Donna Pascual

Hypericin as an inactivator of infectious viruses in blood components

BACKGROUND: Hypericin is a potent virucidal agent with activity against a broad range of enveloped viruses and retroviruses. The effective virucidal activity emanates from a combination of photodynamic and lipophilic properties. Hypericin binds cell membranes (and, by inference, virus membranes) and crosslinks virus capsid proteins. This action results in a loss of infectivity and an inability to retrieve the reverse transcriptase enzymatic activity from the virion.

Inactivation of viruses in blood with aluminum phthalocyanine derivatives

The inactivation of viruses added to whole blood and a red cell concentrate with aluminum phthalocyanine and its sulfonated derivatives was studied. A cell‐free form of vesicular stomatitis virus (VSV), used as a model, was completely inactivated (greater than 10(4) infectious units; TCID50) on treatment of whole blood with 10 microM (10 mumol/L) aluminum phthalocyanine chloride (AIPs) and visible light dosage of 88 to 176 J per cm2. At 44 J per cm2, complete VSV inactivation was achieved on raising the concentration of AIPc to 25 microM (25 mumol/L). Results at least as good were achieved on similar treatment of a red cell concentrate. Also inactivated were a cell‐associated form of VSV and both cell‐free and cell‐associated forms of human immunodeficiency virus; encephalomyocarditis virus, used as a model for non‐lipid‐enveloped viruses, was not inactivated by this procedure. This inactivation of cell‐free VSV suggests that a similar degree of inactivation could be achieved with a lower concentration of the sulfonated forms of aluminum phthalocyanine. Throughout the above studies, red cell integrity was well maintained, as judged by the absence of hemoglobin release (less than or equal to 2%) during the course of treatment or on subsequent storage. Red cell osmotic fragility was decreased on treatment of whole blood with AIPc. This study indicates that AIPc may be a promising method for the inactivation of viruses in cellular blood products.

Strategies for Evaluation of Enveloped Virus Inactivation in Red Cell Concentrates Using Hypericin

Abstract Photodynamically induced virus inactivation appears promising in preventing transmission of enveloped virus infections in transfusible blood products. The potential for utilizing hypericin as a photosensitizer to inactivate key enveloped viruses in packed red cell concentrates (PRC) was evaluated. In addition to inactivating effectively ≥106 TCID50 of human immunodeficiency virus (HIV), inactivation of bovine viral diarrhea virus (BVDV) in PRC was used as a model for hepatitis C virus to overcome the deficiency in reliable experimental systems for hepatitis C virus (HCV) inactivation. BVDV was two orders of magnitude more sensitive to inactivation by hypericin than HIV. As part of the virucidal efficacy analyses, the effects of photosensitization on hemopoietic cell lines carrying quiescent integrated HIV provirus were studied as models for evaluating virus inactivation in latently infected cells. Phorbol ester-induced virus production by these cells was effectively prevented by photosensitization with hypericin. A refinement of the illumination conditions, incorporating a monochromatic sodium light source with an emission spectrum coinciding with the absorption peak of hypericin, was highly virucidal, however, caused unacceptable levels of hemolysis. Red blood cells could be protected from phototoxic cellular damage by complexing hypericin with human serum albumin (albumin–hypericin), but the decrease in hemolysis was at the expense of virucidal efficacy. Thus, excitation of hypericin with a fluorescent source appears to be useful potentially for virus inactivation in PRC.

High-Temperature Short-Time Heat Inactivation of HIV and Other Viruses in Human Blood Plasma

An ultra‐short‐time heating system was used to process blood plasma spiked with various viruses (HIV, vesicular stomatitis virus, encephalomyocarditis virus). Virus reduction and recovery of plasma proteins were measured at various temperatures from 65 to 85 °C. Processing at 77 °C and 0.006 s resulted in a high level of virus kill, including ≥ 4.4 log10 HIV, while maintaining protein structure and activity essentially intact.

Onchocerca volvulus: immunization of chimpanzees with X-irradiated third-stage (L3) larvae.

To provide a theoretical basis for the potential development of vaccines against Onchocerca volvulus (Ov) a trial has been conducted to assess the protective efficacy of immunization of chimpanzees with X-irradiated L3 larvae. Approximately 1000 larvae were injected at 0, 1, and 7 months. The immunized animals, and unimmunized controls, were then challenged with 250 live L3. In order to provide possibly protective exposure to the immunologically distinct L4 epicuticle, a radiation dose (45 krad) was chosen which preserved about 50% of the molting ability of unirradiated larvae. Despite the presence of a strong immune response to crude adult worm extracts, and to cloned Ov antigens, at the time of challenge little or no significant protection against patent infection was observed: three of four immunized animals developed patent infection as compared to four of four controls. One immunized animal failed to become patent or to manifest the late antibody response to adult worm antigens seen in both subpatent and patent infections in this model, and may have been protected from infection. The implications of these studies for future attempts to immunize against O. volvulus are discussed.

Enhancement in the Safety of Immune Globulins Prepared from High-Risk Plasma

Hyperimmune γ‐globulins have proven efficacious in the prevention and treatment of viral infections, including those caused by hepatitis A and B viruses, cytomegalovirus, parvovirus. Interest in the prevention and/or treatment of infections caused by human immunodeficiency virus (HIV) has led to clinical trials with anti‐HIV immune plasma and purified immune globulin prepared from donors who are actively infected with HIV. The handling and fractionation of this or other infectious plasma requires the construction and operation of virus containment facilities designed to protect fractionation employees and the immediate environment. This requirement would be reduced substantially by applying virucidal procedures prior to or during plasma pooling. We have shown that heating plasma at 56°C for 1 h followed by treatment with 1% tri(n‐butyl) phophate (TNBP) and 1% Triton X‐100 for 4 h at 30°C resulted in the inactivation of ≥ 1012.1 tissue culture infectious doses (TCID50) of HIV. With this treatment, the recovery of IgG was 87±3%. Fractionation of treated plasma by cold ethanol precipitation proceeded normally, and overall recovery, purity, and potency against selected viral markers were unaffected. The additional treatment of plasma with 15 g/l Aerosil for 4 h at 45 °C removed 104.5 TCID50 of HIV but resulted in substantial IgG losses both prior to and following fractionation. We conclude that potentially infectious plasma can be treated at 56°C for 1 h and by TNBP/Triton X‐100 at 30°C for 4 h prior to fractionation. These steps appear sufficient to assure safety and to permit routine fractionation of plasma. Aerosil treatment, under the condition evaluated, was less satisfactory, although lower concentrations or temperatures than those evaluated may prove advantageous.