- Messages
- 15,793
- Reaction score
- 10,096
- Points
- 288
ivermectin does as well
Peter A. McCullough, MD, MPH™
Feb 21
By Peter A. McCullough, MD, MPH
Far and away the most common question I get from those who took one of the COVID-19 vaccines is: “how do I get this out of my body.” The mRNA and adenoviral DNA products were rolled out with no idea on how or when the body would ever breakdown the genetic code. The synthetic mRNA carried on lipid nanoparticles appears to be resistant to breakdown by human ribonucleases by design so the product would be long-lasting and produce the protein product of interest for a considerable time period. This would be an advantage for a normal human protein being replaced in a rare genetic deficiency state (e.g. alpha galactosidase in Fabry’s disease). However, it is a big problem when the protein is the pathogenic SARS-CoV-2 Spike. The adenoviral DNA (Janssen) should broken down by deoxyribonuclease, however this has not be exhaustively studied.
This leaves dissolution of Spike protein as a therapeutic goal for the vaccine injured. With the respiratory infection, Spike is processed and activated by cellular proteases including transmembrane serine protein 2 (TMPRSS2), cathepsin, and furin. With vaccination, these systems may be avoided by systemic administration and production of Spike protein within cells. As a result, the pathogenesis of vaccine injury syndromes is believed to be driven by accumulation of Spike protein in cells, tissues, and organs.
more
petermcculloughmd.substack.com
Dissolution of Spike Protein by Nattokinase
Holy Grail of COVID-19 Vaccine Detoxification
Peter A. McCullough, MD, MPH™
Feb 21
By Peter A. McCullough, MD, MPH
Far and away the most common question I get from those who took one of the COVID-19 vaccines is: “how do I get this out of my body.” The mRNA and adenoviral DNA products were rolled out with no idea on how or when the body would ever breakdown the genetic code. The synthetic mRNA carried on lipid nanoparticles appears to be resistant to breakdown by human ribonucleases by design so the product would be long-lasting and produce the protein product of interest for a considerable time period. This would be an advantage for a normal human protein being replaced in a rare genetic deficiency state (e.g. alpha galactosidase in Fabry’s disease). However, it is a big problem when the protein is the pathogenic SARS-CoV-2 Spike. The adenoviral DNA (Janssen) should broken down by deoxyribonuclease, however this has not be exhaustively studied.
This leaves dissolution of Spike protein as a therapeutic goal for the vaccine injured. With the respiratory infection, Spike is processed and activated by cellular proteases including transmembrane serine protein 2 (TMPRSS2), cathepsin, and furin. With vaccination, these systems may be avoided by systemic administration and production of Spike protein within cells. As a result, the pathogenesis of vaccine injury syndromes is believed to be driven by accumulation of Spike protein in cells, tissues, and organs.
more
Dissolution of Spike Protein by Nattokinase
Holy Grail of COVID-19 Vaccine Detoxification
petermcculloughmd.substack.com