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FOR IMMEDIATE RELEASE
Resolving "Long-Haul COVID" and Vaccine Toxicity: Neutralizing the Spike ProteinCommentary by Thomas E. Levy, MD, JD(OMNS June 21, 2021) Although the mainstream media outlets might have you believe otherwise, the vaccines that continue to be administered for the COVID pandemic are emerging as very substantial sources of morbidity and mortality themselves. While the degree to which these negative outcomes of the COVID vaccines can be debated, there is no question that enough disease and death have already occurred to warrant cessation of the administration of these vaccines until additional, completely scientifically-based research can examine the balance between its now clear-cut side effects versus its potential (and still not yet clearly proven) ability to prevent new COVID infections. Nevertheless, enough vaccinations have already been administered to warrant concern that a new "pandemic" of illness and death may well be emerging from the side effects that continue to be documented in steadily increasing numbers. The vaccine-induced "culprit" that is now receiving most of the attention and is the focus of much new research is the COVID virus fragment known as the spike protein. Its physiological impact appears to be doing far more harm than good (COVID antibody induction), and its manner of introduction appears to be fueling its ongoing replication with a continuing presence inside the body for an indefinite length of time. The physical appearance of the COVID virus can been depicted as a central sphere of viral protein surrounded completely by spear-like appendages. Known as spike proteins, they are very analogous to the quills surrounding a porcupine. And just as the porcupine stabs its victim, these spike proteins penetrate into cell membranes throughout the body. After this penetration, protein-dissolving enzymes are activated, the cell membrane breaks down, the viral sphere enters the cytoplasm through this membrane breach, and the metabolism of the cell is subsequently "hijacked" to manufacture more viral particles. These spike proteins are the focus of a great deal of ongoing research examining vaccine side effects (Belouzard et al., 2012; Shang et al., 2020). The spike protein first attaches to ACE2 (angiotensin converting enzyme 2) receptors in the cell membranes (Pillay, 2020). This initial binding step is vital to triggering the subsequent sequence of events that brings the virus inside the cell. When this binding is blocked by competition or prompt enough displacement with an appropriate therapeutic agent, the virus cannot enter the cell, the infectious process is effectively stopped, and the immune defenses of the body are freed to mop up, metabolize, and eliminate the viral pathogens, or just the spike protein alone if free and no longer attached to a viral particle. Although ACE2 is found in many different cells throughout the body, it is especially noteworthy to realize that it is the initial target bound by coronavirus on the epithelial cells lining the airways after pathogen inhalation (Hoffmann et al., 2020). ACE2 expression (concentration) is also especially high on lung alveolar epithelial cells (Alifano et al., 2020). This cell membrane-bound virus can then begin the process that eventually results in the severe acute respiratory syndrome (SARS) seen in clinically-advanced COVID infections (Perrotta et al., 2020; Saponaro et al., 2020). The SARS presentation manifests most clearly when the degree of oxidative stress in the lungs is very elevated. This stage of COVID infection-related extreme oxidative stress is often referred to in the literature as a cytokine storm, and left unchecked this invariably leads to death (Hu et al., 2021). Increasing concern has focused on the continued presence of the spike protein in the blood by itself, unattached to a virion, following COVID vaccination. Supposedly intended to initiate an immune response to the entire virus particle, the spike protein injections are disseminating throughout the body rather than staying put in the upper arm at the vaccine site while the immune response to it evolves. Furthermore, it also appears that these circulating spike proteins can enter cells on their own and replicate themselves without attached virus particles. This not only wreaks havoc inside those cells, it helps to assure the indefinite presence of the spike protein throughout the body. It has also been suggested that large amounts of spike protein are just binding ACE2 receptors and not proceeding any further into the cell, effectively blocking or disabling normal ACE2 function in a given tissue. Additionally, when the spike protein binds a cell wall and "stops" there, the spike protein serves as a hapten (antigen) which can then initiate an autoimmune (antibody or antibody-like) response to the cell itself, rather than to the virus particle to which it is usually attached. Depending on the cell types to which such spike proteins bind, a wide variety of diseases with autoimmune qualities can result. Finally, another very worrisome property of the spike protein which alone would be of great concern is that the spike protein itself appears to be highly toxic. This intrinsic toxicity, along with the apparent ability of the spike protein to replicate itself indefinitely within the cells it enters, probably represents the way in which the vaccine can inflict its worst long-term damage, as the production of this toxin can continue indefinitely without other external factors at play. In fact, the long-haul COVID syndrome likely represents a low-grade unresolved smoldering COVID infection with the same kind of spike protein persistence and clinical impact as is seen in many individuals after their COVID vaccinations (Mendelson et al., 2020; Aucott and Rebman, 2021; Raveendran, 2021). While the totality of the mechanisms involved are far from being completely understood and worked out, the increasing occurrence of post-vaccine clinical complications is nevertheless very clear-cut and must be addressed as rapidly and effectively as possible. By itself, the disruption of ACE2 receptor function in so many areas of the body has resulted in an array of different side effects (Ashraf et al., 2021). Such clinical complications being seen in different organ systems and areas of the body, can all occur in the following three clinical situations. All three are "spike protein syndromes," although the acute infection always includes the entirety of the virus particles along with the spike protein during the initial phases of the infection.
In structuring a clinical protocol to stop the ravages of persistent spike protein presence throughout the body, it is first important to realize that the protocol should be able to effectively treat any aspect of COVID infection, including those periods during active infection, after "active" infection (long-haul COVID), and during ongoing spike protein presence secondary to either "chronic" COVID infection or resulting from COVID vaccine administration. As is the case with any treatment for any condition, factors of expense, availability, and patient compliance always play a role in determining what treatment a given patient will actually undergo for a given period of time. As such, no one specific protocol will be appropriate for all patients, even if the same pathology is present. Ideally, of course, the best protocol is to use all of the options discussed below. When the entirety of the protocol is not possible or feasible, which is most often the case, the combination of HP nebulization, high-dose vitamin C, and appropriately-dosed ivermectin is an excellent way to effectively address long-haul COVID and persistent spike protein syndromes. Much of the rationale of the protocols is based on what is known about the spike protein and how it appears to inflict its harm. The following aspects of spike protein pathophysiology need to all be considered in crafting an optimal treatment protocol:
Therapeutic Agents and Their MechanismsA substantial number of agents have already been found to be highly effective in resolving COVID infections, and even more are continuing to be discovered as worldwide research efforts have so intensely focused on curing this infection (Levy, 2020). Some of the most effective agents and their mechanisms of actions include the following:
[More detail on the therapeutic agents above is available in Chapter 10 of Rapid Virus Recovery] The suggested optimal way to deal with acute COVID that has evolved into long-haul COVID, or with symptoms consistent with the toxic effects of circulating spike protein post-vaccination, is to always eliminate any active or chronic areas of pathogen proliferation with HP nebulization. Vitamin C supplementation should be optimized at the same time. 50-gram infusions of sodium ascorbate should be administered at least several times weekly as long as there is symptomatology attributable to long-haul COVID and circulating spike protein. Initially, a 25-gram infusion of sodium ascorbate given three times a day should prove to be even more effective as circulating vitamin C is rapidly excreted. Oral vitamin C supplementation should be taken as well, either as several grams of liposome-encapsulated vitamin C daily, or as a teaspoon of sodium ascorbate powder several times daily. One capsule daily of Formula 216 can be added to this as well. With the "foundation" of HP nebulization and vitamin C supplementation in place, the best prescription medicines to counter long-haul COVID and circulating spike protein would be with ivermectin first, and then HCQ or HQ if the clinical response is not acceptable. Dosages would need to be determined by the prescribing physician. Along with the baseline immune support supplements noted above, quercetin, 500 to 1,000 mg daily, should be added as well. Any and all of the above recommendations should be undertaken with the guidance of a trusted physician or other appropriately-trained health care professional. RecapEven as the COVID pandemic appears to be slowly subsiding, many individuals are now chronically ill with long-haul COVID and/or with the side effects of a COVID vaccination. It would appear that both clinical situations are primarily characterized by persistent presence of the spike protein and its negative impact on different tissues and organs. Treatment is aimed at neutralizing the direct toxic impact of spike protein, while working to block its ability to bind the receptors needed to hijack the metabolism of the cell into making new viruses and/or more spike protein. At the same time, treatment measures are taken to assure that there is as complete an elimination of active or smoldering COVID infection remaining in the patient. The views expressed in this article are the author's and not necessarily those of the Orthomolecular Medicine News Service or all members of its Editorial Board. OMNS invites alternative viewpoints. Submissions may be sent directly to Andrew W. Saul, Editor, at the email contact address further below. ReferencesAboTaleb H (2020) Neurological complications in COVID-19 patients and its implications for associated mortality. Current Neurovascular Research 17:522-530. PMID: 32718292 Ali M, Spinler S (2021) COVID-19 and thrombosis: from bench to bedside. Trends in Cardiovascular Medicine Alifano M, Alifano P, Forgez P, Iannelli A (2020) Renin-angiotensin system at the heart of COVID-19 pandemic. Biochemie 174:30-33. PMID: 32305506 Asraf U, Abokor A, Edwards J et al. (2021) SARS-CoV-2, ACE2 expression, and systemic organ invasion. Physiological Genomics 53:51-60. PMID: 33275540 Aucott J, Rebman A (2021) Long-haul COVID: heed the lessons from other infection-triggered illnesses. Lancet 397:967-968. PMID: 33684352 Belouzard S, Millet J, Licitra B, Whittaker G (2012) Mechanisms of coronavirus cell entry mediated by the viral spike protein. Viruses 4:1011-1033. PMID: 22816037 Bobker S, Robbins M (2020) COVID-19 and headache: a primer for trainees. Headache 60:1806-1811. PMID: 32521039 Chen L, Li X, Chen M et al. (2020) The ACE2 expression in human heart indicates new potential mechanism of heart injury among patients infected with SARS-CoV-2. Cardiovascular Research 116:1097-1100. PMID: 32227090 Derosa G, Maffioli P, D'Angelo A, Di Pierro F (2021) A role for quercetin in coronavirus disease 2019 (COVID-19). Phytotherapy Research 35:1230-1236. PMID: 33034398 Dhawan R, Gopalan D, Howard L et al. (2021) Beyond the clot: perfusion imaging of the pulmonary vasculature after COVID-19. The Lancet. Respiratory Medicine 9:107-116. PMID: 33217366 Eweas A, Alhossary A, Abdel-Moneim A (2021) Molecular docking reveals ivermectin and remdesivir as potential repurposed drugs against SARS-CoV-2. Frontiers in Microbiology 11:592908. PMID: 33746908 Fantini J, Di Scala C, Chahinian H, Yahi N (2020) Structural and molecular modelling studies reveal a new mechanism of action of chloroquine and hydroxychloroquine against SARS-CoV-2 infection. International Journal of Antimicrobial Agents 55:105960. PMID: 32251731 Galli E, Cipriani F, Ricci G, Maiello N (2020) Cutaneous manifestation during COVID-19 pandemic. Pediatric Allergy and Immunology 31 Suppl 26:89-91. PMID: 33236439 Han x, Y Q (2021) Kidney involvement in COVID-19 and its treatments. Journal of Medical Virology 93:1387-1395. PMID: 33150973 Hassett C, Gedansky A, Migdady I et al. (2020) Neurologic complications of COVID-19. Cleveland Clinic Journal of Medicine 87:729-734. PMID: 32847818 Hellwig M, Maia A (2021) A COVID-19 prophylaxis? Lower incidence associated with prophylactic administration of ivermectin. International Journal of Antimicrobial Agents 57:106248. PMID: 33259913 Hess D, Eldahshan W, Rutkowski E (2020) COVID-19-related stroke. Translational Stroke Research 11:322-325. PMID: 32378030 Hoffmann M, Kleine-Weber H, Schroeder S et al. (2020) SARS-CoV-2 cell entry depends on ACE2 and TMPRSS2 and is blocked by a clinically proven protease inhibitor. Cell 181:271-280. PMID: 32142651 Hu B, Huang S, Yin L (2021) The cytokine storm and COVID-19. Journal of Medical Virology 93:250-256. PMID: 32592501 Hunt R, East J, Lanas A et al. (2021) COVID-19 and gastrointestinal disease: implications for the gastroenterologist. Digestive Diseases 39:119-139. PMID: 33040064 Jacobs J, Eichbaum Q (2021) COVID-19 associated with severe autoimmune hemolytic anemia. Transfusion 61:635-640. PMID: 33274459 Khehra N, Padda I, Jaferi U et al. (2021) Tozinameran (BNT162b2) vaccine: the journey from preclinical research to clinical trials and authorization. AAPS PharmSciTech 22:172. PMID: 34100150 Lehrer S, Rheinstein P (2020) Ivermectin docks to the SARS-CoV-2 spike receptor-binding domain attached to ACE2. In Vivo 34:3023-3026. PMID: 32871846 Levy T (2002) Curing the Incurable. Vitamin C, Infectious Diseases, and Toxins. Henderson, NV: MedFox Publishing Levy T (2017) Hidden Epidemic: Silent oral infections cause most heart attacks and breast cancers. Henderson, NV: MedFox Publishing. Free eBook download available at https://hep21.medfoxpub.com/ Levy T (2020) Vaccinations, Vitamin C, Politics, and the Law. Orthomolecular Medicine News Service, January 20, 2020. http://orthomolecular.org/resources/omns/v16n05.shtml Levy T (2020) COVID-19: How can I cure thee? Let me count the ways. Orthomolecular Medicine News Service, July 18, 2020. http://orthomolecular.org/resources/omns/index.shtml Levy T (2021) Rapid Virus Recovery: No need to live in fear! Henderson, NV: MedFox Publishing. Free eBook download available at https://rvr.medfoxpub.com/ Levy T (2021) Hydrogen peroxide nebulization and COVID resolution. Orthomolecular Medicine News Service, May 10, 2021. http://orthomolecular.org/resources/omns/index.shtml Lima-Martinez M, Boada C, Madera-Silva M et al. (2021) COVID-19 and diabetes: a bidirectional relationship. Clinica e Investigacion en Arteriosclerosis 33:151-157. PMID: 33303218 Liu Y, Sawalha A, Lu Q (2021) COVID-19 and autoimmune diseases. Current Opinion in Rheumatology 33:155-162. PMID: 33332890 Maiti S, Banerjee A (2021) Epigallocatechin gallate and theaflavin gallate interaction in SARS-CoV-2 spike-protein central channel with reference to the hydroxychloroquine interaction: bioinformatics and molecular docking study. Drug Development Research 82:86-96. PMID: 32770567 McDonald L (2021) Healing after COVID-19: are survivors at risk for pulmonary fibrosis? American Journal of Physiology. Lung Cellular and Molecular Physiology 320:L257-L265. PMID: 33355522 Mendelson M, Nel J, Blumberg L et al. (2020) Long-COVID: an evolving problem with an extensive impact. South African Medical Journal 111:10-12. PMID: 33403997 Mishra A, Lal A, Sahu K et al. (2020) An update on pulmonary hypertension in coronavirus disease-19 (COVID-19). Acta Bio-Medica 91:e2020155. PMID: 33525228 Munoz J, Ballester M, Antonijoan R et al. (2018) Safety and pharmacokinetic profile of fixed-dose ivermectin with an innovative 18 mg tablet in healthy adult volunteers. PLoS Neglected Tropical Diseases 12:e0006020. PMID: 29346388 Pan B, Fang S, Zhang J et al. (2020) Chinese herbal compounds against SARS-CoV-2: puerarin and quercetin impair the binding of viral S-protein to ACE2 receptor. Computational and Structural Biotechnology Journal 18:3518-3527. PMID: 33200026 Pandey P, Rane J, Chatterjee A et al. (2020) Targeting SARS-CoV-2 spike protein of COVID-19 with naturally occurring phytochemicals: an in silico study for drug development. Journal of Biomolecular Structure & Dynamics Jul 22. Online ahead of print. PMID: 32698689 Perisetti A, Gajendran M, Mann R et al. (2020) COVID-19 extrapulmonary illness-special gastrointestinal and hepatic considerations. Disease-A-Month 66:101064. PMID: 32807535 Pasqualetto M, Sorbo M, Vitiello M et al. (2020) Pulmonary hypertension in COVID-19 pneumoniae: It is not always as it seems. European Journal of Case Reports in Internal Medicine 7:002160. PMID: 33457379 Perrotta F, Matera M, Cazzola M, Bianco A (2020) Severe respiratory SARS-CoV2 infection: Does ACE2 receptor matter? Respiratory Medicine 168:105996. PMID: 32364961 Pillay T (2020) Gene of the month: the 2019-nCoV/SARS-CoV-2 novel coronavirus spike protein. Journal of Clinical Pathology 73:366-369. PMID: 32376714 Potus F, Mai V, Lebret M et al. (2020) Novel insights on the pulmonary vascular consequences of COVID-19. American Journal of Physiology. Lung Cellular and Molecular Physiology 319:L277-L288. PMID: 32551862 Raveendran A (2021) Long COVID-19: Challenges in the diagnosis and proposed diagnostic criteria. Diabetes & Metabolic Syndrome: Clinical Research & Reviews 15:145-146. PMID: 33341598 Roth N, Kim A, Vitkovski T et al. (2021) Post-COVID-19 cholangiopathy: a novel entity. The American Journal of Gastroenterology 116:1077-1082. PMID: 33464757 Saha J, Raihan M (2021) The binding mechanism of ivermectin and levosalbutamol with spike protein of SARS-CoV-2. Structural Chemistry Apr 12. Online ahead of print. PMID: 33867777 Saponaro F, Rutigliano G, Sestito S et al. (2020) ACE2 in the era of SARS-CoV-2: controversies and novel perspectives. Frontiers in Molecular Biosciences 7:588618. PMID: 33195436 Sawalha K, Abozenah M, Kadado A et al. (2021) Systematic review of COVID-19 related myocarditis: insights on management and outcome. Cardiovascular Revascularization Medicine: Including Molecular Interventions 23:107-113. PMID: 32847728 Sehailia M, Chemat S (2020) Antimalarial-agent artemisinin and derivatives portray more potent binding to Lys353 and Lys31-binding hostpots of SARS-CoV-2 spike protein than hydroxychloroquine: potential repurposing of artenimol for COVID-19. Journal of Biomolecular Structure & Dynamics Jul 22. Online ahead of print. PMID: 32696720 Seymen C (2021) The other side of COVID-19 pandemic: effects on male fertility. Journal of Medical Virology 93:1396-1402. PMID: 33200417 Shang J, Wan Y, Luo C et al. (2020) Cell entry mechanisms of SARS-CoV-2. Proceedings of the National Academy of Sciences of the United States of America 117:11727-11734. PMID: 32376634 Wang N, Han S, Liu R et al. (2020) Chloroquine and hydroxychloroquine as ACE2 blockers to inhibit viropexis of 2019-nCoV spike pseudotyped virus. Phytomedicine: International Journal of Phytotherapy and Phytopharmacology 79:153333. PMID: 32920291 Yang J, Lin S, Ji X, Guo L (2010) Binding of SARA coronavirus to its receptor damages islets and causes acute diabetes. Acta Diabetologica 47:193-199. PMID: 19333547 Zeppa S, Agostini D, Piccoli G et al. (2020) Gut microbiota status in COVID-19: an unrecognized player? 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