From Our Partners
Wednesday, June 29, 2022
News on Pathogens and Preparedness
Global Biodefense
  • Featured
  • COVID-19
  • Funding
  • Directory
  • Jobs
  • Events
  • Subscribe
No Result
View All Result
  • Featured
  • COVID-19
  • Funding
  • Directory
  • Jobs
  • Events
  • Subscribe
No Result
View All Result
Global Biodefense
No Result
View All Result
Home Medical Countermeasures

Pills of the Future: Nanoparticles

by Global Biodefense Staff
December 2, 2013

Researchers from MIT and Brigham and Women’s Hospital (BWH) have developed a new type of nanoparticle that can be delivered orally and absorbed through the digestive tract, allowing patients to simply take a pill instead of receiving injections.

The researchers used the particles to demonstrate oral delivery of insulin in mice, but they say the particles could be used to carry any kind of drug that can be encapsulated in a nanoparticle. The new nanoparticles are coated with antibodies that act as a key to unlock receptors found on the surfaces of cells that line the intestine, allowing the nanoparticles to break through the intestinal walls and enter the bloodstream.

This type of drug delivery could be especially useful in developing new treatments for conditions such as high cholesterol or arthritis. Patients with those diseases would be much more likely to take pills regularly than to make frequent visits to a doctor’s office to receive nanoparticle injections, say the researchers.

Several types of nanoparticles carrying chemotherapy drugs or short interfering RNA, which can turn off selected genes, are now in clinical trials to treat cancer and other diseases. These particles exploit the fact that tumors and other diseased tissues are surrounded by leaky blood vessels. After the particles are intravenously injected into patients, they seep through those leaky vessels and release their payload at the tumor site.

For nanoparticles to be taken orally, they need to be able to get through the intestinal lining, which is made of a layer of epithelial cells that join together to form impenetrable barriers called tight junctions.

“The key challenge is how to make a nanoparticle get through this barrier of cells. Whenever cells want to form a barrier, they make these attachments from cell to cell, analogous to a brick wall where the bricks are the cells and the mortar is the attachments, and nothing can penetrate that wall,” Farokhzad says.

Researchers have previously tried to break through this wall by temporarily disrupting the tight junctions, allowing drugs through. However, this approach can have unwanted side effects because when the barriers are broken, harmful bacteria can also get through.

To build nanoparticles that can selectively break through the barrier, the researchers took advantage of previous work that revealed how babies absorb antibodies from their mothers’ milk, boosting their own immune defenses. Those antibodies grab onto a cell surface receptor called the FcRN, granting them access through the cells of the intestinal lining into adjacent blood vessels.

The researchers coated their nanoparticles with Fc proteins — the part of the antibody that binds to the FcRN receptor, which is also found in adult intestinal cells. The nanoparticles, made of a biocompatible polymer called PLA-PEG, can carry a large drug payload, such as insulin, in their core.

After the particles are ingested, the Fc proteins grab on to the FcRN in the intestinal lining and gain entry, bringing the entire nanoparticle along with them.

“It illustrates a very general concept where we can use these receptors to traffic nanoparticles that could contain pretty much anything. Any molecule that has difficulty crossing the barrier could be loaded in the nanoparticle and trafficked across,” Karnik says.

Breaking through barriers

In this study, the researchers demonstrated oral delivery of insulin in mice. Nanoparticles coated with Fc proteins reached the bloodstream 11-fold more efficiently than equivalent nanoparticles without the coating. Furthermore, the amount of insulin delivered was large enough to lower the mice’s blood sugar levels.

The researchers now hope to apply the same principles to designing nanoparticles that can cross other barriers, such as the blood-brain barrier, which prevents many drugs from reaching the brain.

“If you can penetrate the mucosa in the intestine, maybe next you can penetrate the mucosa in the lungs, maybe the blood-brain barrier, maybe the placental barrier,” Farokhzad says.

They are also working on optimizing drug release from the nanoparticles in preparation for further animal tests, either with insulin or other drugs.

The research was funded by a Koch-Prostate Cancer Foundation Award in Nanotherapeutics; the National Cancer Institute Center of Cancer Nanotechnology Excellence at MIT-Harvard; a National Heart, Lung, and Blood Institute Program of Excellence in Nanotechnology Award; and the National Institute of Biomedical Imaging and Bioengineering.

Read the paper at Science Translational Medicine: Transepithelial Transport of Fc-Targeted Nanoparticles by the Neonatal Fc Receptor for Oral Delivery

From Our Partners
Tags: Nanotech

Related Posts

UK Health Security Agency Widens Monkeypox Vaccine Umbrella for Outbreak Control
Medical Countermeasures

UK Health Security Agency Widens Monkeypox Vaccine Umbrella for Outbreak Control

June 21, 2022
Biodefense Industry News
Industry News

Tonix Pharmaceuticals Opens Advanced Development Center for Vaccine Programs

June 20, 2022
Monkeypox Cases Prompt Additional Contracts for Bavarian Nordic Vaccine
Medical Countermeasures

Monkeypox Cases Prompt Additional Contracts for Bavarian Nordic Vaccine

May 30, 2022
Novavax Missed Its Global Moonshot but Is Angling to Win Over mRNA Defectors
Industry News

Novavax Missed Its Global Moonshot but Is Angling to Win Over mRNA Defectors

May 26, 2022
Load More

Latest News

Poliovirus Detected in London Sewage: Response Measures Emphasize Wastewater Surveillance and Vaccination Gaps

Poliovirus Detected in London Sewage: Response Measures Emphasize Wastewater Surveillance and Vaccination Gaps

June 22, 2022
Monkeypox Diagnostics: CDC Authorizes Five Commercial Lab Companies

Monkeypox Diagnostics: CDC Authorizes Five Commercial Lab Companies

June 22, 2022
UK Health Security Agency Widens Monkeypox Vaccine Umbrella for Outbreak Control

UK Health Security Agency Widens Monkeypox Vaccine Umbrella for Outbreak Control

June 21, 2022
Influenza Research

New Way to Identify Influenza A Virus Lights Up When Specific Virus Targets are Present

June 20, 2022

Subscribe

  • About
  • Contact
  • Privacy
  • Subscribe

© 2022 Stemar Media Group LLC

No Result
View All Result
  • Featured
  • COVID-19
  • Funding
  • Directory
  • Jobs
  • Events
  • Subscribe

© 2022 Stemar Media Group LLC