Effects of physical and chemical factors on pseudorabies virus activity in vitro.

BACKGROUND: Pseudorabies (PR) is latent and can persist in infected sows for a long time, and thus, convalescent sows can carry the virus throughout life, causing severe economic losses to farmers and posing a tremendous challenge to PR prevention and control. Here, to investigate the biological characteristics of pseudorabies virus (PRV), a variety of physical and chemical factors were analyzed under controlled conditions. RESULTS: The results showed that a high ambient temperature and dry environment led to faster virus inactivation. PRV had a certain resistance to weakly acidic or alkaline environments and was rapidly inactivated in strongly acidic or alkaline environments. The effect of ultraviolet (UV) radiation on PRV activity primarily depended on the frequency, intensity, and irradiation time of the UV exposure. Exposure to sunlight inactivated PRV via multiple factors, including temperature, sunlight intensity, UV intensity, and environmental humidity, and any shielding from sunlight strongly lowered the killing effect. Conventional disinfectants had a good disinfection effect on PRV. CONCLUSIONS: The biological characteristics of different PRV strains are variable. Generally, the activity of PRV is affected by multiple factors, which can show both synergy and antagonism. Real-world conditions should be taken into consideration to guide pork production.

Effect of increased agitation speed on pathogen inactivation efficacy and in vitro quality in UVC-treated platelet concentrates.

BACKGROUND AND OBJECTIVES: Pathogen inactivation technologies require continuous development for adjustment to different blood components and products. With Theraflex UV-Platelets, a system using shortwave ultraviolet C (UVC) light (254 nm), efficient mixing of platelet concentrates (PCs) during UVC treatment is essential to ensure homogeneous illumination of the blood components. In this study, we investigated the impact of increasing the agitation speed during UVC treatment on pathogen inactivation capacity and platelet quality. MATERIAL AND METHODS: The pathogen inactivation efficacy of UVC treatment was evaluated at two agitation speeds (110 vs. 180 rpm) using four different transfusion-relevant bacteria strains and three model viruses. Using a pool-and-split design, the in vitro quality of buffy coat-derived PCs stored in SSP+ additive solution for up to 7 days was assessed in UVC-treated PCs agitated at either 110 rpm (standard speed) or 180 rpm (increased speed) and in untreated controls. RESULTS: The higher agitation speed improved bacterial inactivation but did not influence viral inactivation. Metabolic activity (glucose consumption and lactate accumulation) in UVC-treated platelets was slightly higher than in untreated controls. Increases in parameters such as CD62P expression and annexin A5 binding indicated moderate activation of UVC-treated platelets. Quality variables for UVC-treated platelets agitated at standard vs. increased agitation speed were comparable. CONCLUSION: The mixing rate during illumination may be a process parameter for further development of UVC-based pathogen inactivation procedures for PLT concentrates.

[Technical study on inactivating/removing virus in collagen sponge].

OBJECTIVE: To verify the technics of inactivating/removing virus in collagen sponge derived from bovine Achilles tendon. METHODS: Possible pathogen species were determined according to the raw material of bovine Achilles tendon used in production, then vesicular stomatitis virus (VSV), theiler's mouse encephalomyelitis virus (TEMV), pseudorabies virus (PRV), and simian vacuolating virus 40 (SV40) were selected as indicator virus. Virus suspension was prepared in accordance with Technical Standard for Disinfection. 60Co radiation 25 kGy of collagen sponge was determined as inactivating/removing virus process according to the analysis of the manufacture process, the virus inactivation/removal effect was verified by the measurement of median tissue culture infective dose (TCID50) and showed by virus reduction factor (sample average values of numerical difference before and after processing). RESULTS: Reduction factors of VSV, TEMV, PRV, and SV40 after 60Co radiation 25 kGy were 5.646, 4.792, 5.042, and 5.292 logTCID50/0.1 mL (logs), respectively. Reduction factor of each indicator virus was greater than 4 logs, showing that 60Co irradiation 25 kGy can effectively inactivate and remove viruses. CONCLUSION: 60Co radiation 25 kGy of collagen sponge derived from bovine Achilles tendon can be used as the technics of inactivating/removing virus during the preparation process of collagen sponge to guarantee the safety of the product.

Additive effects of dipyridamole and Trolox in protecting human red cells during photodynamic treatment.

BACKGROUND AND OBJECTIVES: Photodynamic treatment (PDT) of red blood cell (RBC) suspensions has been reported to result in virus inactivation, but also in deterioration of cell quality. Recently, we have demonstrated the potential usefulness of the reactive oxygen species scavenger dipyridamole in selectively protecting RBCs against the harmful side-effects of PDT. Unfortunately, dipyridamole-conferred protection against long-term photohaemolysis was incomplete. In the present study, dipyridamole was applied in combination with Trolox (a hydrophilic vitamin E analogue) in order to augment RBC protection. MATERIALS AND METHODS: Leucodepleted RBC suspensions (30% haematocrit) were treated with 1,9-dimethylmethylene blue (DMMB) and red light, and the effect of inclusion of dipyridamole and Trolox was assessed on potassium leakage as well as on short-term and long-term photohaemolysis. Possible interference of the scavenger cocktail with virus inactivation was examined using extracellular pseudorabies virus (PRV). RESULTS: Treatment of RBC with DMMB and red light resulted in enhanced potassium leakage and both short- and long-term haemolysis. Dipyridamole and Trolox showed additive protective effects against induction of potassium leakage and photohaemolysis, suggesting different protection mechanisms for the two scavengers. Combined inclusion of dipyridamole and Trolox did not interfere with efficacy of PRV inactivation. CONCLUSIONS: Combined inclusion of dipyridamole and Trolox results in substantially improved selectivity of photodynamic treatment of RBC suspensions.

The band III ligand dipyridamole protects human RBCs during photodynamic treatment while extracellular virus inactivation is not affected.

BACKGROUND: Recently, the potential usefulness of dipyridamole (DIP) in protecting RBCs against the harmful side effects of photodynamic sterilization was demonstrated. In the present study, the use of DIP for selective protection of RBCs was investigated under conditions more relevant for blood bank practice. STUDY DESIGN AND METHODS: WBC-reduced RBC suspensions (30% Hct) were treated with 1,9-dimethylmethylene blue and red light, and the influence of the inclusion of DIP on photohemolysis was assessed as a function of sensitizer concentration, light dose, and storage time. Furthermore, the possible interference of DIP with inactivation of extracellular virus by use of a panel of different viruses (HIV-1, pseudorabies virus [PRV], bovine viral diarrhea virus [BVDV], VSV, encephalomyocarditis, and canine parvovirus) was investigated. RESULTS: In WBC-reduced RBC suspensions (30% Hct), DIP exerted a clear protective effect against photohemolysis. Part of this protection was achieved with concentrations near the dissociation constant for band III binding. Importantly, efficiency of inactivation of extracellular HIV-1, PRV, BVDV, and VSV was not significantly impaired by the inclusion of DIP. Phototreatment conditions, resulting in a 4 to 5 log inactivation of extracellular HIV-1 and PRV, resulted in a high level of hemolysis after 28 days of storage. This long-term hemolysis could be decreased, but not completely prevented, by the inclusion of DIP. CONCLUSION: Photohemolysis in RBC concentrates can be reduced substantially by the application of DIP, while the efficacy of inactivation of HIV-1 and other viruses remains unchanged.

Effect of gamma irradiation on human cortical bone transplants contaminated with enveloped and non-enveloped viruses.

In the production of bone grafts intended for transplantation, basic safety measures to avoid the transmission of pathogens are selection and serological screening of donors for markers of virus infections. As an additional safety tool we investigated the effect of gamma irradiation on the sterility of human bone diaphysis transplants and evaluated its impact on the virus safety of transplants. Model viruses were included in the study to determine the dose necessary to achieve a reduction factor for the infectivity titres of at least 4 log(10) at a temperature of -30+/-5 degrees C. The following viruses were used: human immunodeficiency virus type 2 (HIV-2), hepatitis A virus (HAV), and poliovirus (PV-1), and the following model viruses: pseudorabies virus (PRV) as a model for human herpesviruses, bovine viral diarrhoea virus (BVDV) for HCV, and bovine parvovirus (BPV) for parvovirus B19. A first approach was to determine the D(10) values (kGy) for the different viruses (virus inactivation kinetics: BPV 7.3; PV-1 7.1; HIV-2 7.1; HAV 5.3; PRV 5.3; BVDV <3.0 kGy). Based on these results, inactivation of these viruses was studied in experimentally contaminated human bone transplants (femoral diaphyses). For BPV, the most resistant one of the viruses studied, a dose of approximately 34 kGy was necessary to achieve a reduction of infectivity titres of 4 log(10). We therefore recommend a dose of 34 kGy for the sterilisation of frozen bone transplants.

Suppression of the proliferation of mouse splenocytes by pseudorabies virus.

Pseudorabies virus (PRV) infection in resistant swine caused immunosuppression which sometimes resulted in secondary infection by other viruses or bacteria. However the mechanism of the immunosuppression is not well understood. In this study, the effect of PRV on the immune system was examined in the mouse model. Splenocytes or lymphocytes prepared from the spleen of BALB/c mice were incubated in vitro with mitogen, and the ability of cells to proliferation was measured. When the cells were incubated with PRV, the ability of cells to proliferate was inhibited, although PRV did not multiply in the lymphocytes. UV-inactivated PRV also suppressed the proliferation of mice splenocyte. This result suggests that the structural component of PRV virion might cause the immunosuppression.

Preservation of red cell properties after virucidal phototreatment with dimethylmethylene blue.

BACKGROUND: All published reports have described methods for virus photoinactivation which significantly alter red cell (RBC) properties during storage. In order to improve virucidal activity and reduce damage to RBCs, a series of phenothiazine derivatives were either synthesized or purified and screened for bacteriophage inactivation and red cell potassium efflux. One compound, 1,9-dimethylmethylene blue (dimethyl-methylene blue), had superior screening results and was chosen for further characterization. STUDY DESIGN AND METHODS: White cell reduced RBC suspensions (30% hematocrit) were deliberately inoculated with extracellular virus or virus-infected VERO cells, incubated with 4 microM dimethyl-methylene blue and illuminated with cool-white fluorescent light. Control and treated samples were titered for virus inactivation. In parallel studies, RBC suspensions were exposed to dimethylmethylene blue and light under identical conditions and assayed for in vitro RBC storage properties. RESULTS: Phototreatment of RBC suspensions inactivated > 4.4 log10 of extracellular vesicular stomatitis virus (VSV), > 3.0 log10 of intracellular VSV, > 5.0 log10 of extracellular pseudorabies virus (PRV), > 4.8 log10 of intracellular PRV, > 4.7 log10 of extra-cellular bovine virus diarrhea virus, 5.8 log10 of bacterio-phage phi 6 and > 7 log10 of bacteriophage R17. Encephalo-myocarditis virus, a nonenveloped picornavirus, was resistant to photoinactivation. Virucidal conditions resulted in no detectable IgG binding in 11 of 13 samples, unchanged RBC morphology, normal banding patterns of RBC membrane proteins on SDS PAGE, and unaltered characteristics of 12 of 13 RBC antigens during storage as measured by antibody titrations. In addition, minimal changes were observed in RBC osmotic fragility, lysis, potassium efflux, ATP and 2,3-DPG levels, and the strength of one RBC antigen during storage of phototreated samples compared with controls. CONCLUSION: Dimethylmethylene blue photo-treatment can inactivate several intracellular and extracellular model viruses under conditions which minimally alter RBC properties during 42 days storage at 1-6 degrees C.

Inactivation of viruses by chemically and photochemically generated singlet molecular oxygen.

Inactivation of viruses in blood plasma can be achieved by photodynamic procedures using methylene blue (MB) or other photoactive dyes. Singlet molecular oxygen (1O2) probably contributes to the virucidal effects of photosensitization. We report the inactivation of herpes simplex virus type 1 (HSV-1) and suid herpes virus type 1 (SHV-1) by chemically generated singlet oxygen, produced by thermal decomposition of the endoperoxide of 3,3'-(1,4-naphthylidene)dipropionate (NDPO2). We demonstrate that viruses can be inactivated by 1O2 generated by chemiexcitation in a reaction in the dark, even in the presence of human plasma. Virus inactivation in phosphate-buffered saline (PBS) was enhanced when water was replaced by deuterium oxide (D2O) and diminished when human plasma or quenchers (imidazole or histidine) were added. The singlet oxygen quenching activities of plasma, imidazole and histidine correlated with their inhibitory effects on virus inactivation. The production of 1O2 was assessed by an indicator reaction: the bleaching of p-nitrosodimethylaniline (RNO) with imidazole as 1O2 acceptor. Virus inactivation and singlet oxygen generation of NDPO2 were compared with those of MB/light-mediated photosensitization. Based on similar amounts of 1O2 generated by either procedure, virus inactivation by MB/light was more effective. Virus inactivation by MB/light was not affected by type I quenchers (e.g. mannitol), but was inhibited by human plasma or singlet oxygen quenchers. Furthermore, in D2O-based PBS, virus inactivation was more effective than that in H2O. These observations confirm that singlet oxygen is involved in virus inactivation by MB/light. Taken together, the results demonstrate that singlet oxygen produced by either procedure is virucidal. The enhanced effect of the photochemical procedure suggests that, in addition to type II, type I reactions and/or the binding affinity of the dye for the virus contribute to virus killing by MB/light.

Herpes simplex virus type 1 and pseudorabies virus bind to a common saturable receptor on Vero cells that is not heparan sulfate.

Herpes simplex virus type 1 (HSV-1) and pseudorabies virus (PRV) infect different natural hosts but are very similar in structure, replicative cycle, and entry into cultured cells. We determined whether HSV-1 and PRV use the same cellular components during entry into Vero cells, which are highly susceptible to each virus but are not from native hosts for either. UV-inactivated virions of either HSV-1 or PRV could saturate cell surfaces to block infection of challenge HSV-1 or PRV. In the presence of saturating levels for infection of either virus, radiolabeled virus bound well and in a heparin-sensitive manner. This result shows that heparan sulfate proteoglycans on Vero cells are not the limiting cellular component. To identify the virus component required for blocking, we used an HSV-1 null mutant virus lacking gB, gD, or gH as blocking virus. Virions lacking gB were able to block infection of challenge virus to the same level as did virus containing gB. In contrast, virions lacking gD lost all and most of the ability to block infection of HSV-1 and PRV, respectively. HSV-1 lacking gH and PRV lacking gp50 also were less competent in blocking infection of challenge virus. We conclude that HSV-1 and PRV bind to a common receptor for infection of Vero cells. Although both viruses bind a heparin-like cell component on many cells, including Vero cells, they also attach to a different and limited cell surface component that is bound at least by HSV-1 gD and possibly gH and to some degree by PRV gp50 but not gB. These results clearly demonstrate binding of both HSV-1 and PRV to a common cell receptor that is not heparan sulfate and demonstrate that several types of attachment occur for both viruses during infectious entry.

Testing of cyclophosphamide and diethylstilbestrol for their ability to enhance virus survival in normal human cells.

A relatively simple assay for determining the capability of chemicals to induce the reactivation of UV-irradiated pseudorabies virus in human embryo cells is presented. Using this assay cyclophosphamide (CP) and diethylstilbestrol (DES) were tested in the presence and in the absence of exogenous metabolizing system. N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) was used for comparison. CP increased the survival of UV-irradiated pseudorabies virus exclusively in the presence of exogenous metabolizing system. In the cells pretreated with CP or MNNG the survival of the virus was dependent on time interval between host cell pretreatment and virus infection. No enhancement of virus survival was obtained in the cells pretreated with DES.

Possible role of aphidicolin-sensitive DNA polymerase(s) in N-methyl-N'-nitro-N-nitrosoguanidine and bleomycin induced cellular repair synthesis and virus reactivation.

Treatment of human embryonic cell line CLV 102 with N-methyl-N'-nitro-N-nitrosoguanidine or bleomycin was used to induce DNA repair synthesis. Both the repair synthesis induced by these agents and reactivation of UV-damaged pseudorabies virus were inhibited by aphidicolin.

The phosphorylation of ribosomal protein S6 in hamster fibroblasts infected with pseudorabies virus inactivated by ultraviolet radiation.

Infection of baby hamster fibroblasts with pseudorabies virus at high multiplicities resulted in a substantial increase in the phosphorylation of ribosomal protein S6. However, the phosphorylation was still observed with virus that had been completely inactivated by u.v. irradiation. We therefore conclude that expression of the viral genome is not required for the virus to elicit this effect.

Photodynamic inactivation of pseudorabies virus with methylene blue dye, light, and electricity.

Pseudorabies virus was photoinactivated with a combination of methylene blue dye, light, and electricity. Viral suspensions were mixed with variable amounts of methylene blue dye and then were placed in a current source apparatus. Total inactivation of pseudorabies virus (1.7 X 10(6) 50% tissue culture infective doses per ml) was achieved with constant mixing, a methylene blue dye concentration of 10(-4) M, and an electrical current of 12 microA for 12 min.

Inactivation by gamma irradiation of animal viruses in simulated laboratory effluent.

Several animal viruses were treated with gamma radiation from a 60Co source under conditions which might be found in effluent from an animal disease laboratory. Swine vesicular disease virus, vesicular stomatitis virus, and blue-tongue virus were irradiated in tissues from experimentally infected animals. Pseudorabies virus, fowl plague virus, swine vesicular disease virus, and vesicular stomatitis virus were irradiated in liquid animal feces. All were tested in animals and in vitro. The D10 values, that is, the doses required to reduce infectivity by 1 log10, were not apparently different from those expected from predictions based on other data and theoretical considerations. The existence of the viruses in pieces of tissue or in liquid feces made no difference in the efficacy of the gamma radiation for inactivating them. Under the "worst case" conditions (most protective for virus) simulated in this study, no infectious agents would survive 4.0 Mrads.

Influence of environmental factors upon the survival of Aujeszky's disease virus.

The survival of Aujeszky's disease (pseudorabies) virus outside the living host was found to be dependent on pH level and temperature. Virus inactivation occurred at a rate varying from 0.04 log10 per day at 4 degrees C to 0.6 log10 per day at 37 degrees C at the optimum pH levels of 6 to 8. Fluctuation of the temperature between 4 degrees C and 37 degrees C had no apparent effect upon the titre of the virus. At a steady temperature of -13 degrees C, the virus was rapidly inactivated at all tested pH levels. For long-term storage it is recommended that the pH should be adjusted to between 6 and 7, that suspensions should be kept at -90 degrees C and that freezing and thawing should be rapid so as to pass through the just subzero temperature zone as quickly as possible. Drying, both on glass and on gelatin, caused inactivation of the virus at all pH levels, as did exposure to ultraviolet light.

[Resistance of the Aujeszky's disease virus to gamma ray irradiation]. / Prouchvaniia vurkhu ustoichivostta na virusa na bolestta na Aueski pri obluchvane s gama-luchi.

Investigations on the resistance of Aujeszky's disease virus to gamma irradiation from a 60Co source were performed. The resistance of the virus was tested in vitro in a fluid medium of 50% Henk's balanced saline solution, 50% Eagle's medium MEM and a supplement of 10% normal calf serum as well as its resistance on artificially virus infected pig skin and greasy wool of sheep. It is established that virus inactivation in the fluid medium occurs following 1.6 Mrad gamma irradiation. The irradiated with lower than 1.6 Mrad gamma doses live virus particles form smaller than and with irregular oval shape and dentated plates as compared to the non-irradiated control virus. 1.5 Mrad gamma rays are needed to inactivate the virus on pig skin and greasy wheep's wool. The presence of lanoline in greasy sheep's wool, due to the alkaline pH (9--13) it produces, has an effect on the vitality of the virus both in the control and in the experimental samples.

Comparison of pseudorabies virus inactivated by bromo-ethylene-imine, 60Co irradiation, and acridine dye in immune assay systems.

Pseudorabies virus infections among animals, especially swine, have become prevalent in the United States in the past few years. The disease in swine is now economically important. Test systems and antigens are being developed for use in control and disease suppression efforts. Pseudorabies virus was inactivated by three methods: chemically, with bromo-ethylene-imine; physically, with 60Co irradiation; and chemically and physically, with 3,9-diaminoacridine dye followed by exposure to white visible light. The antigenicities of the preparations were determined in the presence of specific antibody in immunodiffusion tests and through immunoelectrophoresis. The latter technique permitted quantitation of either antigen or antibody. In the electrophoretic patterns, the antigenic mass in bromo-ethylene-imine preparations was estimated to be 42 mg/ml, the same as in the untreated control material. After 60Co irradiation, 22 mg/ml was present, in comparison with 50 mg/ml in the untreated control antigen. In contrast, 67 mg/ml was present in the acridine dye-light-treated preparation, in comparison with 58 mg/ml in the untreated control material. A possible explanation for the acridine dye-light-treated preparation values is that photodynamic inactivation interferes with viral maturation during the replicative cycle within cells, with a resulting production of a greater amount of antigen, at least some of which is in the form of defective particles.