RETRACTED ARTICLE: Methylene blue photochemical treatment as a reliable SARS-CoV-2 plasma virus inactivation method for blood safety and convalescent plasma therapy for COVID-19

Corona virus disease 2019 (COVID-19) is caused by severe acute respiratory syndrome (SARS)-corona virus (CoV)-2. The first outbreak occurred at the end of 2019, causing symptoms such as fever and pneumonia. In serious cases, the patient might die. As of the early March 2021, the COVID-19 epidemic had appeared in all continents except Antarctica, about 117 million people have been diagnosed worldwide, and the death toll has approached 2.6 million, seriously threatening global public health [1].

SARS-CoV-2 was first isolated from epithelial cells of the human airway, and was identified by next-generation sequencing technology in January 2020 as a new member of the beta coronaviruses (β-CoVs) [2]. Coronaviruses are enveloped, single-stranded RNA viruses [2]. From 2002 to 2003, more than 8000 patients were infected by SARS-CoV, which causes SARS, and the World Health Organization (WHO) finally reported 774 related deaths. Since September 2012, a total of 2494 laboratory-confirmed Middle East respiratory syndrome (MERS)-CoV infected cases have been reported. The WHO has reported 858 MERS-CoV-related deaths [3, 4]. These emerging infectious diseases with global transmission are caused by β CoVs.

Although coronaviruses cause respiratory tract infections, several studies have shown that the viral RNA of SARS-CoV [5], MERS-CoV [6], or SARS-CoV-2 [7, 8] can be detected in blood plasma. As early as 2003, the WHO noted that blood products could be contaminated with SARS-CoV. Although no cases of SARS-CoV infection caused by blood transfusion have been reported, there is still a theoretical risk of transmitting SARS-CoV or other coronaviruses through blood transfusion [9]. As more asymptomatic infections are identified among COVID-19 cases [10], blood safety becomes more important [11, 12]. In addition, there are currently no specific drugs or vaccines that are effective against SARS-CoV-2. Patient convalescent plasma therapy could be a rapid and effective treatment for this epidemic situation [13]. However, the critical aspect of this method is to ensure the complete inactivation of SARS-CoV-2 in the plasma from donors. There is an urgent need for a reliable and practical method of plasma SARS-CoV-2 inactivation.

Photochemical treatment methods are used as pathogen inactivation/reduction technologies (PRTs). Photochemical methods to kill viruses are performed by adding methylene blue (MB) into blood products followed by visible light treatment. Methylene blue is a photosensitizer with a maximum absorption peak of 670 nm. It is usually used as an antidote to treat methemoglobinemia and cyanide poisoning caused by nitrite poisoning. The surface of MB carries a positive charge. It can be embedded into DNA or RNA, especially in combination with negatively charged G-C base pairs of viral nucleic acids. Under visible light, MB absorbs light energy, activates it from the ground state to a singlet state, and generates singlet oxygen through electron transfer, which damages and breaks nucleic acids to kill viruses. Viral envelopes and nucleic acids can be targets of MB attack. Alamdari and colleagues used leucomethylene blue, a reduced form of MB, as a therapeutic method for COVID-19 infection [14]. Furthermore, they used a combination of MB-vitamin C-N-acetyl Cysteine to treat five patients with COVID-19 and four out of five survived [15]. The possibility of using MB for either the prevention of viral infection or the development of photoactive fabrics has been proposed by Almeida et al. [16]. Under light, MB can cause nucleic acid strand breaks [17]. The visible light source can be a halogen lamp, a metal halide lamp, or a fluorescent lamp, with full-band white light. However, because of the low excitation efficiency of MB in full-band white light, this process also generates heat to destroy plasma components. The ‘BX-1 AIDS treatment instrument’, developed by Boxin Biotechnology Development LTD (Beijing, China), uses LED single wavelength light combined with MB and is highly effective at killing various lipid enveloped viruses, such as HIV-1 and other viruses [18, 19]. As SARS-CoV-2 is a new type of coronavirus, its tolerance to physicochemical conditions is unclear. Therefore, in the present study, the ‘BX-1 AIDS treatment instrument’ was used to study the plasma inactivation of a SARS-CoV-2 isolate from Zhejiang University.

The new coronavirus SARS-CoV-2, which appeared in December 2019, spread globally within 3 months and is being monitored closely worldwide. The following are safety considerations for blood transfusions or blood products: (1) Viral RNA in plasma or serum can be detected in patents with COVID-19 2 or 3 d before the onset of symptoms [8]; (2) most patients, especially young adults who can donate blood, experience milder symptoms than do the elderly; (3) multiple asymptomatic carriers have been found in China and other countries, which increases the possibility of blood donation by COVID-19 or virus carriers [10]; (4) infection rates of patients in the incubation period are still uncertain, and there is yet no data on viral load in plasma, serum, or lymphocytes during the incubation period. Blood transfusions carry the risk of transmitting SARS-CoV-2, and thus measures to inactivate pathogens in blood products should be explored as soon as possible.

Coronaviruses are enveloped, single-stranded RNA viruses. Previous studies indicated that coronaviruses are generally susceptible to acid, alkaline, and heat [20]. After the outbreak of SARS and MERS, some studies investigated the potential of PRTs to reduce or completely eliminate the potential risks of coronavirus transmission through blood products or derivatives [21]. Research on plasma inactivation methods has focused on heat and photochemical treatment methods. (1) Heat method, in general, 30 mins at 60 °C is sufficient to reduce SARS-CoV from cell-free plasma [22], and 25 mins at 56 °C reduced MERS virus by more than 4 log10 TCID50/mL [23]. Heating can denature proteins in blood products; therefore, it cannot be used to manufacture plasma-derived products. (2) Photochemical treatment methods. Different wavelengths of light affect the viability of SARS and MERS viruses in the blood. UV light, Amotosalen, or riboflavin can inactivate pathogenic nucleic acids [22]. Keil et al. performed SARS-CoV-2 inactivation of blood products in standard blood bags using the Riboflavin and the UV methodand the data indicated that the reductions of the viral titres were ≥ 3.40 Logs and ≥ 4.53 Logsin plasma and platelets, respectively [24], which are on the same order of magnitude as our data. It has been previously reported that MB plus visible light is capable of inactivating coronavirus in plasma [21, 25] Previously, the prototype ‘plasma virus inactivator’ JY-1 developed by Boxin (Beijing) Biotechnology Development LTD, under the condition of a single-wavelength LED illumination of 40,000 lx, was used for treatment together with 1 μM MB for 30 min [26, 27]. The new BX-1 ‘AIDS treatment instrument’ used in this study can reduce the titer of new coronavirus SARS-CoV-2 by 4.5 log10 TCID50/mL in 2 mins (Fig. 2), which is a strong advantage for inactivation of viruses in plasma.

MB and LED based BX-1 technology provides a new approach for inactivation of SARS-CoV-2 in plasma, which may be useful for convalescent plasma therapy of critical ill patients with COVID-19. Convalescent plasma therapy is a rapid and effective treatment that has been applied for severe infectious diseases for over 100 years [13]. In 1890, Emil von Behring from Germany and Saburo Kitari from Japan announced an important discovery: They kept injecting small amounts of non-lethal tetanus into animals, which produced an antitoxin in the blood. This could neutralize the bacillus toxicity of tetanus injected into the body. The serum could also be isolated from animals that have acquired tetanus immunity and injected into other animals to enhance their immunity to tetanus. Emil Behring won the 1901 Nobel Prize in Medicine for his research on diphtheria serum therapy. The earliest application of convalescent plasma therapy allowed humans to overcome diphtheria [13]. In 2014, during Ebola virus disease outbreaks, the WHO recommended the use of convalescent plasma as an empirical treatment [28]. Previously, in the clinical treatment of SARS coronavirus, doctors in Hong Kong, Taiwan, and Singapore had shown that convalescent plasma therapy could improve the conditions for critical ill patients with SARS for whom comprehensive treatment had not been effective [29]. Given this long history of serum-based treatment in the modern era, and its established safety and efficacy, convalescent plasma transfusion should be used to treat patients with COVID-19 [30].

BX-1 based MB photochemical technology could inactivate SARS-CoV-2 efficiently and has great potential for ensuring the safety of blood transfusions, for plasma transfusion therapy in recovering patients, and for preparing inactivated vaccines.