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New Applications of the Human Whole Blood Pyrogen Assay
______________________________ ~I~-~,c' New Applications of the Human Whole Blood Pyrogen Assay (PyroCheck) Stefan Fennrich, Albrecht Wendel, and Thomas Hartung University of D-Konstanz Summary The absence ofpyrogens in injectable drugs is an indispensable safety control because contaminants causing fever pose a life-threatening risk to the patient resulting in the worst case in death by shock. When fever- inducing agents, i.e.pyrogens, come into contact with the immunocompetent cells in blood, these cells release mediators which transmit the fever signal to the thermoregulatory centre of the brain. The Phamocopoeia lists currently two test systems for pyrogenicity: 1. The in vivo rabbit pyrogen test which measures the fever reaction following injection of the sample to the animals. 2. The in vitro Limulus Amebocyte Lysate assay (IAL) which measures the coagulation in a lysate prepared from the blood of the horseshoe crab specifically initiated by endotoxins, i.e. cell wall components from Gram-negative bacteria. The new test presented here (PyroCheck) exploits the reaction of monocyteslmacrophages for the detection of pyrogens: human whole blood takenfrom healthy volunteers is incubated in the presence of the test sample in any form, be it a solution, a powder or even solid material. Pyrogenic contaminations initiate the release of the "endogenous pyrogen" 1nterleukin1fJ determined by ELlSA after a fixed incubation time. The technology presently listed in the Pharmacopoeia is limited to parenteralia (rabbit test: biologicals and pharmaceuticals, LAL: predominantly pharmaceuticals). In the EU Medical Devices Directivefrom 1995 the rabbit pyrogen test for medical products is in some cases requested. (in some cases IAL of an eluate from the device). However, pyrogentesting needs to cover also innovative high-tech products such as medical devices (implants, medical plastic materials, dialysis machines), cellular therapies and species-specific agents (e.g. recombinant proteins). Here we report that the human blood test PyroCheck is suitable for testing filters in air quality control as well as for assessing medical devices and biocompatibility (dialysate fluid}, i.e. that it can be extended to a wide spectrum of applications. Keywords: 3R, replace, pyrogen test, Limulus Amebocyte endotoxin, pyrogens, medical devices 146 ZusammenJassung: Weitere Anwendungsm6glichkeiten des Pyrogentests mit menschlichem Vollblut (PyroCheck) Die Abwesenheit von Pyrogenen in injizierbaren Armeimitteln (Parenteralia) ist unabdingbar fUr die Patientensicherheit, denn diese [ieberinduzierenden Verunreinigungen stellen fiir den Menschen ein erhebliches Risiko dar. 1m Extremfall bedeuten sie den Tod durch Schock. Im Kontakt mit immunkompetenten Zellen bewirken Pyrogene die Ausschiittung von BotenstofJen, die direkt auf das zentrale Thermoregulationszentrunt im Gehirn einwirken. Die Pharmakopoe schreibt zwei Testsysteme zur Pyrogendetektion vor: 1. Den in vivo Kaninchen-Pyrogen-Test, der nach Injektion der Prufsubstan: die Erhohung der Korpertemperatur ermittelt. 2. Den in vitro Limulus Amobozyten Lysat-Test (IAL), der die Koagulation eines aus dem Blut des Pfeilschwanrkrebses gewonnenen Lysates mifit, ausgelost durch Endotoxin, eines Zellwandbestandteiles Gram-negativer Bakterien. Der hier vorgestellte neue Test (PyroCheck) nutzt zur Detektion die Reaktion von mensch lichen MonozyteniMakrophagen auf Pyrogene: Blut gesunder freiwilliger Spender wird mit der Probe, unabhangig ob es eine Losung, ein Pulver oder irgendein solides Material ist, zusammen inkubiert. Anwesende Pyrogene induzieren die Ausschuitung von "endogenen Pyrogenen" wie Interleukin-1fJ, welches mit dem ELlSA bestimmt wird. Die gegenwiirtig in der Pharmakopoe vorgeschriebene Pyrogentestmethodik ist begrenri auf den Nachweis von Parenteralia (Kaninchen- Test: biologische und pharmazeutische Arzneimittel; LAL: hauptsdchlicb pharmazeutische Arzneimittel). Die Priifung von medizinischen Materialien ist im EU Gesetz fiir Medizinprodukte seit 1995 geregelt und schreibt auch z. T. den Kaninchentest vor (sonst IAL des Eluates eines Materials). Pyrogentestung sollte daruber hinaus innovative high-tech Produkte einschliefJen, wie Medizinprodukte (Implantate, medizinische Materialien, Dialyseprodukte), zellulare Therapeutika und spezifische Therapeutika wie rekombinante Proteine. Hier wird gezeigt, dafJ der humane Pyrogen-Test PyroCheck geeignet ist zur Testung von Filtern zur Qualitiitskontrolle der Luft, sowie Medirinprodukten und zur Prufung auf Biokompatibilitat (Dialyseflussigkeiten}. Es zeigt sich, dafJ diese neue Technik fiir ein sich ausweitendes Anwendungsspektrum praktikabel ist. Lysate Test, human whole blood test, PyroCheck, Interleukin-Ifi, ALTEX 16, 3/99 ~~ FENNRICH ET AL. --~~---------------------------~c' 1 Introduction Immediate recognition of bacterial infection is mandatory for the survival of the hnman organism. Evolution of mankind, therefore, has created a highly sensitive detection system which identifies bacteria and other germs based on those structural components they do not share with the human body. Most effectively, the human system reacts to structures which are highly conserved among different bacterial strains. The most potent stimuli are endotoxins from Gram-negative bacteria. These lipopolysaccharides (LPS) of the outer cell membrane induce a cascade of defense mechanisms known as inflammation and fever. Due to their inherent capability to induce fever, such stimuli are also termed pyrogens (for review see Pearson, 1985). When cells of the immune system, namely blood monocytes and rnacrophages (c.f. title page of this issue of ALTEX), come in contact with pyrogenic contamination, they release mediators which transmit the fever reaction within the organism. The most prominent representative of these endogenous pyrogens is the pro-inflammatory cytokine Interleukin-IB (IL-IE). The new pyrogen test (Hartung and Wendel, 1995, 1996) is based on this principle: The sample to be tested is incubated with a small amount of blood taken from a healthy donor. Any pyrogenic activity, independent of its chemical nature, induces the formation ofIL-IE which can be determined by ELISA. Currently, a national collaborative prevalidation of this test is performed between the University of Konstanz, a Federal Institute and industrial partners. Table 1: Comparison of the application spectra of the rabbit pyrogen test, the Limulus Amebocyte Lysate assay (LAL) and the human whole blood assay (PyroCheck). Tests Principles and Applications Rabbit Priciple of test Detectable pyrogens Applications LAL cytoxine reease (1L-1B) Gram-neg. + + Gram-pes. + Fungi + Biologicals + - Pharmaceuticals + + + Medical Devices - (+) + (+) (+) - + Air quality Blood products blood assay is based. A standardised version of the test in form of a kit (PyroCheck, DPC Biermann, Bad Nauheim) is now commercially available as the result of a successful technology transfer to a industry partner. Preliminary results of the evaluation of feasibility of the test for pharmaceuticals and biologicals have been reported previously (Fennrich et al 1998, 1999). In table 1, the present state of the properties of the human whole blood assay is compared with the ones of the rabbit test and the LAL. It is evident that among the two in vitro tests, Gram-positive and fungal (Zimmermann, 1999) contaminations escape detection by the LAL while the blood assay detects them. Human Fever Reaction + + + + Our current research activities are focussed on expansion of the test to hitherto uncovered gaps of product safety, such as applications to biocompatibility, e.g. of dialysis fluids. A second field encompasses testing of medical devices, e.g. plastics or filters. The goal of this research line was to identify applications that can neither be covered by rabbit pyrogen test nor by the LAL or can replace the animal test in a wider range of applications. One of the characteristics of the whole blood assay is that the direct contact between the relevant cells (monocyte/macrophage) and with the surface of any material of interest is the key event that initiates the signal that is taken as the final readout. In other words, a heterogeneous Rabbit Pyrogen Test 2 Material and methods .../'! pyrogen See earlier publications (Hartung and Wendel, 1995, 1996; Fennrich et al, 1998) For testing medical devices it is easy to bring the diluted whole blood in contact with the material either by moving the material into the blood or by rinsing it with blood. The dilution procedure and the test time are the same as described earlier for testing drugs. human blood tests fever reaction defense mechanism mammal arthropoda ~ test semple leucocyte ~ ~ whole blood FEVER cytoxines (1L-1B) ~ cytoxines (1 L-1 B) ~ ELISA 3 Results Human Py ro 9en Test The diagram in figure 1 illustrates the principle on which the human whole Figure 1: The basic principles of the rabbit pyrogen test and the human whole blood assay PyroCheck. ALTEX 16,3/99 Human Whole Blood 147 _F_ENN __ ~_C_H_E_T_AL_. ~~~ _ .' 0' phase reaction is the basic physicochemical principle of the assay. In contrast, the LAL requires a homogeneous reaction phase, i.e. it is restricted to LPS in soluble form. Hence, the contaminant to be tested has to be eluted from the original test material- a technical complication of the procedure with unknown quantitative doseeffect relationships. A well-known characteristic property of pyrogens is that they tend to firmly attach to material, even test tubes, while in contrast the surface itself can induce the immune system to react. The experiments shown in figure 2 provide evidence that endotoxins soaked into filters and dried are also capable of initiating a concentration-dependent release of IL-l from whole blood. Under these conditions, we blindly tested air filters which were used in the air conditioning of a veterinary facility for sheep. Contaminated filters were identified and later microbiological analysis confirmed this classification (data not shown). These findings suggest that where neither the test material nor the surface can be brought into solution, the blood test is the alternative of choice as an indicator of biohazard. The data shown in figure 3 demonstrate that bacteria and fragments of their membranes can be detected in a very sensitive way with the blood assay, independent of whether they had been killed before by heat or exposed to antibiotics. Taking this into account suggests that such conditions to be tested as contaminants reflect the more realistic situation because crude endotoxins are more likely to be expected in test samples than purified LPS in a sterile environment. 4000 E 3000 OJ So .•.. ~ 2000 1000 ng _ Figure 3: Release of IL-1 B from of the human whole blood initiated by bacteria killed by heat or antibiotics. 4 Discussion The absence of pyrogens (fever inducing contamination) represents an indispensable safety control in products given to patient via a parenteral way.The rabbit pyrogen test has served for drug safety control for more than fifty years (Flint, 1984). Due to improved manufacturing procedures, contaminated end-products have become rare and the adequacy of a test consuming larger animals is doubted. However, the level of safety reached needs to be maintained since infusion or injection of contaminated drugs to often critically ill patients is life-threatening. Innovative high-tech products such as medical devices (implants, medical plastic heat inactivated c::::J treated _live 20000 with peniCillin/streptomycin bacteria ""-e- ~ 10000 n 0 10' 10' 10' 10' Bacteria/ml [x3,24] II 10' II 10' 10' Figure 2: Concentration-dependent release of IL-1B from of the human whole blood initiated by nitrocellulose filters contaminated with defined LPS-concentrations (representative for medical device testing). 148 ~g LPS/filter E. coli: Incubation with human whole blood 30000 ] Cl ~ Medical device testing: IL-1 B-release from whole blood by incubation of NC-filters coated with LPS materials, dialysis machines), cellular therapies and species-specific agents (e.g. recombinant proteins) will continuously expand this product segment in the future. In special prescriptions for medical devices (EU Medical Device Directive) it is regulated to use the rabbit pyrogen test. These are essential parts of DIN-, EN- or ISO standards for testing medical products like syringes, catheters, stylets and machines or parts of them (Zamow and Spielmann, 1998). It is regulated to prepare an eluate that has to be injected into the rabbit, like the classical pyrogen test claim it. The possibility of testing cell culture plastic material directly by exposing it to human blood was shown in a collaboration with a industrial partner and will be first demonstrated on the 3rd world congress on alternatives and animal use in the life sciences in Bologna 1999. Taken together, it seems possible to reduce or replace the rabbit test in the regulation (DIN, EN, ISO). On the other hand, the blood test is much more versatile than the in vivo rabbit test with respect to applications to medical devices, blood products and air quality. These applications demonstrate the putative use of the blood test in the control of biological hazards in e.g. aircraft or hospital ventilation systems. Further applications include air quality control during work in waste recycling, or microbiological air quality assessment in animal mass production facilities. ALTEX 16, 3/99 r:"\ FENNRICH ET AL. --~----------------------------------For most biologicals, especially blood-derived drugs, the rabbit animal experiment still represents the only choice at an annual expense of hundreds of thousands of animals in the European Union. In addition, this test is laborious and expensive. However, for new therapies such as recombinant human proteins or cellular therapeutics, the rabbit assay is not applicable because in many cases false-positive results will be obtained due to the speciesspecificity of the immunological recognition of these agents. The only in vitro alternative presently available, the Limulus amebocyte lysate test, which is based on the coagulation of horseshoe crab blood, detects only one class of pyrogens - endotoxins (lipopolysaccharides, LPS) from Gram-negative bacteria - leaving patients at risk originating from undetected "nonendotoxin" pyrogens such as Gram-positive bacterial toxins, viruses and fungi (Diamond, 1989; Kayser, 1998). Thus, only an assay based on the human fever reaction will close these "safety gaps". The introduction ofthis kit version enables international availability, distribution of the methodology and interlaboratory comparisons. It was very helpful, to use this version inside of the prevalidation network and the feedback of experience with this method was included in the test procedure for all participants. In recent years, several alternative cellular assays have been suggested in order to replace the rabbit test and offer testing in the relevant species (man) (Eperon, 1997; Gommer, Peterbauer, 1999; Poole, 1988; Taktak, 1991; Werner, 1998; Werner-Pelmayer, 1995). All of them are based upon the response of human leukocytes (principally monocytes), which release inflammatory mediators (endogenous pyrogens) in response to pyrogenic contamination (exogenous pyrogens). However, the cell-based in vitro assay systems differ with regard to the cells employed (isolated primary blood leukocytes or whole blood or immortalised monocyte cell lines), the mediator determined (interleukin-I, interleukin-6, tumor necrosis factor, neopterin, or NO) and the precise set-up of the test. Using human blood implies considerably simplified handling, reliability and reproducibility of the assay. Now, this blood test will be evaluated in comparison to the other human cell approaches. ALTEX 16, 3/99 References Diamond, R. D. (1989). Immune Response to Fungal Infection. Rev Infect Dis, I1 Suppl 7,1600-1604. Eperon, S., DeGroote, D., Werner-Felrnayer, G., and Jungi, T. (1997).Hurnanmonocytoid cell lines as indicators of endotoxin: comparison with rabbit pyrogen and Limulus amebocyte lysate assay. 1. Immunol. Meth. 207,135-145. Fennrich, S., Fischer, M., Hartung, T., Lexa, P., Montag-Lessing, T., Sonntag, H. G., Weigandt, M. und Wendel, A. (1998). Entwicklung und Evaluierung eines Pyrogentests mit menschlichem Blut. ALTEX 15, 123-128. Fennrich, S., Fischer, M., Hartung, T., Lexa, P., Montag, T., Sonntag, H. G., Weigandt, M., and Wendel, A. (1999). Detection of endotoxins and otherpyrogens using human whole blood. Dev. Biol. Stand., in press. Flint, O. (1984). A timetable for replacing, reducing and refining animal use with the help of in vitro tests: the Limulus amebocyte lysate test (LAL) as an example. meA. Reinhardt (ed.), Alternatives to Animal Testing: New WCO'sin the Biomedical Science, Trends and Progress (27-43). Weinheim: VCH. Gommer, A. M., and Donders, L. A. M.: An investigation of the possibility to replace the rabbit pyrogen test by an in vitro test. RIVM report 319006003. Hartung, T. und Wendel, A. (1995). Die Erfassung von Pyrogenen in einem humanen Vollblutrnodell. ALTEX 12, 70-75. Hartung, T., Sauer, A., and Wendel, A. (1996). Testing ofImmunomodulatory Properties in Vitro. Dev. BioI. Stand. 86, 85-96. Hartung, T., and Wendel, A. (1996). Detection of Pyrogens Using Human Whole Blood. In VItro Toxicology 9,353-359. Kayser, F. H., Bienz, K. A., Eckert, J. und Zinkernagel, R. M. (1998). Medizinische Mikrobiologie. Stuttgart: Thieme. Pearson, C. F., III (1985). Endotoxins, LAL Testing, and Depyrogenation. In 1. R. Robinson (ed.), Pyrogens (3-272). New York and Basel: Marcel Dekker, Inc. Peterbauer, A., Werner, E. R. und Werner-Felmayer, G. (1999). Weiterentwicklung eines Zellkulturmodells zum Nachweis bakterieller Pyrogene. ALTEX 16, 3-8. Poole, S., Thorpe, R., Meager, A., Hubbard, A. R., and Gearing, A. J. H. (1988). Detection of pyrogen by cytokine release. Lancet, 8577,130. Taktak, Y S., Selkirk, S., Bristow, A. F., Car- penter, A., Ball, C., Rafferty, B., and Poole, S. (1991). Assay of pyrogens by interleukin-6 release from monocytic cell lines. 1. Pharm. Pharmacol., 43,578-582. Wemer, E. R., Werner-Felrnayer, G., and Mayer, B. (1998). Tetrahydrobiopterin, cytokines and nitric oxide synthesis. Proc. Soc. Exp. Biol. Med. 219, 171-182. Wemer-Felmayer, G., Baier-Bitterlich, G., Fuchs, D., Hausen, A., MUlT,C, Reibnegger, G., Werner, E. R., and Wachter, H. (1995). Detection of bacterial pyrogens on the basis of their effects on gamma interferon-mediated formation of neopterin or nitrite in cultured monocyte cell lines. Clin. Diagn. Lab. Immunol.,307-313. Zamow, Katharina und Spielmann, H. (1998). Moglichkeiten zur Reduzierung oder zum Ersatz von Tierversuchen, die in DIN-Normen vorgeschriebensindAL7EX15, 129-140. Zimmermann, Melanie (1999). Immunakiivierung durch Pilze am Beispiel der Zytokininduktion durch Candida albicans und Aspergillus niger. Universitat Konstanz, Fakultat fur Biologie, Diplomarbeit. Acknowledgements A national collaborative prevalidation of this test is performed between the University of Konstanz, the Paul-Ehrlich-Insitut (Langen), the University of Heidelberg and some the commercial enterprises Centeon (Marburg), Biotest (Dreieich), PharmaHameln (Hameln), Phytos (Neu-Ulm) and Biochem (Karlsruhe). Sponsored by the German Minister of Education, Science, Research and Technology (BMBF) the suitability of the new method to replace the rabbit pyrogen test for biologicals is currently evaluated. In addition, an evaluation of the test for pharmaceuticals sponsored by Boehringer Mannheim on behalf of the European Pharmakopoea is presently carried out. A standardised version of the test in form of a kit (PyroCheck) is now commercially available by DPC Biermann, Bad Nauheim, Germany. The fruitful help and technical assistance of Astrid Leja, Dona Kindinger and Gregor Pinski are gratefully acknowledged. Correspondence to Dr. Dr. Thomas Hartung University of Konstanz Biochemical Pharmacology P.O. Box M 668 D-78457 Konstanz 149
