Journeying through the human body used to exist only in Hollywood
fantasies think Fantastic Voyage or Innerspace.
Instead of injecting miniaturized humans piloting equally tiny submarines into
an unsuspecting person, however, real-life scientists send in specially
designed microscopic capsules (nanoparticles) in order to target diseased cells
or tissues. Omid Farokhzad, associate professor at
Harvard Medical School, and colleagues are developing such nanoparticles packed
with cancer-killing drugs to attack tumors while protecting the surrounding
healthy tissue. He explains how to send nanoparticles on this journey in just
five steps.
Step 1. Get it in blood
The nanoparticle needs to get into the bloodstream in order to circulate the body and find the cancer. Direct options include injections or intravenous hook ups. Indirect methods get them there through the lungs, skin or mouth.
The nanoparticle needs to get into the bloodstream in order to circulate the body and find the cancer. Direct options include injections or intravenous hook ups. Indirect methods get them there through the lungs, skin or mouth.
Step 2. Hide it
The human immune system has evolved over tens of thousands of years to recognize and clear foreign objects. This includes viruses, which happen to be around the same size as Farokhzad's synthetic nanoparticles. So, the immune system has to be tricked into thinking that the nanoparticle is native. One way to do this is to engineer the nanoparticle's surface to be hydrophilic, or water-loving, to blend in with the body's natural materials and thus trick the immune system into letting it pass.
The human immune system has evolved over tens of thousands of years to recognize and clear foreign objects. This includes viruses, which happen to be around the same size as Farokhzad's synthetic nanoparticles. So, the immune system has to be tricked into thinking that the nanoparticle is native. One way to do this is to engineer the nanoparticle's surface to be hydrophilic, or water-loving, to blend in with the body's natural materials and thus trick the immune system into letting it pass.
Step 3. Find the cancer
Next, the nanoparticle must find its target site: cancerous cells or tissues. Each cell type in the body has a molecular signature on its surface; cancer cells and normal cells have different signatures. In order to get the nanoparticle to recognize the cancer cell's signature, the particle's surface is decorated with molecules that can locate it and bind to only the tumor.
Next, the nanoparticle must find its target site: cancerous cells or tissues. Each cell type in the body has a molecular signature on its surface; cancer cells and normal cells have different signatures. In order to get the nanoparticle to recognize the cancer cell's signature, the particle's surface is decorated with molecules that can locate it and bind to only the tumor.
Step 4. Enter the cell
Like the Trojan horse delivering its warriors, the nanoparticle has to get inside the cancer cell before it can deliver its chemotherapy drugs. A cell typically recycles its membrane, pulling in proteins from the surface in order to break them down and make new proteins. The nanoparticle takes advantage of this, binding to proteins on the cell's surface, which the cell pulls in as it recycles itself.
Like the Trojan horse delivering its warriors, the nanoparticle has to get inside the cancer cell before it can deliver its chemotherapy drugs. A cell typically recycles its membrane, pulling in proteins from the surface in order to break them down and make new proteins. The nanoparticle takes advantage of this, binding to proteins on the cell's surface, which the cell pulls in as it recycles itself.
Step 5. Release the drugs
Once inside, the nanoparticle must break open in order for the drugs to come into contact with the cancerous cell. The interior of the cell is more acidic than its surroundings, so one option is to design the nanoparticle to degrade when exposed to a certain pH. Or, time capsules can release the medicine after a specific amount of time.
Once inside, the nanoparticle must break open in order for the drugs to come into contact with the cancerous cell. The interior of the cell is more acidic than its surroundings, so one option is to design the nanoparticle to degrade when exposed to a certain pH. Or, time capsules can release the medicine after a specific amount of time.
Not just anyone has what it takes to make a nanoparticle, let alone one
that can deliver chemotherapies to individual cells in the body. But, a lot of
school can help. Farokhzad has a background in molecular biology, medicine and
nanotechnology, and his team members come from the biology, chemistry, physics
and engineering fields.
And, if the Hollywood version ever comes true, you'll probably also need
a submarine pilot.
SOURCE - http://www.livescience.com/33472-how-get-inside-human-body.html
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