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1.IntroductionEmerging viral pathogens are a constant and prominent threat to human health worldwide, as evidenced by the recent outbreak of severe acute respiratory syndrome (SARS), Middle East respiratory syndrome (MERS) coronaviruses, and novel influenza strains with pandemic potential. In addition, there is a persistent risk of engineered viruses derived from bioterrorism. The most logical and cost-effective strategy to protect the human population from these emerging viral diseases is through immunization. Thus, there is a dire need for rapid methods to develop vaccines in response to new viral pathogens. Whole inactivated virus (WIV) vaccines represent an ideal strategy for this purpose. In contrast to subunit or recombinant vector vaccines, WIV vaccines circumvent the need to identify relevant antigens and can be quickly produced from purified virus using chemical or physical inactivation methods. WIV vaccines contain many of the immunogenic epitopes and immunostimulatory components (such as toll-like receptor ligands) that are needed for an effective virus-specific immune response. Unfortunately, a general method for producing safe and immunogenic WIV vaccines is lacking. Formalin, an alkylating agent, is one of the most extensively used methods for virus inactivation in the manufacture of vaccines.1,2 However, formalin treatment has several crucial limitations: (1) it causes structural damage to B-cell epitopes, which reduces the specificity of antibody responses elicited by the vaccine;3 (2) it generates carbonyl groups in proteins,4 a form of oxidative damage that induces harmful and undesirable T helper type 2 (Th2) -biased immune responses;5 and (3) it adds unnecessary cost and public concern by introducing a carcinogen into the vaccine. These limitations can be seen in the failure of formalin-inactivated respiratory syncytial virus and measles vaccines, which caused disastrous worsening of the disease upon natural infection.6–9 Alternative methods for virus inactivation, including other alkylating agents, heat, ultraviolet (UV) light, and gamma radiation, all suffer from various combinations of the abovementioned limitations.10–13 Recently, a novel method for pathogen inactivation using visible ultrashort pulsed (USP) lasers has been reported (Ref. 14). Visible USP laser treatment inactivates viruses through a physical mechanism: the impulsive stimulated Raman scattering (ISRS) process.15,16 There are several theoretical reasons why USP lasers would be advantageous over other methods for WIV vaccine production. Visible light (in the wavelength range of 400 to 700 nm) lacks the photon energy to disrupt covalent bonds in biological macromolecules such as viruses; therefore, USP laser irradiation should not generate Th2 response-inducing carbonyl groups in proteins. In the absence of chromophores, visible light shows negligible intrinsic absorption by proteins and nucleic acids; thus, USP laser irradiation should not denature structural B-cell epitopes through heating. In addition, USP laser irradiation does not induce protein–nucleic acid crosslinking; hence, the TLR-stimulating capacity of viral nucleic acids should be preserved. Furthermore, the USP laser method does not involve introducing any potentially toxic or carcinogenic chemicals during treatment and would alleviate public concerns in those regard. These rationales make the USP laser treatment an attractive potential method to generate safe and effective WIV vaccines. In this paper, we demonstrate that immunization of mice with the USP laser-inactivated whole inactivated H1N1 influenza virus at about a 10-fold lower dose than that required by conventionally formalin-inactivated H1N1 vaccine results in protection against lethal-dose H1N1 influenza challenge. Splenocytes extracted from mice vaccinated with the USP laser-inactivated virus showed an enhanced influenza-specific cytotoxic T-cell (CTL) response compared with those from unvaccinated mice. In addition, we employed a neutralization assay to confirm the presence of neutralizing antibodies. We demonstrate through hemagglutination assay that the USP laser irradiation has no effect on the surface protein structure of the virus. Furthermore, we have evaluated the effects of USP laser–treatment on a model protein—bovine serum albumin (BSA). We have found that, in contrast to conventional pathogen inactivation methods, the USP laser treatment did not generate Th2 response-inducing carbonyl groups in BSA protein. Therefore, USP laser treatment is a novel and an attractive potential strategy to generate WIV vaccines with greater potency and safety than vaccines produced by current inactivation techniques. 2.Materials and Methods2.1.MiceFemale BALB/c mice (8 weeks old) were obtained from the National Cancer Institute (Bethesda, Maryland). The mice were kept in a pathogen-free environment at Johns Hopkins University (Baltimore, Maryland). 2.2.CellsMadin-Darby canine Kidney (MDCK) cells, obtained from ATCC (Manassas, Virginia), were used for all in vitro assays. Cells were grown in Dulbecco’s modified Eagle’s medium (DMEM) with L-glutamine and 10% FBS at 37°C with 5% . 2.3.VirusThe strain of virus used in this study was A/PR/8/34 (H1N1) from ATCC (Manassas, Virginia). The virus was first grown in MDCK host cells. After centrifugation at for 10 min at 4°C, the cell debris was removed. The remaining virus particles were then concentrated by centrifugation at for 1 h at 4°C through a 20% sucrose cushion in phosphate buffered saline (PBS). The virus was stored in aliquots at . The titer of the virus was measured by the tissue culture infectious dose-50 () assay.17 For the assay, MDCK cells were plated on a 96-well plate. The virus was added in 10-fold dilutions using infection media (DMEM with N-acetylated trypsin and 0.03% BSA) for each successive row of wells. The plates were stored in an incubator at 37°C and 5% . After 4 days, formaldehyde was added to fix the cells and naphthol blue–black was added to stain the fixed cells. The plates were washed and then the 50% infectious dose was calculated using the Reed–Muench method.18 2.4.Laser IrradiationThe excitation laser source employed in this work was a diode-pumped mode-locked Ti-sapphire laser. The laser produced a continuous train of 65 fs pulses at a repetition rate of 80 MHz.14,15,19 The output of the second-harmonic generation of the Ti-sapphire laser was used to irradiate the sample. The excitation laser was chosen to operate at a wavelength of 415 nm and with an average power of 140 mW. It had a pulse width of full width at half maximum of about 100 fs. An achromatic lens of focus length 7.5 cm was used to focus the laser beam into the sample area. In order to facilitate the interaction of the laser with the influenza virus particles, which were placed inside a Pyrex cuvette with buffer solution, a magnetic stirrer was set up so that virions would enter the laser-focused volume. All the laser-irradiated influenza samples contained approximately virus and had a volume of about . The typical exposure time of the sample to laser irradiation was about 8 h. The diameter of the laser beam was approximately within the cuvette and the effective laser exposure time for individual virions was estimated to be about 28 s. The sterility of influenza virus samples after laser treatment was confirmed by assay. All the experimental results reported here were obtained at 23°C and with a single laser beam excitation. The temperature increase of sample solutions during USP laser treatments, as monitored by a thermocouple, did not exceed 2°C. The inactivated virus was stored in aliquots at for use in subsequent vaccination experiments. 2.5.Hemagglutination AssayLive and the USP laser-inactivated virus preparations were serially twofold-diluted in a 100 ml volume on a 96-well microtitre plate. A 0.5% chicken erythrocyte suspension was added to all wells and plates were incubated for 30 min on ice. This hemagglutination assay was adapted from current protocols in microbiology.20 2.6.Immunization and ChallengeGroups of mice were vaccinated twice at a 2-week interval, as previously described,21,22 with () of laser-inactivated H1N1 virus by intranasal administration. Control mice did not receive vaccine. The mice in both groups maintained a consistent weight prior to administration of the challenge dose. Two weeks after the last vaccination, the mice were challenged with a lethal dose ( ) of H1N1, and the weight of the mice was daily monitored. Mice losing more than 25% of their body weight were considered to have reached the experimental endpoint and were euthanized. 2.7.Flow CytometryTwo weeks after the last vaccination, mice were sacrificed and their splenocytes were isolated and stimulated using influenza nucleoprotein peptide (NP). Detection of cellular surface CD8a and intracellular IFN- was performed using flow cytometry as previously described.23 Briefly, the cells were incubated for overnight with of GolgiPlug (BD Pharmingen) in the presence of of NP peptide. After washing with FACScan buffer, the cells were stained with phycoerythrin-conjugated anti-mouse CD8a antibody. The cells were then incubated with BD cytofix/cytoperm solution (BD Pharmingen) followed by staining with FITC-conjugated anti-mouse IFN- antibody. The splenocytes of all the mice in each group were pooled together and then analyzed by flow cytometry on a Becton-Dickinson FACSCalibur with CellQuest software (BD Biosciences, Mountain View, California). Gating was performed on the lymphocyte area. 2.8.Microneutralization AssayBlood was collected from the tail vein of vaccinated () or unvaccinated () mice 2 weeks after the last vaccination. The serum was stored in aliquots at 4°C. After the serum was collected, the mice were tested for H1N1-specific neutralizing antibodies as follows. MDCK cells were plated in each well of a 96-well plate. Serum was diluted with infection media (DMEM with N-acetylated trypsin and 0.03% BSA) to 1:100 and added to the first row of wells containing the MDCK cells. After thorough mixing of the well contents, of the first row’s wells were added to of infection media in the next row. This procedure was continued until the last row of wells, resulting in two-fold dilutions, then the extra serum was discarded. A constant H1N1 concentration of was used for each plate. The virus and serum were incubated at 25°C for 2 hours and then added to the 96-well plate with MDCK cells. The plates were stored for three nights in an incubator at 37°C and 5% . Formaldehyde and naphthol blue–black was added to visualize the results of the reaction as in the assay. This assay was repeated three times. Neutralization titers were calculated using the Reed–Muench method. The inverse of the highest dilution at which 50% protection was achieved was determined to be the neutralization titer of the serum.24 2.9.ELISAThe levels of anti-influenza antibodies in sera were determined by a direct enzyme-linked immunosorbent assay (ELISA) as previously described.25,26 Briefly, wells of a 96-microwell plate were coated with of a of influenza and incubated at 4°C overnight. The wells were then blocked with PBS containing 20% fetal bovine serum. Sera were prepared from the mice on day 14 postimmunization, 100 times diluted in PBS, added to the ELISA wells, and incubated at 37°C for 2 h. After being washed with PBS containing 0.05% Tween 20, the plate was incubated with a 1/2,000 dilution of a peroxidase-conjugated rabbit anti-mouse immunoglobulin G antibody (Zymed, San Francisco, California) at room temperature for 1 h. The plate was washed six times, and then 1-Step Turbo TMB-ELISA was used as a substrate for color development (Pierce, Rockford, Illinois); color development was stopped with 1 M . The absorbance of the ELISA plate wells was then determined with a standard ELISA reader at 450 nm. 2.10.Protein Carbonyl QuantificationThe carbonyl concentrations in untreated BSA, USP laser-treated BSA, or UV-treated BSA were assessed using a dinitrophenylhydrazine (DNPH)-based protein carbonyl colorimetric assay kit (Cayman Chemical) according to the manufacturer’s instructions. In the UV treatment group, BSA samples were exposed to a Phillips TUV30W 30-Watt germicidal UVC lamp at a 4-cm distance from the bulb for 90 min. 3.Experimental Results3.1.Effect of the Ultrashort Pulsed Laser Virus Inactivation on Hemagglutination ActivityHemagglutination activity after the USP laser virus inactivation provides one indicator to the structural alternation of the surface proteins of the virus inactivation treatment. Purified influenza stock was aliquoted into batches and treated with the USP laser irradiation. Following the complete loss of infectivity, we compared the hemagglutination activity of live and inactivated viruses. As shown in Table 1, within the experimental uncertainty, hemagglutination activity was not affected by the USP laser irradiation. These results provide evidence that the USP laser irradiation, among other inactivation methods, causes the least structural changes to viral surface proteins. Table 1Hemagglutination activity of live and the ultrashort pulsed (USP) laser-inactivated influenza virus with A/PR/8/34 strain.
3.2.Laser-Inactivated H1N1 Influenza Vaccine Confers Protection against Lethal H1N1 Challenge in MiceWe determined whether the laser-inactivated H1N1 virus vaccine conferred protection against a lethal dose of H1N1. The percent of change from initial weight was used as an indicator of the health of the mice. Groups of mice received vaccination () or no treatment (). Two weeks after the last vaccination, mice in both groups were given a lethal dose of live H1N1 virus. Following administration of the challenge dose, the weights of mice in the control group rapidly decreased. As shown in Fig. 1, by the seventh day after receiving the challenge dose, control mice lost a significant percentage of their initial weight, while the mice in the vaccinated group maintained healthy weights. Our results show that vaccination is 87.5% effective against a challenge of lethal dose. 3.3.Laser-Inactivated H1N1 Influenza Vaccine Increases Immune Response in MiceTo further investigate the immunity generated by vaccination with laser-inactivated virus, CTL activation was assessed. Splenocytes were obtained from vaccinated or untreated mice and stimulated by immunogenic influenza NP peptide. Cells were fluorescently tagged for CD8 and IFN- and analyzed by flow cytometry. Figure 2 demonstrates that the vaccinated mice show a 10-fold increase in the percentage of activated NP peptide-specific T cells in comparison to the control mice. These data indicate that vaccination with laser-inactivated virus generates influenza antigen-specific T cell immune responses. 3.4.Laser-Inactivated H1N1 Influenza Vaccine Generates Influenza-Specific Neutralizing AntibodiesWe next investigated humoral immunity induced by vaccination using a microneutralization assay. This neutralization assay is a sensitive and specific technique to measure neutralizing antibody responses to H1N1 virus. As shown in Fig. 3, we found that sera from mice that received laser-inactivated vaccination showed a significantly higher neutralizing antibody titer compared to sera from control (unvaccinated) mice. Furthermore, we observed that vaccination with decreasing doses of laser-inactivated influenza virus generated virus-specific antibody responses to lesser degrees. These experimental results indicate that vaccination with laser-inactivated virus induces neutralizing antibody immune responses. 3.5.Transmission Electron Microscopy Images Reveal that the Laser-Inactivated Virus Retains Its Global Viral StructureWe used transmission electron microscopy (TEM) to visually examine the active and laser-inactivated influenza viruses. Figures 4(a) and 4(b) show the TEM images of the influenza virus with or without laser irradiation, respectively. We have found that the global structure of the virus is maintained after the USP laser treatment, indicative of the production of WIV by the USP laser irradiation. 3.6.Laser Treatment Does Not Generate Carbonyl Groups in ProteinConventional inactivation methods including formalin, UV treatment, and gamma radiation are potent inducers of carbonyl groups in protein;4,10,11,27 these carbonyl groups are in turn inducers of harmful and undesirable T helper type 2 responses.4,5 To determine whether laser treatment generates protein carbonylation, we used a colorimetric 2,4-dinitrophenylhydrazine (DNPH)-based assay to quantitate carbonyl content in laser-treated BSA. Untreated BSA or UV-treated BSA served as negative and positive controls, respectively. Figure 5 shows that there is no significant increase in carbonyl content in laser-treated BSA samples relative to untreated BSA. In contrast, the carbonyl content of the UV-treated BSA was dramatically increased relative to both untreated and laser-treated BSAs (). These results demonstrate that USP laser treatment generates fewer carbonyl groups in protein antigens compared with conventional pathogen inactivation methods, reducing the risk of detrimental vaccine-elicited Th2 responses. 4.DiscussionBecause of the following two reasons, the complete inactivation of H1N1 flu viruses in the sample by the USP laser irradiation observed in our experiments and used for the vaccine cannot be due to the two-photon absorption effect. First, we have estimated the number of UVC photons which might be produced at the laser power densities used in our experiments. The two-photon absorption coefficient for H1N1 flu virus is not available in the literature; however, if we assume that the viruses are giant molecules and that their two-photon absorption coefficient at 415 nm is comparable to that of a typical molecule,28 then the number of UVC photons at 208 nm generated under our experimental conditions was estimated to be of the order of 0.1/ second. Because the laser exposure time is 8 h, the number of generated UVC photons is about 3000 for the total laser exposure time. On the other hand, the total number of H1N1 viral particles in the laser-irradiated sample is about 200 million; since one UVC photon at 208 nm can inactivate only one viral particle, the value of generated UVC photons of about 3000 during the total laser exposure time is too small to account for the complete inactivation of 200 million viral particles observed in our experiments. Second, we have tried to detect the UVC photons which might be generated in our laser experiments (here, the glass vial is replaced by a synthetic fused silica vial) by using a UV spectrometer with a photon counting system. Within our experimental uncertainty of , we failed to detect any of the UVC photons at 208 nm. This finding is consistent with our estimation stated above. In addition, we note that the absorption coefficient of water at 208 nm is about , which means that the effect of water absorption at 208 nm is negligible and cannot be the reason for not detecting the UVC photon. Therefore, the observed complete inactivation for H1N1 flu virus observed in our experiments cannot be due to UVC photons generated by two-photon absorption. It has been shown that nonenveloped viruses such as murine norovirus (MNV) are inactivated by a visible USP laser through the ISRS process,16 whereby the USP laser pulses excite Raman-active vibrational modes on the capsid of the nonenveloped virus––MNV. The amplitude of the vibration is linearly proportional to the laser intensity. When the laser intensity is sufficiently large, the excited amplitude of vibration on the capsid can become extremely large, leading to the breaking of weak links such as hydrogen bonds and hydrophobic contacts in the capsid of the virus. This causes the capsid to disintegrate into subunits. The virus becomes inactivated because of the loss of integrity of its capsid. On the other hand, it has been demonstrated that enveloped viruses such as murine cytomegalovirus (MCMV) are inactivated by a visible USP laser via the ISRS process as well but through a different route/pathway.19 The USP laser pulses excite Raman-active modes on the proteins of the capsid as well as the tegument proteins of the enveloped virus––MCMV through the impulsive stimulated Raman scattering process. The excitations, which break the hydrogen bonds and hydrophobic contacts on these proteins, cause partial unfolding of the proteins. These unfolded proteins will rapidly reform their broken weak hydrogen bonds and hydrophobic contacts and return to their original folded configuration. However, if the concentration of proteins is very high, such as in the case of proteins confined within the capsid of a virus, they can form hydrogen bonds and hydrophobic contacts with other proteins nearby, leading to the aggregation of proteins. This has been the case for the enveloped virus––MCMV. Aggregation between capsid proteins and tegument proteins has been found to be the cause of inactivation for an enveloped virus. All influenza viruses are enveloped viruses. Therefore, we believe that the most likely inactivation mechanism for the H1NI influenza virus inactivated by the visible USP laser studied here is the ISRS process. The TEM images of H1N1 influenza virus before and after the USP laser irradiation, shown in Fig. 4, further support our argument. The striking similarity between these TEM images to those of MCMV,19 i.e., the retention of the capsid and the global structure of the virus, suggests that the effects (and, therefore, the underlining inactivation mechanism) of the USP laser irradiation on these two enveloped viruses are the same. To give a perspective on the vaccine potency reported in our current study, it is illustrative to compare the vaccine dosages required for protection against lethal challenge in mice using conventional or laser-inactivated H1N1 influenza vaccines. Among conventional methods including heat, formalin, beta propiolactone, and detergents, formalin was found to have the greatest preservation of influenza vaccine antigens.13 We have performed additional experiments in which two control groups of mice got conventional formalin-inactivated H1N1 influenza vaccine. Figure 6(a) shows one control group vaccinated with two doses of conventional formalin-inactivated H1N1 vaccine at , which was the dose of the USP laser-inactivated vaccine that we used for protection against the challenge. Figure 6(b) shows the other control group vaccinated with two doses of conventional formalin-inactivated H1N1 vaccine at . The mice of the control group in Fig. 6(a) all died (the weights decreased more than 30% of their initial ones) 10 days after challenging; whereas the mice of the control group in Fig. 6(b) achieved 75% protection. On the other hand, with the visible USP laser irradiation method, we employed two doses of USP laser-inactivated vaccine at , which is a 10-fold lower dose relative to the formalin-inactivated vaccine, to achieve 87.5% protection. Therefore, these results indicate that the USP laser-inactivated vaccine is significantly more efficient than the vaccine prepared by the conventional formalin-inactivated vaccine. The relatively high potency of the USP laser-inactivated influenza virus vaccine can be partly attributed to the fact that the visible USP laser irradiation has minimal effects on the structure of proteins. The circular dichroism (CD) spectrum of BSA protein measured before and after the USP laser irradiation is a good example. The CD spectrum is very sensitive to the secondary structure of proteins. It has been shown that, within experimental uncertainty, there is no change in the CD spectrum of BSA protein before and after USP laser irradiation.15 These spectroscopic results are in line with our hemagglutination activity results. Our experimental results on the hemagglutination activity of the virus show that, within the experimental uncertainty, the USP laser irradiation has no effects on the surface protein structure of the virus. We note that the USP laser-inactivated influenza vaccine may generate heterosubtypic immunity, which is the aim of current efforts to design universal influenza vaccines. The CTL response is a key mechanism for improved heterosubtypic protection against influenza because CTLs have been shown to be specific for epitopes that are conserved among viral subtypes.29 Our data showed that splenocytes from vaccinated mice showed a 10-fold increase of influenza NP-specific CTLs compared to unvaccinated mice. These results suggest that the laser-inactivated influenza vaccine has the potential to generate cross-protection against multiple strains and address the issue of viral mutation. The presence of carbonyl groups in vaccine antigens has been linked to the induction of undesirable and potentially deleterious Th2-mediated immunopathology.4,5 Many inactivation techniques including UV and gamma radiation are potent inducers of protein carbonylation.4,10,11,27 We note that although formaldehyde is not an oxidizing agent and cannot produce oxidative damage in a cell free system, the carbonyl groups introduced into proteins by formaldehyde in the formalin inactivation technique have something in common with the carbonyl groups introduced by protein oxidation. In contrast to these techniques, visible USP lasers lack the energy to disrupt covalent structures in proteins. Therefore, we reasoned that USP laser treatment would not cause protein carbonylation. The experimental results in Fig. 5 confirm this. These data demonstrate that USP laser treatment does not generate significant levels of carbonyl groups in protein antigens compared with conventional pathogen inactivation methods, reducing the risk of detrimental vaccine-elicited Th2 responses. In addition to carbonyl groups, other types of covalent damage caused by formalin, UV, and gamma radiation can result in the formation of “neoantigens” and elicit adverse immune reactions when administered to patients, as was seen in penicillin allergies30 and certain chemically treated blood products.31 In contrast, the USP laser inactivates enveloped influenza virus through the disruption of weak, noncovalent hydrogen bonds and hydrophobic contacts in the virion, leading to the aggregation of capsid and tegument proteins. As a result, there is an overall reduced concern of side effects from vaccines prepared by the USP laser treatment method. 5.ConclusionIn summary, we have demonstrated a novel USP laser irradiation method for the production of safe and potent WIV vaccines. We envision that the future of pathogen inactivation technologies will favor chemical-free methods that target properties specific to pathogens while preserving desirable components of the treated product, leading to improved safety profiles. The USP laser irradiation method we have presented in this report is one such potential technology. Further, evaluation of the USP laser-inactivated vaccine for cross-protection and in the context of other important pathogens such as HIV, SARS, and MERS is warranted. AcknowledgmentsThis work was supported in part by NHLBI Ruth L. Kirschstein NRSA F30 under Grant No. HL116183-01 (SDT), the Mallinckrodt Institute of Radiology Development Fund, and NIH under Grant Nos. R01 EB008111 and R33 CA123537 (SA). ReferencesE. S. MocarskiT. ShenkR. F. Pass, Fields Virology, 2701
–2772 Lippincott Williams and Wilkins, Philadelphia, Pennsylvania
(2007). Google Scholar
N. BardiyaJ. H. Bae,
“Influenza vaccines: recent advances in production technologies,”
Appl. Microbiol. Biotechnol., 67 299
–305
(2005). http://dx.doi.org/10.1007/s00253-004-1874-1 AMBIDG 0175-7598 Google Scholar
N. K. BlackburnT. G. Besselaar,
“A study of the effect of chemical inactivants on the epitopes of Rift Valley fever virus glycoproteins using monoclonal antibodies,”
J. Virol. Methods, 33 367
–374
(1991). http://dx.doi.org/10.1016/0166-0934(91)90036-Y JVMEDH 0166-0934 Google Scholar
A. Moghaddamet al.,
“A potential molecular mechanism for hypersensitivity caused by formalin-inactivated vaccines,”
Nat. Med., 12 905
–907
(2006). http://dx.doi.org/10.1038/nm1456 1078-8956 Google Scholar
A. E. Moghaddamet al.,
“Reactive carbonyls are a major Th2-inducing damage-associated molecular pattern generated by oxidative stress,”
J. Immunol., 187 1626
–1633
(2011). http://dx.doi.org/10.4049/jimmunol.1003906 JOIMA3 0022-1767 Google Scholar
J. Chinet al.,
“Field evaluation of a respiratory syncytial virus vaccine and a trivalent parainfluenza virus vaccine in a pediatric population,”
Am. J. Epidemiol., 89 449
–463
(1969). AJEPAS 0002-9262 Google Scholar
V. A. Fulginitiet al.,
“Respiratory virus immunization. I. A field trial of two inactivated respiratory virus vaccines; an aqueous trivalent parainfluenza virus vaccine and an alum-precipitated respiratory syncytial virus vaccine,”
Am. J. Epidemiol., 89 435
–448
(1969). AJEPAS 0002-9262 Google Scholar
H. W. Kimet al.,
“Respiratory syncytial virus disease in infants despite prior administration of antigenic inactivated vaccine,”
Am. J. Epidemiol., 89 422
–434
(1969). AJEPAS 0002-9262 Google Scholar
A. Z. Kapikianet al.,
“An epidemiologic study of altered clinical reactivity to respiratory syncytial (RS) virus infection in children previously vaccinated with an inactivated RS virus vaccine,”
Am. J. Epidemiol., 89 405
–421
(1969). AJEPAS 0002-9262 Google Scholar
C. S. Sanderet al.,
“Photoaging is associated with protein oxidation in human skin in vivo,”
J. Invest. Dermatol., 118 618
–625
(2002). http://dx.doi.org/10.1046/j.1523-1747.2002.01708.x JIDEAE 0022-202X Google Scholar
D. Scheideggeret al.,
“Protein oxidative changes in whole and skim milk after ultraviolet or fluorescent light exposure,”
J. Dairy Sci., 93 5101
–5109
(2010). http://dx.doi.org/10.3168/jds.2010-3513 JDSCAE 0022-0302 Google Scholar
S. De FloraG. Badolati,
“Thermal inactivation of untreated and gamma-irradiated A2-Aichi-2-68 influenza virus,”
J. General Virol., 20 261
–265
(1973). http://dx.doi.org/10.1099/0022-1317-20-2-261 JGVIAY ISSN 0022-1317 Google Scholar
M. Jongeset al.,
“Influenza virus inactivation for studies of antigenicity and phenotypic neuraminidase inhibitor resistance profiling,”
J. Clin. Microbiol., 48 928
–940
(2010). http://dx.doi.org/10.1128/JCM.02045-09 JCMIDW 1070-633X Google Scholar
S. W. Tsenet al.,
“Prospects for a novel ultrashort pulsed laser technology for pathogen inactivation,”
J. Biomed. Sci., 19 62
(2012). http://dx.doi.org/10.1186/1423-0127-19-62 1021-7770 Google Scholar
K. T. Tsenet al.,
“Studies of inactivation of encephalomyocarditis virus, M13 bacteriophage, and Salmonella typhimurium by using a visible femtosecond laser: insight into the possible inactivation mechanisms,”
J. Biomed. Opt., 16 078003
(2011). http://dx.doi.org/10.1117/1.3600771 JBOPFO 1083-3668 Google Scholar
S. W. Tsenet al.,
“Studies of inactivation mechanism of non-enveloped icosahedral virus by a visible ultrashort pulsed laser,”
Virol. J., 11 20
(2014). http://dx.doi.org/10.1186/1743-422X-11-20 VJIOA4 1743-422X Google Scholar
D. D. LaBarreR. J. Lowy,
“Improvements in methods for calculating virus titer estimates from TCID50 and plaque assays,”
J. Virol. Methods, 96 107
–126
(2001). http://dx.doi.org/10.1016/S0166-0934(01)00316-0 JVMEDH 0166-0934 Google Scholar
L. J. ReedH. Muench,
“A simple method of estimating fifty per cent endpoints,”
Am. J. Hyg., 27 493
–497
(1938). AJHYA2 0096-5294 Google Scholar
S. W. Tsenet al.,
“Inactivation of enveloped virus by laser-driven protein aggregation,”
J. Biomed. Opt., 17 128002
(2012). http://dx.doi.org/10.1117/1.JBO.17.12.128002 JBOPFO 1083-3668 Google Scholar
K. J. SzretterA. L. BalishJ. M. Katz,
“Influenza: propagation, quantification, and storage,”
Current Protocols in Microbiology, 1 John Wiley & Sons, Inc, New Jersey
(2006). http://dx.doi.org/10.1002/0471729256.mc15g01s3 Google Scholar
B. Manicassamyet al.,
“Protection of mice against lethal challenge with 2009 H1N1 influenza A virus by 1918-like and classical swine H1N1 based vaccines,”
PLoS Pathog., 6 e1000745
(2010). http://dx.doi.org/10.1371/journal.ppat.1000745 1553-7374 Google Scholar
C. Savardet al.,
“Improvement of the trivalent inactivated flu vaccine using PapMV nanoparticles,”
PloS One, 6 e21522
(2011). http://dx.doi.org/10.1371/journal.pone.0021522 1932-6203 Google Scholar
S. Penget al.,
“Characterization of HPV-16 E6 DNA vaccines employing intracellular targeting and intercellular spreading strategies,”
J. Biomed. Sci., 12 689
–700
(2005). http://dx.doi.org/10.1007/s11373-005-9012-3 1021-7770 Google Scholar
R. E. Wooleyet al.,
“Comparison of a microneutralization test in cell culture and virus neutralization test in embryonated eggs for determining infectious bronchitis virus antibodies,”
J. Clin. Microbiol., 3 149
–156
(1976). JCMIDW 1070-633X Google Scholar
F. S. Quanet al.,
“Kinetics of immune responses to influenza virus-like particles and dose-dependence of protection with a single vaccination,”
J. Virol., 83 4489
–4497
(2009). http://dx.doi.org/10.1128/JVI.02035-08 JOVIAM 1070-6321 Google Scholar
F. S. Quanet al.,
“Virus-like particle vaccine induces protective immunity against homologous and heterologous strains of influenza virus,”
J. Virol., 81 3514
–3524
(2007). http://dx.doi.org/10.1128/JVI.02052-06 JOVIAM 1070-6321 Google Scholar
A. KriskoM. Radman,
“Protein damage and death by radiation in Escherichia coli and Deinococcus radiodurans,”
Proc. Natl. Acad. Sci. U. S. Am., 107 14373
–14377
(2010). http://dx.doi.org/10.1073/pnas.1009312107 PNASA6 0027-8424 Google Scholar
R. W. Boyd, Nonlinear Optics, Academic Press, San Diego, California
(1992). Google Scholar
M. SchotsaertX. SaelensG. Leroux-Roels,
“Influenza vaccines: t-cell responses deserve more attention,”
Expert Rev. Vaccines, 11 949
–962
(2012). http://dx.doi.org/10.1586/erv.12.71 ERVXAX 1476-0584 Google Scholar
X. Menget al.,
“Direct evidence for the formation of diastereoisomeric benzylpenicilloyl haptens from benzylpenicillin and benzylpenicillenic acid in patients,”
J. Pharmacol. Exp. Ther., 338 841
–849
(2011). http://dx.doi.org/10.1124/jpet.111.183871 JPETAB 0022-3565 Google Scholar
P. M. Sobralet al.,
“Viral inactivation in hemotherapy: systematic review on inactivators with action on nucleic acids,”
Revista brasileira de hematologia e hemoterapia, 34 231
–235
(2012). http://dx.doi.org/10.5581/1516-8484.20120056 1516-8484 Google Scholar
|