Miraculos Natural Cancer Cell Killer

Guybano (Annona Muricata Linnaeus) The Soursop Fruit

A miraculos natural cancer cell killer, 10,000x stronger than chemotherapy. Unlike chemotherapy the compound extracted from guyabano selectively hunts down and kills only cancer cells. It does not harm healthy cells, it only effectively targets and kills malignant cells in 12 types of cancer. The extracts from guyabano can attack cancer safely and effectively with an all-natural therapy that does not cause extreme nausea and hair loss. It protects your immune system and avoids deadly infections; feels stronger and healthier throughout the course of the treatment and boost your energy and improves your outlook in life. Guyabano powder extract is also taken as a remedy for urethritis, haematuria and liver ailments.

Guyabano belongs to the family of  Annonaceae, (A. muricata L.) The flesh of the fruit consist of a white edible pulp  that is high in carbohydrates and considerable amounts of Vitamin C, Vitamin B1, Vitamin B2, Potassium and dietary fiber. It is low in cholesterol, saturated fat and sodium.


The US National Cancer Institute reportedly performed the first scientific research on guyabano in 1978 and the result showed guyabano very effectively in attacking and destroying malignant cells.

Nutrients that can be had from Guyabano extract:
Calories, Protein, Fat, Carbohydrates, Fiber, Ash, Calcium, Phosphorus, Potassium, Iron, Vitamin A, Vitamin C, Thiamine, Riboflavin, Niacin, Trytophan, Methionine and Lysine.

Razor Clam - Digging Skill

The razor clam burrows into hard-packed ground so quickly that it has been called " the Ferrari of underwater diggers." Although it appears to lack sufficient strength to dig through sand!

The razor clam wiggles its foot down into the sand, creating a small pocket that quickly fills with water and sand. The clam then moves its body up and down while opening and closing its shell. This results in watery mixture that the clam can easily dig. It can dig some 28 inches at a speed of 0.4 inch per second. Once dug in, the clam is hard to pull out. In fact, considering its anchoring force and the amount of energy it uses to embed itself, it is ten times more efficient than the best anchors made by man.

Engineers have been inspired by the razor clam in designing what they call the first "smart" anchor. It opens and closes, and moves up and down, like a real clam.Such a strong, energy-efficient anchor could be useful on underwater research vessels, floating oil rigs, and digging devices that destroy mines.

What do you think? Did the razor clam's digging skills come about by chance? Or was it designed?

Mighty Oak Tree

Amazingly, from a tiny acorn grows to a mighty oak! It can live more than a thousand years and reach 130 feet in height and more than 40 feet in girth.Worldwide there are about 450 varieties. What identifies them all is their seed, the tiny acorn.

Oak timber is exceptionally strong and durable. It has long been a favorite for building houses and making fine furniture. It is ideal for making barrels in which to age beer and wine. And sturdy sailing ships built of oak helped the British Navy to dominate the seas for many years.

Oak timber is still valued. And the tree, is justly admired for its strength, dependability, and endurance. From a tiny acorn grows a mighty oak - yet another marvel of creation!

What can we learn from birds?

Ask Please, the Winged Creatures...

Everything about birds appears to be designed for flight. For example, the shafts of wing feathers, it's bones and the muscles.

How can the wings be so light yet so strong?

It resembles what engineers call a foam-sandwich beam. It has a pithy interior and a rough exterior. Engineers have studied feather shafts, and foam-sandwich beams are used in aircraft.

What about the bones?

It's bones are also amazingly designed. Most are hollow, and some maybe strengthened by internal struts in a form engineers call the Warren girder. Interestingly, a similar design was used in the wings of the space shuttle.

Muscles?

Well, a pilot balance modern aircraft by adjusting a few flaps on the wings and tail. But a bird uses some 48 muscles in its wing and shoulder to change the configuration and motion of its wings and individual feather, doing so several times a second. No wonder that avian aerobatic ability is the envy of aircraft designers!