Secret Sounds That Heal
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After reading this article, you may have a new appreciation for your cat.
 Elizabeth
Von Muggenthaler is a research scientist and bio-acoustic specialist
who has gone where no man (or woman) has gone before - into the mysterious
realm of the healing power of a cat's purring, the haunting whale-song
of the Sumatran rhino, and about the sounds that we feel but never hear.
She is also president of Fauna
Communication Research Institute, where amazing breakthroughs are
being made that may forever change the way we listen to the animals.
Elizabeth was truly delightful to speak with. Her love and devotion to
animals came through quite clearly during our interview. In fact, she was
walking one of her beloved horses throughout most of our conversation and spoke
to me from her cell phone.
One of the most remarkable things I experienced when first contacting
Elizabeth were some of the sounds that play on her research web site. In
particular, I was fascinated with the sounds of the Sumatran Rhinoceros. I had
no idea that a Rhinoceros could sound so similar to the sounds of a humpback
whale. It was eerie and intriguing at the same time.
When I asked her about these sounds, there was a noticeable sadness in her
voice. According to Elizabeth, the Sumatran Rhinoceros is the oldest living
rhino. They're called the wooly rhinoceros, and there are only about 200 of them
left in the world. Poaching and habitat encroachment have devastated them. They
stand about four feet tall - no higher than your shoulder - so they're small and
furry, and they sing like whales. These Rhinos are near and dear to Elizabeth.
It's easy to tell that she loves them.
There is a unique parallel between rhino's and whales
When she went on to study the analysis of the sound recordings of these
rhinos, she realized that she had seen this type of signal before. Help came
from Jim Darling, who is one of the foremost authorities on humpback whales and
has done a lot of research on their song. He sent her a tape of the sounds of
the humpback whale, and indeed, there were amazing similarities. Under analysis,
allowing for the fact that one animal is underwater, the signal analysis of the
sounds is very close.
Elizabeth actually calls their continuous sounds "whale song," and within
those sounds are little "eeps" and other noises, like whistle blows. But the
majority of sounds are really very much like whale songs. She spoke with various
paleontologists about it. Some said they didn't know, stating that the
whale and the rhinoceros are not considered to be related. However, she did find
other paleontologists who held the theory that rhinos and whales are related,
and that her research analysis on their song adds support to their theories.
Besides, there is something called an ancestral song. It's never been formulated
into a scientific fact, but among certain mammals the elements of a basic song
are found. Some of it or all of it sounds very much like whale song. The sounds
of the Sumatran rhino may be linked to this ancestral song.
In the wild, these rhinos are supposedly solitary and rarely seen together.
It's really curious that such a solitary creature has developed such an
extensive repertoire. They like to lie in their mud wallows and sing. Elizabeth
believes that it is some sort of meditation. When she watches them, they will
stand there singing in their little mud wallow and being really peaceful. She
can't help but feel that while they're doing this they are somehow singing with
the forest and connecting with the Earth. She gets emotional about them and
their beauty, reminding me that there are only around 200 left in the world, and
not much is being done about that. It's heart-breaking that these wonderful
creatures may eventually be lost to us. I noticed my reaction to hearing the
rhino's song on her website. I had never heard such a thing. Especially when I
heard the loud popping noise, which sounds exactly like a whale forcing air
through its blowhole. Elizabeth says that this is the whistle blow the rhinos
make, its very low frequency and it carries for miles.
They are found only on the Island of Sumatra. There are only eight in
captivity. Three or four are in the United States now. They do not do well in
captivity. They are protected, however poaching laws are not being enforced
because there is no money to fund that. And since the average person has never
even heard that they exist, much less heard them sing, there is no public
awareness of what's happening to them.
Sounds we feel but cannot hear
In analyzing the sounds of animals, very specific equipment is used. At Fauna
Communications Research Institute, they have developed a unique system that
records signal analysis called "Polynesia." It's a "virtual instrument program"
that can measure anything. It's an amazing system. Fauna Research also studies
sounds that are below the normal range of human hearing - called infrasound.
This is so interesting, and most people don't know about infrasound. An example
of infrasound can be seen when you're in your car stopped at a traffic light,
and you look over and see that the car next to you is shaking because the music
is so loud. It's the infrasound that's making the car shake. It's below our
normal range of hearing.
The range of human hearing is technically, between 20 and 20,000 hertz.
Infrasound is below 20 hertz. It's been documented that one 19-year-old girl
could hear at 19 hertz, but the average person - who has been exposed to car
noises, loud noises, and maybe a rock concert or two - is probably hard pressed
to hear below 30 or 40 hertz. Another example of how infrasound affects people
is in car sickness. The reason some one gets car sick is not always that the car
is moving. Car sickness is sometimes caused by the car's vibration - around 4
hertz.
In fact, cars are interesting; you get all kinds of low-frequency vibrations
from them - 4 hertz, 7 hertz - that kind of thing. Frequencies of 7 hertz can
cause osteoporosis. Low frequencies like 18 hertz can cause dizziness,
blackouts, and feelings of terror. There is a theory that some ghost hauntings
are actually caused by low-frequency vibrations of around 18 hertz in a
building. That's a fairly common frequency in structures. Tigers roar at around
18 hertz. It doesn't matter that you can't see the tiger. Just hearing the sound
is pretty terrifying. I had read an article that the roar of a tiger may
actually paralyze its victim. Elizabeth says that this hasn't been proven.
Nevertheless, when she and her researchers recorded the exact frequency of the
tiger's range they found that its highest frequency is right around 18 hertz. So
theoretically the tiger's roar could cause temporary paralysis, weakening of the
muscles, feelings of terror, coldness, blackouts, and headaches - that kind of
thing.
Infrasound can penetrate solid objects like walls and even go through
mountains.
How does it do that? To begin with, ultrasound is a short wave. Take a pen
and draw waves up and down, up and down, and make them close together. That's an
illustration of an ultrasound wave. This shape and wavelength causes the sounds
to bounce off objects. That's why this sound frequency is used for sonar, and
why bats and dolphins use it for eco-location. Low frequency or infrasound is a
very long wave. Take your pen and draw a nearly straight line. That's how an
infrasound signal looks. This is why infrasound can travel through buildings,
mountains, etc., because the wave of infrasound is a long wave that actually
goes between particles and molecules of an object rather than bouncing off them.
An interesting thing happens when the space shuttle takes off: it creates
infrasound that travels the earth about seven times before it dissipates. In
fact, if you go about 30 miles south of Coco Beach there's a little place called
Satellite Beach where there is a hotel built mostly of glass. If you are in one
of those rooms when the space shuttle is taking off, you will see the panes of
glass bow inward about two-and-a-half inches!
Lots of things create infrasound: wind, building movement, trains going by,
planes flying overhead, vehicles on the interstate. Why isn't there more study
in this area?
People have the tendency to believe that if you can't hear it and see it then
no one else can, either. There is a lot of skepticism to this day in the
bio-acoustic field. But scientists are becoming a little bit more open minded
than they used to be. I was curious to know if human's were capable of creating
infrasound. Elizabeth said that she didn't know. However, in some of her studies
- and this is something she would like to pursue further - that people who
practice certain forms of yoga or martial arts use sound to strengthen their
muscles. Our chest cavities are perfectly capable of humming at around 25 hertz;
they could vibrate at that frequency. Our voice isn't going to make infrasound,
but our chest, diaphragm, and lungs might. If her research could prove that
humans can create that frequency, yoga practitioners who use the Om sound might
be able to claim scientifically that they were doing healing.
Now we get to the exciting part: the Cat's Purr
Elizabeth's research into the cat's purr has brought her a great deal of
support from many sources, including veterinarians. She has also received
support from a professor emeritus in England who is known as the "grandfather of
bones." He is the foremost authority on bone density. She doesn't want to give
his name since she doesn't have his permission. Interestingly, he writes that
optimal frequency for bone stimulation is 50 hertz. The dominant and fundamental
frequency for three species of cats' purrs is exactly 25 to 50 hertz: the best
frequencies for bone growth and fracture healing.
The cat's purr falls well within the 20 - 50 hertz anabolic range, and
extends up to 140 hertz. All members of the cat family except cheetahs have a
dominant or strong harmonic at 50 hertz. The harmonics of three cat species fall
exactly on or within 2 points of 120 hertz, a frequency which has been found to
repair tendons.
A few veterinarians have said that the purr is only a vocalization of
contentment, and most people believe that. But Elizabeth's research analysis
shows it's not true. Cats will purr when they are injured and in pain as well as
when they are content. In one case, a cat had broken its femur and the femur was
sticking out. But it was purring, so it can be assumed that purring is not
always a sign of contentment. Some people claim that cats purr when they're
injured because they're humming to make themselves feel better. That makes
absolutely no sense. If you've ever broken your leg or an arm and you find
yourself in the emergency room, are you whistling "Dixie"?
Purring takes a lot of energy. It's created by both the diaphragm and the
larynx. Getting a diaphragm to move for something other than breathing is
difficult, it takes energy. When there is pain and suffering, our bodies are
traumatized and they shut down non-essential activity. Since cats purr when they
are severely injured or dying, it has to be survival-related.
Put a cat in a room with a bunch of broken bones - the bones will heal.
According to Elizabeth, that statement is an old veterinarian's adage and
it's still taught in veterinary schools to this day. That's the first thing she
came across when she started out with this research. But no one has done any
studies on it. The type of frequencies that are found in the cat's purr are good
for healing muscle, tendon, and ligament injuries, as well as for muscle
strengthening and toning. They are good for any type of joint injury, wound
healing, reduction of infection and swelling, pain relief, and relief of chronic
pulmonary disease.
Authors of the veterinarians' surgery manual say that what it basically comes
down to is that, compared to other animals, cats simply don't get chronic
pulmonary disease, muscle and tendon injuries, bone diseases, and a lot of other
things that dogs get. The purr seems to be a constant strengthener and toner for
the muscles. The average health of cats is considered to be greater than that of
dogs. An actual case study was done where they took 52,000 animals and found
that lameness in dogs occurred 3.6 percent and in cats only .26 percent. In
another study, arthritis in dogs was listed as 2.4 percent of the population,
and was not reported at all in cats. The prevalence of lameness in dogs occurred
3.1 percent of the time, and again, in cats it was not even mentioned. The
overall incidence of primary lung tumors in the dog is 1.24 percent, and in the
cat, .38 percent. This basically says that cats are in fact healthier than dogs
are.
People like to say, "Oh, that's just coincidence," but it can't be. The odds
of its being coincidence are like three billion to one. Any veterinary
orthopedic surgeon will tell you how relatively easy it is to mend broken cat
bones compared with dog bones. Dog bones take much more effort to fix and longer
to heal.
There is excellent documentation of cats' quick recovery from such things as
high-rise syndrome, which was first mentioned by Dr. Gordon Robinson and later
studied and reported in the Journal of the American Veterinary Medical
Association. They documented 132 cases of cats' plummeting an average of 5.5
stories from high-rise apartments, with some of them suffering severe injuries.
But interestingly, 90 percent of these cats survived. Most cats that fell from
seven stories or more managed to live. The record for survival from heights is
45 stories!
Is there a difference between a cat's purr of contentment and the purr of a
cat that's been injured? Apparently, there is no difference. It's machine-like.
The purr is nearly the same across species: The ocelot, chervil, and domestic
cat all create an identical sound. Elizabeth showed this data to an
architectural engineer who measures building vibration, and he asked if she were
into mechanics, since the signal appeared to be so regular. He was greatly
surprised when she told him that he was looking at the analysis of a cat's purr.
It's totally unlike any other animal's vocalization.
An idea is born
Elizabeth stumbled upon these ideas by accident (which is true of most
inventions and discoveries!). She had been working with tigers at a facility
where there were also many other wild cats. It seemed odd to her, while passing
by a chervil one day, that it was purring. Later on, she read in National
Geographic about this researcher who had put chickens on a vibrating plank for
twenty minutes a day and their bones grew. She thought that was weird. So she
called him and asked what the anabolic frequencies for bones were. He said that
they were anywhere between 20 and 90 hertz, but that there is evidence
suggesting that 25 hertz and 50 hertz are the best frequencies. The next day,
she got up, went into the living room, grabbed her big tomcat, Spot, started
petting him, and turned on the microphone. Then she ran the recording through
the computer. And guess what? Oh, my God.
After that, she started doing a search in the literature, and found that 25
hertz is the fundamental frequency. In other words, it's the first, or primal,
frequency. After the first frequency, there is something called harmonics.
Harmonics are always a multiple of the fundamental, meaning that if the
fundamental is 25 hertz, the first harmonic is 50, then the second harmonic is
75, the third harmonic is 100, and so forth. She started recording the wild
cats. Then she grabbed every domestic cat from her friends and other people.
"Excuse me. Can I record your cat?"
Then she took accelerometers and started measuring cats - accelerometers
measure vibrations - to find out where on the body the sound is the strongest
and weakest. The research revealed that the vibrational signal is at its weakest
at the extremities. Interestingly, it's rare for cats to get bone cancer, but
when they do, it's most often in the distal end of the extremities - the paw -
and that's also where the vibrational signal is the weakest.
What are the odds that in six out of seven species of cat, their purrs are
identical in frequency and amplitude? All of these cats come from a geological
evolution that is different - South America, Africa, Asia. Yet the sounds they
make match exactly, in both amplitude and frequency, to the frequencies that
have been found to be healing, and not just for healing of bones.
I've had healing experiences with my own cats. I had one cat that slept with
me every night, and it always felt so good and peaceful to have her next to me.
And of course, she purred loud and long until we both fell asleep. So, I wonder,
is it helpful for people to hold their purring cat close to their bodies?
Elizabeth says that from a scientific standpoint she would have to say she
doesn't know since there is no evidence. She goes on to say that for something
to be scientifically therapeutic, it has to be exactly the right strength,
loudness, and amplitude. However, she did say that as a healer, she says "yes, it absolutely", can be helpful to sleep with your cat. You, yourself, may have
noticed that when you're not feeling well, your cat will often come up to the
part of your body that's aching and start to knead you with their paws, purr and
get that meditative look in their eyes. They could be trying to help.
How can we make a difference?
People tend to equate language with intelligence, says Elizabeth, and feels
that people would be more willing to give of themselves to our amazing animal
friends, both wild and domestic, if they considered them intelligent. We have a
lot to learn from them. Most of our modern medicines come from plants or
animals. Killing them off is killing us. The average person does not realize
that every time an animal becomes extinct we lose another opportunity not only
to learn more about our world but also to gain something possibly therapeutic
from this animal. It's unfortunate that many people are so consumed with
purchasing expensive possessions that they don't stop to appreciate what we
already have that has been given to us.
As an avid animal lover, I know full well that animals are intelligent beings
even if they don't speak an understandable language - although my own cats have
tried to talk like humans. Elizabeth has a recording of a cat in a
veterinarian's office who kept saying its owner's name.
Animals have so much more than we have. As humans, we are limited by what
we're able to see, hear, and smell. Our senses are nowhere near as keen as those
of a dog or a cat. You may have seen your own cat at times looking at something
you cannot even sense, much less see. Most humans presume that their cats are
just staring into space, but they are tracking something.
We as humans can't even begin to understand what a dog smells. Their noses
are many times more efficient than ours. A scallop has a hundred eyes, so it
really does see us as we're ripping it from its home. Birds see in the
ultraviolet spectrum. We can't see that. We're so limited. It would be nice to
spend a day inhabiting the body of several different creatures, just to
experience what they're able to see, feel and hear that we can't.
Well... I could have listened to Elizabeth go on and on - her work is that
interesting - and she was quite pleasant and easy to talk with.
To find out more about Elizabeth Von Muggenthaler's important research, animal
sound recordings, CDs, or how you can help protect the Sumatran rhino
from extinction, please visit Fauna Communication Research Institute
at: http://www.animalvoice.com
** to hear the unusual sounds of the Sumatran Rhino, click on Research or News.
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