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New ways to keep cancer from spreading

By Lee Euler / August 20, 2017

One reason cancer is so deadly is its ability to spread throughout the body, in a process known as metastasis. In fact, your chance of surviving cancer is pretty good as long as it’s confined to its original site. It’s metastatic cancer that kills.

This means that understanding how cancer spreads is a key to developing better treatment options…

Researchers have been studying this phenomenon for more than 100 years, with very little ground gained. But that may be about to change. Mainstream medicine has made some promising discoveries regarding cancer metastasis and possible ways to prevent it.

Read on to discover these hopeful new developments…

Continued below…

Breast Cancer Survivor was told:
“You’ll be dead in a year”
(Pssst!! That was 12 years ago!)

Doctors didn’t give Wiltrude much hope when they diagnosed her with cancer in the year 2000. Wiltrude, a German psychologist, never thought cancer would happen to her. But it did. And it came as a big shock.

One doctor told her, “You’ll be dead in a year.” Late stage breast cancer is virtually incurable using conventional treatments. Even M.D.s admit it. They talk about “buying you more time.” (Don’t count on it. The evidence shows you’re better off doing nothing than chemo.)

When Wiltrude told her doctor she was going to try alternative treatments, he said, “You are committing suicide with what you’re doing.” But she was determined to find a way to beat her cancer.

Thanks to the wonders of the Internet, this European woman came across a book by my good friend, the late Bill Henderson, one of the smartest and wisest people I’ve ever known when it comes to cancer treatment.

She tried Bill’s top, number one recommendation — a gentle treatment you can do at home for just $5.15 a day. What’s more, the cost goes down to $3.50 after six weeks because you just need a maintenance dose. And it even tastes good.

Not only has Wiltrude passed the five-year cancer survival mark, she’s survived for 12 years. We just interviewed her recently for this publication. The radiologist who tests her every year told her, “You’re the only one with this kind of result.”

You can find out more about Bill’s proven cancer treatment plan if you click here.

I remember one time when I asked Bill about some of the treatments that top alternative doctors use, he sort of shrugged and said, “They’re fine, but why bother? My treatment works, you can do it yourself, and it costs practically nothing.”

During his long, productive life, Bill coached thousands of cancer patients with all different types and stages of cancer. Most of the people who follow the detailed, specific plan in this Special Report get over their cancer and live for years.

“Almost any kind of cancer is reversible,” Bill said. “I never give up on anyone.”

Click here to learn more about Bill’s amazing cancer protocol.

Understanding the enemy: How metastasis works

Cancer is industrious. A tumor can send cancer cells into the bloodstream constantly, looking for new places to gain traction and set up shop.

Cancer often makes its first move into nearby tissues and lymph nodes. The cancer cells can then create new blood vessels, a process called angiogenesis, to support the spread to distant tissues and organs throughout the body.

Once cancer sets up in a new location, it can repeat the process, and so on again and again until cancer spreads all over.

While some types of tumors are capable of forming metastases in virtually every organ in the body, the most frequent target organs of metastasis are bone, brain, liver, and lung.1 Once the cancer reaches these organs it’s late-stage cancer. It’s much more difficult, if not impossible, to treat.

Altering the Soil:
Using the body to stop the spread of cancer

One theory about metastasis that has held sway for a number of years is the “seed and soil” hypothesis. Developed by Stephan Paget in 1889, it states “that metastasis depends on cross-talk between selected cancer cells (the ‘seeds’) and specific organ microenvironments (the ‘soil’).”2

So like seeds and soil, as long as the body environment supports cancer cells, they’ll continue to grow and spread.

Breast cancer

In a study published in the online journal PLOS in June 2017, researchers turned their attention to the tumor microenvironment for answers.

They found a metabolite in the body called 20-Hydroxyeicosatetraenoic acid (20-HETE) plays a role in helping cancer to spread. 20-HETE naturally occurs in the body and is necessary for metabolism, sodium and fluid transport to the kidneys, and regulating blood flow to the organs, among other processes.

Unfortunately, cancer cells can also use 20-HETE in angiogenesis, which scientists think is the precondition needed for cancer cells to travel throughout the body.

In the presence of cancer, 20-HETE also increases chronic inflammation, making the body environment a perfect place for disease to flourish.

To test a theory, the researchers inserted breast cancer cells into mice. Breast cancer tends to metastasize to the bones, brain, liver and lungs. Once the cancer established itself and started to spread (about 15 days), they injected the mice with a molecule called HET0016, which inhibits parts of 20-HETE activity.

They gave the mice a dose of this substance five days a week for three weeks. At the end of the study they discovered that administration of HET0016. . .

  • Decreased tumor volume and lung metastasis
  • Reduced migration and invasion of tumor cells in the lungs
  • Decreased the number of pro-inflammatory cytokines and other elements that contribute to tumor growth in the lung microenvironment.3

These results show that HET0016 may be a promising way to stop breast cancer metastasis to the lungs.

Pancreatic cancer

In a study published in the July 2016 issue of the journal Cancer Research, scientists tested the efficacy of HET0016 on 20-HETE in pancreatic cancer cells. They focused on the inflammatory processes associated with 20-HETE, because prolonged and unresolved inflammation is associated with the development of pancreatic cancer.

Using in vitro methods, they added 20-HETE to pancreatic cancer cells and discovered it promoted pancreatic tumor growth and spontaneous metastasis. They also found that pancreatic cancer cells produce more 20-HETE than healthy cells.

Too much 20-HETE leads to over-expression of an enzyme that attracts macrophages, immune cells that are associated with increased malignancy in a tumor microenvironment.4

But when they treated the cells with HET0016, it reduced macrophage migration toward pancreatic cancer cells. This made the microenvironemnt less hospitable to the cancer cells and reduced the spread.

The researchers concluded that treating 20-HETE with HET0016 reduced inflammation, tumor growth and metastasis and could be used as a new treatment for pancreatic cancer.5

Immobilizing the cancer cells themselves

Researchers are exploring advancements in nanotechnology, the area of science that focuses on the manipulation of individual atoms and molecules, to stop cancer metastasis.

Scientists can reduce the size of certain materials to nanoscale, which is much smaller than the eye can see. You could almost say it’s infinitely smaller than what we can see. One nanometer (nm) is one billionth of a meter. A single water molecule is about 1.5 nanometers; a single strand of human hair is about 80,000 to 100,000 nanometers.6

The outside edges of all cells contain broad fibers called lamellipodia. They’re like little legs that help the cells move throughout the body as needed. (The suffix “-podia” means “foot” or “footlike,” from Greek.)

But cancer cells also contain an extra protrusion off the lamellipodia, called filopodia. Cancer cells produce both kinds of “feet” in excess, which means they can move faster and more efficiently than healthy cells.

So researchers are testing the use of gold nanorods on these “cancer feet” to stop the spread of cancer cells.

A nanorod is an element that ranges in size from one to 100 nm. Scientists reduce the element gold down to this tiny size, at which point the gold nanoparticles display different physical and chemical properties.

In a study published in May 2017, researchers at the Georgia Institute of Technology in Atlanta injected gold nanorods into cancer cells. When they did this, they found it delayed the migration of the cells. In essence, it hobbled the “cancer feet” so they couldn’t move very fast.

The researchers added another step of heating the gold nanorods with a laser to near-infrared light. This effectively stopped the movement of the cancer cells altogether.7

In another study, researchers at the same lab tested this method in a mouse model and found the gold nanorods induced apoptosis (natural death) in cancer cells, without affecting the nearby healthy cells. They also performed a 15-month follow-up and found no long-term toxicity in the mice.8

This treatment could be a vast improvement over chemotherapy and other treatments that destroy healthy and cancerous cells indiscriminately.

So that’s what’s happening in the world of Big Science. I hope these treatments eventually come to market and help patients. Meanwhile, our last issue talked about a natural treatment you can put to work against cancer right now. It’s one of the more effective steps you can take, and it’s good for prevention, too.

Best regards,

Lee Euler,
Publisher

References:
1 The seed and soil hypothesis revisited – the role of tumor-stroma interactions in metastasis to different organs.
2 The pathogenesis of cancer metastasis: The ‘seed and soil’ hypothesis revisited.
3 HET0016 decreases lung metastasis from breast cancer in immune-competent mouse model.
4 Abstract A13: Macrophage FLT1 mediated inflammatory response determines breast cancer distal metastasis.
5 Targeting the eicosanoid 20-HETE suppresses pancreatic cancer growth and metastasis through regulation of inflammation.
6 Examples of nanoscale.
7 Targeting cancer cell integrins using gold nanorods in photothermal therapy inhibits migration through affecting cytoskeletal proteins.
8 Efficacy, long-term toxicity, and mechanistic studies of gold nanorods photothermal therapy of cancer in xenograft mice.
About the author

Lee Euler

Hi I'm Lee Euler, I’ve spent over a decade investigating every possible way a person can beat cancer. In fact, our commitment to defeating cancer has made us the world’s #1 publisher of information about Alternative Cancer Treatments -- with over 20 books and 700 newsletters on the subject. If you haven't heard about all your cancer options, or if you want to make sure you don’t miss even one answer to this terrible disease, then join our newsletter. When you do, I'll keep you informed each week about the hundreds of alternative cancer treatments that people are using to cure cancer all over the world.

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