"Thuốc chích ngừa" cúm tàu cộng có nam châm

Dạo này trên tờ quát những người đã tiêm "thuốc ngừa" cô vịt mang lên nhiều chuyện lạ lắm. Mình có xem qua vài clips người ta máy đo từ trường để đo trên người, wow cây kim nhảy quá trời luôn.  

Mình mới đi vô thư viện của viện nghiên cứu n Ị h, tìm được tài liệu này, mình gửi bạn đọc cho biết thêm nhé

Lâu lắm rồi mình có nghe ai nói, hình như là Mạ mình, bảo ngoài chợ có bán loại nam châm, mang vào cổ tay sẽ bớt bịnh, bịnh gì thì mình hông biết. Nay nhân dịp đọc vụ ca'c chất kết hợp để tạo ra nam châm trong chích ngừa cúm tàu, không biết chiếc vòng tay đó có hút nam châm từ trong người ra được không nhỉ?

Mời Quý khách bấm lên nút xanh "play" để xem.

The quackccinated are now radioactive and producing Electromagnetic Fields (EMF's). Come the next flu season we are going to see a Holocaust with millions dead from the jabs ... you still think this is a conspiracy theory then wait until next winter. #vaccinated pic.twitter.com/1I44mXge5z

— The Guardians Federation 🇵🇸 (@theguardiansfed) May 21, 2021

National Library of Medicine: Superparamagnetic nanoparticle delivery of DNA vaccine

Fatin Nawwab Al-Deen 1, Cordelia Selomulya, Charles Ma, Ross L Coppel

Affiliations expand

PMID: 24715289 DOI: 10.1007/978-1-4939-0410-5_12

Abstract

The efficiency of delivery of DNA vaccines is often relatively low compared to protein vaccines. The use of superparamagnetic iron oxide nanoparticles (SPIONs) to deliver genes via magnetofection shows promise in improving the efficiency of gene delivery both in vitro and in vivo. In particular, the duration for gene transfection especially for in vitro application can be significantly reduced by magnetofection compared to the time required to achieve high gene transfection with standard protocols. 

SPIONs that have been rendered stable in physiological conditions can be used as both therapeutic and diagnostic agents due to their unique magnetic characteristics. Valuable features of iron oxide nanoparticles in bioapplications include a tight control over their size distribution, magnetic properties of these particles, and the ability to carry particular biomolecules to specific targets. The internalization and half-life of the particles within the body depend upon the method of synthesis. Numerous synthesis methods have been used to produce magnetic nanoparticles for bioapplications with different sizes and surface charges. 

The most common method for synthesizing nanometer-sized magnetite Fe3O4 particles in solution is by chemical coprecipitation of iron salts. The coprecipitation method is an effective technique for preparing a stable aqueous dispersions of iron oxide nanoparticles. We describe the production of Fe3O4-based SPIONs with high magnetization values (70 emu/g) under 15 kOe of the applied magnetic field at room temperature, with 0.01 emu/g remanence via a coprecipitation method in the presence of trisodium citrate as a stabilizer. Naked SPIONs often lack sufficient stability, hydrophilicity, and the capacity to be functionalized. 

In order to overcome these limitations, polycationic polymer was anchored on the surface of freshly prepared SPIONs by a direct electrostatic attraction between the negatively charged SPIONs (due to the presence of carboxylic groups) and the positively charged polymer.

 Polyethylenimine was chosen to modify the surface of SPIONs to assist the delivery of plasmid DNA into mammalian cells due to the polymer's extensive buffering capacity through the "proton sponge" effect.