Transmission electron microscope images showing the structure of pores inside the nanotubes (left) and the inside of the particle (right), where cylindrical tubes form macropores to which the antigen adheres, reaching the immune system intact.

Nanotechnology delivers hepatitis B vaccine
2019-07-17
PT ES

X-ray imaging shows that nanostructured silica acts as protective vehicle to deliver antigen intact to intestine so that it can trigger an immune response. Material developed with FAPESP funding could give rise to polyvaccine against six diseases.

Nanotechnology delivers hepatitis B vaccine

X-ray imaging shows that nanostructured silica acts as protective vehicle to deliver antigen intact to intestine so that it can trigger an immune response. Material developed with FAPESP funding could give rise to polyvaccine against six diseases.

2019-07-17
PT ES

Transmission electron microscope images showing the structure of pores inside the nanotubes (left) and the inside of the particle (right), where cylindrical tubes form macropores to which the antigen adheres, reaching the immune system intact.

 

By André Julião*  |  Agência FAPESP – Brazilian and European researchers have demonstrated exactly how a nanotechnology-based compound delivers an oral vaccine against hepatitis B to the immune system. When particles containing silica and an antigen combine, even though they are different sizes, they reach the intestine without being destroyed by the acidity of the digestive system.

A compound of nanostructured SBA-15 silica and HBsAg, the hepatitis B surface antigen, was submitted to different types of X-ray imaging in European laboratories. The nanostructured silica was developed by researchers at the University of São Paulo’s Physics Institute (IF-USP) in Brazil. The antigen was created by Butantan Institute, also in São Paulo. 

The study was supported by FAPESP and European research funders. The results are published in Scientific Reports

The aim of the study was to understand how 22 nanometers-sized antigen binds to silica nanotubes with a diameter of about 10 nanometers and a honeycomb-like structure. One nanometer (1 nm) is a billionth of a meter. 

Studies carried out at USP revealed the measurements of both the antigen and the silica nanotubes using small-angle X-ray scattering (SAXS), dynamic light scattering (DLS), and transmission electron microscope.

Previous research by the group showed that the antigen did not enter the nanotubes because it has a diameter of 22 nm, more than twice that of the SBA-15. 

“Despite the size difference, tests [in animals] produced an excellent immune response to the oral vaccine – as good as the injectable form or better,” said Márcia Fantini, Full Professor at IF-USP.

X-ray and neutron imaging was coordinated by Heloisa Bordalo, a Brazilian researcher at the University of Copenhagen’s Niels Bohr Institute in Denmark. In collaboration with other researchers in Denmark, as well as colleagues in France, Germany, Sweden and Switzerland, Bordalo submitted the compound to scanning transmission X-ray microscopy (STXM), among other techniques.

Three-dimensional images obtained by these techniques showed that although the antigen did not enter the nanotubes, it was retained in 50 nm macropores between nanotubes. This protected it from the acidity of the digestive system. 

The images also enabled the researchers to determine the ideal proportion of silica and HBsAg so that the antigen did not agglomerate, hindering dispersion of the active principle in the patient’s intestine. 

“The oral and intranasal routes are natural modes of vaccine administration. Nature is the best vaccination agent. However, a vaccine that contains a protein, as in this case, is destroyed by high acidity and its own proteases in passing through the stomach, so it doesn’t reach the immune system, particularly the small intestine,” said Osvaldo Augusto Sant’Anna, Scientific Leader at Butantan Institute and responsible for development of the HbsAg antigen. 

Before proceeding to clinical trials, the team will test polymers that can be used to coat the entire structure and increase the medication’s resistance to the human stomach. In animal trials the formulation proved as effective as the injected vaccine, if not more so, in delivering the antigen to the intestine, where the immune system can detect it and produce antibodies against the virus. 

According to the World Health Organization (WHO), about 257 million people currently live with hepatitis B worldwide.

Polyvaccine

Through a project supported by FAPESP, the group led by Sant’Anna, Fantini and Bordalo are now developing new antigens to add to the compound. The idea is to have at least a triple vaccine by adding others against diphtheria and tetanus. 

However, the formulation may evolve to become a polyvaccine that also immunizes people against whooping cough, poliomyelitis and Haemophilus influenzae type B (Hib), the bacterium that causes meningitis and pneumonia, among other diseases.

The antigens must combat the diseases without interfering with each other. “There have been very interesting results with diphtheria, and we’re now going to test it for tetanus, initially in injectable form,” Sant’Anna said.

The article “3D visualization of hepatitis B vaccine in the oral delivery vehicle SBA-15” (doi: 10.1038/s41598-019-42645-5) by Martin K. Rasmussen, Nikolay Kardjilov, Cristiano L. P. Oliveira, Benjamin Watts, Julie Villanova, Viviane Fongaro Botosso, Osvaldo A. Sant’Anna, Marcia C. A. Fantini and Heloisa N. Bordallo can be read at: www.nature.com/articles/s41598-019-42645-5

* José Tadeu Arantes contributed to this story.

 
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