swab Sampling System (MSSSTM) for Use in Performing Quantitative Swab Sampling

The purpose of this study was to qualify the MicroWorks, Inc. Swab Sampling System (MSSS?) swab kit for use in sampling cleanroom surfaces for bioburden. A six-part study was performed to demonstrate the suitability of the swab materials, the recovery of bioburden from typical cleanroom surfaces, the neutralization of typical disinfectants used in cleanrooms, the removal of diluents from the swabbed surface, and the hold time for test samples. A total of 13 challenge organisms were used: six National Collection of Type Cultures/American Type Culture Collection (NCTC/ATCC) standard culture organisms and seven environmental isolates, which were recovered from different MedImmune manufacturing facilities. Based on the results of the study it was shown that 12 of the challenge organisms were recovered from the calcium alginate swab materials and 13 of the challenge organisms were recovered from the sodium citrate diluent at ≥70%. Eleven organisms, including the six NCTC/ATCC organisms and five of the environmental organisms, were recovered from stainless steel, glass, polyvinylchloride curtain material, latex glove material, and neoprene at a rate of ≥70%. Effective neutralization was shown for LpH (an acid phenolic compound manufactured by Steris Corporation, Mentor, OH), Vesphene II, Spor-Klenz, 70% isopropyl alcohol (IPA), and Biocides B, X, and Y when utilizing the filtration/rinsing process. Recovery of six NCTC/ATCC organisms was demonstrated at ≥70%. The study also demonstrated that the diluents could easily be removed from the swabbed surface by following the swab with a 70% IPA wipe. A hold time of at least 24 h was demonstrated when samples were stored at 2-8 °C. The results of this study demonstrated that the MSSS? swab kit and qualified test method recover ≥70% of surface bioburden from common cleanroom surfaces in the presence of a wide variety of disinfectants.     

除菌过滤器验证(四):兼容性验证

兼容性验证是过滤器工艺验证项目之一,以证实工艺及工艺条件对过滤器的特定性能没有产生负面影响。文中介绍了兼容性的概念、兼容性验证的目的和除菌过滤器兼容性验证实验的方法,同时介绍了重复使用过滤器的兼容性验证和同系列药品在兼容性验证中的分组原则。     

Adsorption Behavior of a Surfactant and a Monoclonal Antibody to Sterilizing-Grade Filters

Formulations of therapeutic proteins usually contain a surfactant such as polysorbate 80 to protect them against interfacial stresses. Since surfactants may interact with surfaces, the aim of the present work was to study the adsorption behavior of low concentrations of polysorbate 80 and of a monoclonal antibody during sterile filtration. Lab-scale tests were performed to study the adsorption behavior of a monoclonal antibody to different filter materials (PVDF, PES, CA, and Nylon) from different suppliers. Subsequently, protein and polysorbate 80 adsorption were tested in manufacturing scale experiments. It was found that the extent of protein adsorption differed with filter materials, but also with different suppliers. Prominently, Nylon filters showed the highest degree of protein adsorption. In manufacturing-scale filtration experiments, significant adsorption of polysorbate 80 to sterilizing-grade filters was found. Thus, the adsorption of both protein and polysorbate to filters should be taken into consideration in the formulation and manufacturing process and assessed on a case-by-case basis depending on the manufacturing process set-up.     

除菌过滤器验证(二):除菌效率验证

目前,过滤除菌技术已广泛应用于制药领域。根据药品的特性选择合适的除菌级过滤器,并结合特定的工艺条件对其除菌效率进行充分的验证是保证药品达到相应无菌保证水平的关键和必要条件。本文从过滤除菌工艺的有效性和安全性角度出发,对验证除菌级过滤器除菌效率的3个阶段、验证的必要性、工艺特定验证的原理和方法、最差条件的选择等进行了综述。     

Scaling from discs to pleated devices

Membrane discs offer a convenient format for evaluating membrane performance in normal flow filtration. However, while pleated devices of different sizes tend to scale in close proportion to their contained areas, they do not necessarily scale in direct proportion from flat discs. The objectives of this study are to quantify differences in performance among sterilizing-grade membrane devices as a function of device type and size, to develop an understanding of the factors that affect device scalability, and to develop a mathematical model to predict a cartridge-to-disc scalability factor based on membrane properties and porous support properties and dimensions. Measured and predicted normalized water permeability scalability factors for seven types of pleated cartridges, including 0.1-micro and 0.2-micro rated PES, and 0.2-micro rated polyvinylidene fluoride (PVDF) sterilizing-grade filters in nominal 1-inch to 5-inch lengths, were determined. The results of this study indicate that pleated cartridge performance can be closely predicted based on 47-mm disc performance provided that a number of measured device parameters are properly accounted for, most importantly parasitic pressure losses in the filter device and plumbing connections, intrinsic membrane variability, true effective device filtration area, and the hydraulic properties of all porous support materials. Throughput scalability factors (discs to devices) tend to converge towards unity, especially for highly plugging streams. As the membrane fouls, the resistance through the membrane dominates other resistances, so the flux scales more linearly with membrane area and the overall scaling factor becomes close to one. The results of throughput tests on seven different cartridge types and five different challenge streams (with widely varying fouling characteristics) show that most of the throughput scaling factors were within +/-10% of 1.0. As part of this study, the effects of pressure and temperature were also evaluated. Neither of these factors was found to have a significant effect on scalability.     

Bacterial Retention During Filtration of a Live Attenuated Virus Vaccine Through the Sartobran P Sterile Filter

Recent studies of sterile filtration of a Live Attenuated Virus (LAV) demonstrated that the Sartobran P sterile filter provided 80% yield of a LAV that was 100 – 400 nm in size, raising questions about the effectiveness of this filter in retaining the standard challenge bacterium, Brevundimonas diminuta. This study evaluated the retention of B. diminuta by the Sartobran P over a range of conditions appropriate for LAV filtration. The B. diminuta were characterized by dynamic light scattering (DLS), nanoparticle tracking analysis (NTA), and scanning electron microscopy. The Sartobran P showed complete retention of B. diminuta under all conditions, even in the presence of additives like sucrose, surfactants, and high salt that have previously been hypothesized to increase the risk of bacterial breakthrough. The size of B. diminuta decreased when incubated in the nutrient poor media required by the ASTM challenge test. The addition of sucrose caused a further reduction in size as measured by NTA, although this was due to an increase in cell motility. There was no evidence of bacterial breakthrough at high loadings of either the LAV or B. diminuta, further demonstrating the effectiveness of the Sartobran P for sterile filtration of large viral vaccines.     

Extractables from filter components in model solvent streams for pharmaceutical filtration processes

Drug manufacturers use filters widely in their manufacturing processes for bioburden reduction and sterility assurance. In implementing a pharmaceutical filtration, it is essential to determine and profile the filter extractables that could be introduced into the product. There is an ongoing industry effort to explore the analysis of extractables. Toward this end, the use of complementary analytical techniques was evaluated to aid in extractables identification by determining whether the analysis of filters in the form of components, rather than entire assemblies, facilitated the profiling of extractables. The study examines filter components of 10-inch, 0.22-microm Durapore cartridge filters using Fourier transform infra-red spectroscopy (FTIR) and nuclear magnetic resonance spectroscopy (NMR), as well as determines the non-volatile residues (NVR) and total organic carbon contents (TOC) of the extractables. The complementary techniques of high performance liquid chromatography (HPLC/UV) and liquid chromatography nuclear magnetic resonance spectroscopy (LC/NMR) were also used. The results of the tests indicated very low levels of extractables.     

除菌过滤器验证(三):溶出物/析出物验证

溶出物/析出物的评估是制药领域中除菌过滤器的工艺特定验证的非常重要的组成部分。文中针对溶出物/析出物的验证要求,综述了影响溶出物/析出物水平的工艺参数、溶出物/析出物的验证方法、可能的溶出物/析出物种类等。为制药领域过滤器用户提供参考。     

Biodegradation of DNA and nucleotides to nucleosides and free bases

Thirty-two different microorganisms were examined in order to check their ability to degrade an exogenous DNA. Bacteria from species: Stenotrophomonas maltophilia, Brevundimonas diminuta, Bacillus subtilis, Mycobacterium butyricum and fungus Fusarium moniliforme were capable to degrade DNA to nucleic bases or their derivatives. Degradation of DNA by S. maltophilia resulted in formation of free bases, such as hypoxanthine, thymine, uracil and xanthine. The optimum concentration of DNA seemed to be 3 mg ml(-1). The mode of degradation of DNA nucleotides depended on the type of nucleotide and its concentration, but nucleic bases or their derivatives were always formed at the end of the reaction process.