The diagnostic applications in diverse laboratory settings is often carried out quickly and with enhanced efficiency with all the assist of various models of laboratory microscopes. These products are integrated with exceptional functionalities that add to their utility worth.
High-end Models to Select From
Laboratory microscopes are available inside a number of models from well-known producers which include LW Scientific, Unico and others. The preferred models involve M5 INFINITY LabScope Strategy Trinocular, M2 LabScope DIN Plan Trinoc. C-mount four Obj, M2 INFINITY Epi-Fluorescent Labscope, Revelation III-A Achro. Binocular, M16 Freedom Jr. Cordless Microscope, M250 Binocular Microscope and a lot of extra.
With the help of those different microscopes, analytical applications in microbiology, cytology, hematology, and pathology labs at the same time as those in school and college biology laboratories might be performed with added comfort. Apart from, these offer greatest accuracy in evaluation reports.
Laboratory Microscopes Obtainable in Distinct Dimensions
Biological Microscope on line are obtainable in distinctive dimensions varying in length, width, height and weight. They may be incorporated with simple to use attributes including:
• Higher point eyepieces (10X/20, 10X/22)
• Around 50-75mm interpupillary distance range
• Diopter adjustment
• Mounted with multiple ball bearing
• Reverse quadruple nosepiece
• Dual slide holder
• Binocular head objectives
• Tension adjustment knob
• Fine adjustment of around 22μm
• Coarse adjustment range around 20 mm
• Coaxial drive controls, metal rack and pinion
Biological Microscopes lab are also provided with portable NA 1.25 Abbe condenser, halogen light, Iris diaphragm and stage locking lever. Other accessories involve spare bulb, 2 amp fuses, immersion oil, blue, green, and yellow filters, operation manual and dust cover. Additionally, they are also provided with one year warranty for the electronic components and lifetime assurance for materials and workmanship.
Purchase zoom?digital microscope from Competent Dealers
When you are planning to purchase laboratory microscopes for your research settings, make sure to contact a competent dealer in the industry. Such a dealer can assist you in selecting the appropriate model, after analyzing your application requirements and budget.
Sunday, December 9, 2012
Atomic Force Microscopy
Microscopes would be the most significant instruments in any bio healthcare study approach. The invention of Atomic Force transportable metallurgical microscope (AFM) has opened new horizons within the investigation of biomedical specimens.
Atomic Force Microscopy was created to master fundamental drawbacks of STM instruments. STM had the capability to image only conducting and semi-conducting surfaces. Nonetheless, AFM can image just about any variety of surface including ceramics, glass, polymers, composites and biological samples.
AFM was invented by Binnig, Quate and Gerber in 1985. The original AFM model consists of a diamond shard attached to a strip of gold foil. The diamond tip contacts the surface straight enabling the interaction mechanism. The interaction mechanism occurs as a result of inter-atomic van der Waals forces. The second tip of AFM detects the cantilever's vertical movement.
Nowadays, most of the AFMs are fitted having a laser beam deflection method which was introduced by Amer and Meyer. The laser is reflected to position-sensitive detectors in the back from the reflective AFM lever in this deflection method. The AFM cantilevers and suggestions are micro-fabricated from Si3N4 or Si. The radius of such suggestions is as much as 10ns of nm. biological microscope for sale is capable of tri dimensional mapping on the surface. The results obtained gained scientific relevance when it was understood that it truly is not fancy reconstruction of surfaces, but actual graphical data that may be obtained vertical down to subnanometer range.
The simplified sample preparation and distinct possibilities of investigating specimens in liquid environment by AFM gives self-confidence to researchers. Researchers always strive to locate a solution to use AFM in their investigation process.
AFM pictures display considerable information about surface characteristics with incredible clarity. The instrument has the capability to examine any decent rigid surface in air or immersed in liquid. The current developments in instruments allow the manage of the temperature in the sample. It may also be fitted with close chamber to achieve environmental handle. The AFM may also be mounted on an inverted metallurgical microscope for concurrent imaging via sophisticated optical approaches.
Atomic Force Microscopy was created to master fundamental drawbacks of STM instruments. STM had the capability to image only conducting and semi-conducting surfaces. Nonetheless, AFM can image just about any variety of surface including ceramics, glass, polymers, composites and biological samples.
AFM was invented by Binnig, Quate and Gerber in 1985. The original AFM model consists of a diamond shard attached to a strip of gold foil. The diamond tip contacts the surface straight enabling the interaction mechanism. The interaction mechanism occurs as a result of inter-atomic van der Waals forces. The second tip of AFM detects the cantilever's vertical movement.
Nowadays, most of the AFMs are fitted having a laser beam deflection method which was introduced by Amer and Meyer. The laser is reflected to position-sensitive detectors in the back from the reflective AFM lever in this deflection method. The AFM cantilevers and suggestions are micro-fabricated from Si3N4 or Si. The radius of such suggestions is as much as 10ns of nm. biological microscope for sale is capable of tri dimensional mapping on the surface. The results obtained gained scientific relevance when it was understood that it truly is not fancy reconstruction of surfaces, but actual graphical data that may be obtained vertical down to subnanometer range.
The simplified sample preparation and distinct possibilities of investigating specimens in liquid environment by AFM gives self-confidence to researchers. Researchers always strive to locate a solution to use AFM in their investigation process.
AFM pictures display considerable information about surface characteristics with incredible clarity. The instrument has the capability to examine any decent rigid surface in air or immersed in liquid. The current developments in instruments allow the manage of the temperature in the sample. It may also be fitted with close chamber to achieve environmental handle. The AFM may also be mounted on an inverted metallurgical microscope for concurrent imaging via sophisticated optical approaches.
Wednesday, October 17, 2012
What Is Breast Cancer?
The breast is a gland that consists of breast tissue supported by connective tissue (flesh) surrounded by fat.
The easiest way to understand how the inside of the breast is formed is by comparing it to an upturned bush. Its leaves are known as lobules and they produce milk that drains into ducts that are the branches of the breast tree. These in turn drain into 12 or 15 major or large ducts which empty onto the surface of the nipple, just like the branches of a tree drain to the trunk.
Breast cancer most often involves glandular breast cells in the ducts or lobules. Most patients present with an asymptomatic lump discovered during examination or screening mammography. Diagnosis is confirmed by biopsy. Treatment usually includes surgical excision, often with radiation therapy and adjuvant systemic therapy.
Symptoms:
* Breast Lump
* Breast Pain
* Breast Tenderness
* Decreased Libido
* Dimpling Of Surface Of Breast
* Enlarged Lymph Nodes, Armpit
* Nipple Discharge
* Orange Peel Texture To Breast
* Pain
* Retraction Of Nipple
* Ulceration Of Breast
* Unilateral Breast Enlargement
* Unintentional Weight Loss
* Vaginal Pain
* Veins Visible On Breast
* Weight Loss
What Causes Breast Cancer?
No one knows exactly what causes breast cancer, but we do know that certain risk factors - things that increase a person's chance of getting a disease - are linked to breast cancer. Risk factors change depending on the type of cancer. There are a number of risk factors, both controllable and uncontrollable, which may increase the chances of developing breast cancer. For instance, the risk factors associated with diet can be controlled, but risk factors such as a person's age or family history can't be changed.
While all women are at risk for breast cancer, the factors listed below are associated with an increased chance of developing the disease.
How is it diagnosed?
Most cases are picked up when a woman notices a lump in her breast or through routine screening with mammography. Nine out of ten lumps aren't dangerous, but they should be checked.
Being breast aware, reporting any changes and, for women aged between 50 and 70, attending NHS mammogram screenings help to identify breast cancer early. Women with a strong family history may be offered screening before 50.
Stage and grade of your cancer
Both of these are important for helping to decide which treatments you need. The stage of your breast cancer means how far it has grown and whether it has spread. Grade means what the cancer cells look like under the microscope. Breast cancers can be
* Low grade or grade 1 (slow growing)
* Intermediate grade or grade 2
* High grade or grade 3 (fast growing)
What's the treatment?
Treatment for breast cancer includes surgery, radiotherapy, chemotherapy, biological therapy and hormone therapy (for example, tamoxifen).
Emotional support for the individual and their family is important.
The easiest way to understand how the inside of the breast is formed is by comparing it to an upturned bush. Its leaves are known as lobules and they produce milk that drains into ducts that are the branches of the breast tree. These in turn drain into 12 or 15 major or large ducts which empty onto the surface of the nipple, just like the branches of a tree drain to the trunk.
Breast cancer most often involves glandular breast cells in the ducts or lobules. Most patients present with an asymptomatic lump discovered during examination or screening mammography. Diagnosis is confirmed by biopsy. Treatment usually includes surgical excision, often with radiation therapy and adjuvant systemic therapy.
Symptoms:
* Breast Lump
* Breast Pain
* Breast Tenderness
* Decreased Libido
* Dimpling Of Surface Of Breast
* Enlarged Lymph Nodes, Armpit
* Nipple Discharge
* Orange Peel Texture To Breast
* Pain
* Retraction Of Nipple
* Ulceration Of Breast
* Unilateral Breast Enlargement
* Unintentional Weight Loss
* Vaginal Pain
* Veins Visible On Breast
* Weight Loss
What Causes Breast Cancer?
No one knows exactly what causes breast cancer, but we do know that certain risk factors - things that increase a person's chance of getting a disease - are linked to breast cancer. Risk factors change depending on the type of cancer. There are a number of risk factors, both controllable and uncontrollable, which may increase the chances of developing breast cancer. For instance, the risk factors associated with diet can be controlled, but risk factors such as a person's age or family history can't be changed.
While all women are at risk for breast cancer, the factors listed below are associated with an increased chance of developing the disease.
How is it diagnosed?
Most cases are picked up when a woman notices a lump in her breast or through routine screening with mammography. Nine out of ten lumps aren't dangerous, but they should be checked.
Being breast aware, reporting any changes and, for women aged between 50 and 70, attending NHS mammogram screenings help to identify breast cancer early. Women with a strong family history may be offered screening before 50.
Stage and grade of your cancer
Both of these are important for helping to decide which treatments you need. The stage of your breast cancer means how far it has grown and whether it has spread. Grade means what the cancer cells look like under the microscope. Breast cancers can be
* Low grade or grade 1 (slow growing)
* Intermediate grade or grade 2
* High grade or grade 3 (fast growing)
What's the treatment?
Treatment for breast cancer includes surgery, radiotherapy, chemotherapy, biological therapy and hormone therapy (for example, tamoxifen).
Emotional support for the individual and their family is important.
Types of Compound Optical Microscopes
Compound optical microscopes are also known as compound microscopes, light microscopes or optical microscopes and come in several varieties. These include digital, inverted, stereo, monocular and binocular.
All work on the same principles and deliver an enlarged image to the viewer. They have some differences though, which will be detailed here.
Monocular:
These are probably the ones you think of when microscopes come to mind. Using a single light as a sample illuminator and compound lenses for magnification, these have a single eyepiece. This is a bit uncomfortable, as you need to close one eye to get a clear image of what you are looking at on the slide. The eyepiece has a power of about 10X and the objectives or lenses on the nosepiece range from 2X to 50X depending on your particular microscope. The big one here is the single eyepiece.
Binocular:
Binocular microscopes are becoming more common. You can tell a binocular style microscope by the dual eyepiece. Simply put, you use both eyes to view the sample image. This makes them more comfortable to use and thereby more popular. Dual eyepiece scopes are used widely in high school and college classrooms. Binocular microscopes have all the same characteristics as the monocular ones above.
Stereo:
Stereo microscopes bring a whole new dimension to the image, literally. Whereas the typical light microscope produces a two-dimensional image, the stereo microscope uses two light sources working independently to produce a three-dimensional image to the viewer. The sample on the slide will have height, depth and width. Using all of the same features and characteristics of the other optical microscopes, stereomicroscopes stand out among their counterparts.
Digital:
This is where things go differently in the realms of microscopy. Standard optical microscopes use light to illuminate and lenses to magnify something that you could not see with the unaided eye.
Digital microscopes are a breed apart. This type of microscope inverts the light source, placing it above the sample. Standard optical microscopes place the light below the sample. You also get the 3D image like in stereo scopes. The difference is that the image is digitized and transmitted to a monitor or screen for viewing. Imagine watching cells divide on a 19" monitor. The user can take still photos or moving video of the sample in real time. I think you can see the advantages here.
Inverted:
Inverted microscopes are used to study samples that are gravity sensitive, like gases suspended in a liquid. The inversion refers to the light source, which is typically below the sample slide. With the inverted microscope, the light source is above the sample slide. This paved the way for new innovations in digital imaging that came along.
All these different types will work for you. It's just a matter of what you want to accomplish or study. I can tell you this, though; using any microscope will open your eyes to a whole new perspective of where we came from and what we are made of.
If you're interested in this, you're mostly welcome to Microscopebiz.com and please feel free to contact us for detailed information.
All work on the same principles and deliver an enlarged image to the viewer. They have some differences though, which will be detailed here.
Monocular:
These are probably the ones you think of when microscopes come to mind. Using a single light as a sample illuminator and compound lenses for magnification, these have a single eyepiece. This is a bit uncomfortable, as you need to close one eye to get a clear image of what you are looking at on the slide. The eyepiece has a power of about 10X and the objectives or lenses on the nosepiece range from 2X to 50X depending on your particular microscope. The big one here is the single eyepiece.
Binocular:
Binocular microscopes are becoming more common. You can tell a binocular style microscope by the dual eyepiece. Simply put, you use both eyes to view the sample image. This makes them more comfortable to use and thereby more popular. Dual eyepiece scopes are used widely in high school and college classrooms. Binocular microscopes have all the same characteristics as the monocular ones above.
Stereo:
Stereo microscopes bring a whole new dimension to the image, literally. Whereas the typical light microscope produces a two-dimensional image, the stereo microscope uses two light sources working independently to produce a three-dimensional image to the viewer. The sample on the slide will have height, depth and width. Using all of the same features and characteristics of the other optical microscopes, stereomicroscopes stand out among their counterparts.
Digital:
This is where things go differently in the realms of microscopy. Standard optical microscopes use light to illuminate and lenses to magnify something that you could not see with the unaided eye.
Digital microscopes are a breed apart. This type of microscope inverts the light source, placing it above the sample. Standard optical microscopes place the light below the sample. You also get the 3D image like in stereo scopes. The difference is that the image is digitized and transmitted to a monitor or screen for viewing. Imagine watching cells divide on a 19" monitor. The user can take still photos or moving video of the sample in real time. I think you can see the advantages here.
Inverted:
Inverted microscopes are used to study samples that are gravity sensitive, like gases suspended in a liquid. The inversion refers to the light source, which is typically below the sample slide. With the inverted microscope, the light source is above the sample slide. This paved the way for new innovations in digital imaging that came along.
All these different types will work for you. It's just a matter of what you want to accomplish or study. I can tell you this, though; using any microscope will open your eyes to a whole new perspective of where we came from and what we are made of.
If you're interested in this, you're mostly welcome to Microscopebiz.com and please feel free to contact us for detailed information.
Monday, October 15, 2012
Does Reverse Osmosis Make Water Safe to Drink? - Here Are Some Startling Facts
Today we are going to go over the large number of disadvantages of reverse osmosis. People are constantly asking me, does reverse osmosis make water safe to drink? Despite what you may have been led to believe, no it does not.
The disadvantages of reverse osmosis are obvious even at the level of the water treatment facilities. The R.O. system was originally designed for de-mineralizing water for industrial purposes, and was recruited to clean up our water supplies a few years later. People were dying in large numbers from waterborne diseases, and R.O. was the only answer that we had.
So am I backtracking on my answer to does reverse osmosis make water safe to drink? Absolutely not, it simply makes water safer to drink than if we had no filter at all. The water treatment facilities and the EPA both have stated that with the number of contaminants still in the water after treatment that we should switch to bottled or buy a home purification system.
That should tell you everything you need to know about the disadvantages of reverse osmosis. The EPA and the treatment facilities don't even believe in the system's ability to make our drinking water safe. To better clarify exactly why they feel this way, allow me to explain.
R.O. systems were designed strictly for de-mineralization, which means that they remove silt and sediment from our drinking water and nothing more. The porous filters that are used are only capable of removing contaminants that have great molecular density than the water that carries them. Does reverse osmosis make water safe to drink? Not with that kind of limitation.
All chemical matter that is in the water that is in a liquefied state passes directly through the membrane filter, and is carried by the water to your home. This is not the only problem that we face. Another of the disadvantages of reverse osmosis is that it also cannot stop biological matter that is microscopic in size.
You see, despite chlorine disinfection many microbes live on. Parasites and bacteria that are immune to the chlorine's disinfectant power pass on to you for ingestion. This can lead a person to severe intestinal distress, and to the very old, young, or the immune impaired it could lead to much worse.
Does reverse osmosis make water safe to drink? Not with the number of limitations that you've seen here. Additional filtering is required in order to end the risk that we face from the impurities in the water that R.O. is not sufficiently able to handle. That is why the EPA and the treatment facilities are telling you to purchase a home water purification system.
As you can see, the disadvantages of reverse osmosis are many. I would certainly never depend on a home R.O. system to adequately protect my family from the hundreds of impurities in our reservoirs, and neither should you. Purchase a quality home water purification system today, and guarantee that your family will remain healthy and happy.
The disadvantages of reverse osmosis are obvious even at the level of the water treatment facilities. The R.O. system was originally designed for de-mineralizing water for industrial purposes, and was recruited to clean up our water supplies a few years later. People were dying in large numbers from waterborne diseases, and R.O. was the only answer that we had.
So am I backtracking on my answer to does reverse osmosis make water safe to drink? Absolutely not, it simply makes water safer to drink than if we had no filter at all. The water treatment facilities and the EPA both have stated that with the number of contaminants still in the water after treatment that we should switch to bottled or buy a home purification system.
That should tell you everything you need to know about the disadvantages of reverse osmosis. The EPA and the treatment facilities don't even believe in the system's ability to make our drinking water safe. To better clarify exactly why they feel this way, allow me to explain.
R.O. systems were designed strictly for de-mineralization, which means that they remove silt and sediment from our drinking water and nothing more. The porous filters that are used are only capable of removing contaminants that have great molecular density than the water that carries them. Does reverse osmosis make water safe to drink? Not with that kind of limitation.
All chemical matter that is in the water that is in a liquefied state passes directly through the membrane filter, and is carried by the water to your home. This is not the only problem that we face. Another of the disadvantages of reverse osmosis is that it also cannot stop biological matter that is microscopic in size.
You see, despite chlorine disinfection many microbes live on. Parasites and bacteria that are immune to the chlorine's disinfectant power pass on to you for ingestion. This can lead a person to severe intestinal distress, and to the very old, young, or the immune impaired it could lead to much worse.
Does reverse osmosis make water safe to drink? Not with the number of limitations that you've seen here. Additional filtering is required in order to end the risk that we face from the impurities in the water that R.O. is not sufficiently able to handle. That is why the EPA and the treatment facilities are telling you to purchase a home water purification system.
As you can see, the disadvantages of reverse osmosis are many. I would certainly never depend on a home R.O. system to adequately protect my family from the hundreds of impurities in our reservoirs, and neither should you. Purchase a quality home water purification system today, and guarantee that your family will remain healthy and happy.
Aerospace Ultrasonic Test Equipment Basics
The components of aerospace ultrasonic test equipment.
PC-based and external components make up an aerospace ultrasonic test system. Each of these components has features and considerations when put together to build custom flexible ultrasonic test equipment.
Assembling Ultrasonic Immersion Test Equipment.
Ultrasonic test equipment can take several forms, but the most common type of ATE is immersion test equipment. Squirter systems are the commonest used for aerospace composite material inspection and complex geometry composite parts. To achieve effective acoustical impedance matching between the couplant and the composite component or titanium plate that is the subject of the test (unit under test), and to achieve free range over the entire surface of the UUT, many test systems use an immersion tank filled with water. This equipment uses one or more ultrasonic transducers, which are moved over the surface of the UUT. It receives echoes from the surfaces. This process is repeated many times a second with one pulse and subsequent echoes. Application software sets up the test and presentation. Motion control moves the ultrasonic transducers. The signal from the ultrasonic transducer is amplified and filtered before it is sent back to the PC. The waveform is converted from voltage to bits using an analog-to-digital converter. The application software handles the data.
The scale of immersion test equipment can vary enormously in aerospace including, for example, anything up to 17 axis scanning bridges. Acoustic microscopes use high ultrasonic frequencies and high resolution scanning units.
Ultrasonic Transducers
Ultrasonic transducers are built around piezoelectric ceramics that vibrate at ultrasonic frequencies. Piezoelectric ceramics in ultrasonic transducers used in field service are commonly contact sensors, and are contoured to the surface to be inspected. Standard Immersion Ultrasonic Transducers works on the principal that in ultrasonics, the voltage amplitude is proportional to the amount of energy echoed by the flaw. In immersion testing, the ultrasonic wave must travel through water before arriving at the UUT. If the distance is known, a trigger delay can be implemented to minimize the amount of unnecessary data that is recorded and stored. There is a trade-off between resolution, speed, channel count, data throughput, and cost. However, the technology is evolving and many of these trade-offs will become insignificant with respect to cost.
Motion Control and switching
Most automated ultrasonic test systems use motion control to gather multiple data points with one transducer. For instance, acquiring B- or C-scans requires movement of the ultrasonic sensor
over the UUT surface to create a surface map.
As for switching, in ultrasound applications that have one digitizer and pulser/receiver for multiple ultrasonic sensors, switching is required to route the signals properly. This is used for equipment like acoustic microscopes that use arrays of sensors to create images. Arrays of ultrasonic sensors are common in aerospace NDT applications because the sound energy can be steered in multiple directions without moving the sensor array. Multitransducer applications are also common when speed of test is an issue.
Application software
One of the main trends in non-destructive testing, and ultrasonic test equipment, in particular, is full test automation. ATE includes not only data collection and presentation automation but also pass/fail
automation. Setting pass/fail templates increases statistical accuracy and eliminates much of the subjectivity that is commonly found with NDT.For more information, you are most welcome to our website:www.micriscopebiz.com
PC-based and external components make up an aerospace ultrasonic test system. Each of these components has features and considerations when put together to build custom flexible ultrasonic test equipment.
Assembling Ultrasonic Immersion Test Equipment.
Ultrasonic test equipment can take several forms, but the most common type of ATE is immersion test equipment. Squirter systems are the commonest used for aerospace composite material inspection and complex geometry composite parts. To achieve effective acoustical impedance matching between the couplant and the composite component or titanium plate that is the subject of the test (unit under test), and to achieve free range over the entire surface of the UUT, many test systems use an immersion tank filled with water. This equipment uses one or more ultrasonic transducers, which are moved over the surface of the UUT. It receives echoes from the surfaces. This process is repeated many times a second with one pulse and subsequent echoes. Application software sets up the test and presentation. Motion control moves the ultrasonic transducers. The signal from the ultrasonic transducer is amplified and filtered before it is sent back to the PC. The waveform is converted from voltage to bits using an analog-to-digital converter. The application software handles the data.
The scale of immersion test equipment can vary enormously in aerospace including, for example, anything up to 17 axis scanning bridges. Acoustic microscopes use high ultrasonic frequencies and high resolution scanning units.
Ultrasonic Transducers
Ultrasonic transducers are built around piezoelectric ceramics that vibrate at ultrasonic frequencies. Piezoelectric ceramics in ultrasonic transducers used in field service are commonly contact sensors, and are contoured to the surface to be inspected. Standard Immersion Ultrasonic Transducers works on the principal that in ultrasonics, the voltage amplitude is proportional to the amount of energy echoed by the flaw. In immersion testing, the ultrasonic wave must travel through water before arriving at the UUT. If the distance is known, a trigger delay can be implemented to minimize the amount of unnecessary data that is recorded and stored. There is a trade-off between resolution, speed, channel count, data throughput, and cost. However, the technology is evolving and many of these trade-offs will become insignificant with respect to cost.
Motion Control and switching
Most automated ultrasonic test systems use motion control to gather multiple data points with one transducer. For instance, acquiring B- or C-scans requires movement of the ultrasonic sensor
over the UUT surface to create a surface map.
As for switching, in ultrasound applications that have one digitizer and pulser/receiver for multiple ultrasonic sensors, switching is required to route the signals properly. This is used for equipment like acoustic microscopes that use arrays of sensors to create images. Arrays of ultrasonic sensors are common in aerospace NDT applications because the sound energy can be steered in multiple directions without moving the sensor array. Multitransducer applications are also common when speed of test is an issue.
Application software
One of the main trends in non-destructive testing, and ultrasonic test equipment, in particular, is full test automation. ATE includes not only data collection and presentation automation but also pass/fail
automation. Setting pass/fail templates increases statistical accuracy and eliminates much of the subjectivity that is commonly found with NDT.For more information, you are most welcome to our website:www.micriscopebiz.com
Friday, October 12, 2012
HIV Aids and Glyconutrients
If you or a loved one is suffering form HIV or AIDS, you need to review this information thoroughly.
The AIDS epidemic is affecting millions of lives of young children and adults in Africa and around the world; the average life expectancy in Africa is 47. This is a tragic situation and soon the world will find out what they can do to help. If this epidemic continues no one will even know what an old person looks like in Africa.
On October 15th 2005, the term glyconutrients will enter into the public consciousness and dictionaries of the world. In Los Angeles, California, the first World Wide AIDS Concert will be held to raise money to supply glyconutrients for children in Africa and other third world countries that are devastated with AIDS. Watch for the first and subsequent events on a network station in your area.
During the next three years, six 'Live Aid' type concerts will focus exclusively on Global AIDS Awareness. AIDS is the single largest threat to children in third world countries, and increasingly so in the west, yet it captures few headlines. Other concerts will take place in the UK, Russia, Brazil, Africa and China during the three years. The executive producer of the series is Hal Uplinger, who was the US producer for the Live Aid concerts in the 80's and at the turn of the century for the Millennium Show. He will bring together massive talent to make this his largest undertaking ever!
U2, one of the most popular rock bands in the world, along with the Dave Matthews Band, will be performing at the initial concert in LA. The Global AIDS Awareness Program is a series of live concerts, each of which will be telecasted worldwide. The Program will increase AIDS awareness and raise money to improve the quality of life for AIDS children around the world.
Maybe "the cure" is really the human body. The human body is truly the miracle; it is the job of science to find what the body requires to function at optimal wellness. Through history it has been proven time and again that providing essential nutrients through foods that you eat, to support your bodies systems to run efficiently, is truly your best medicine. It is your body that can recover from illness and prevent the onset of a disease or condition, but only when your bodies systems are supported properly.
Recent science has discovered a group of essential nutrients that has been overlooked in the past called glyconutrients.
Glyconutrients have been improving the quality of life of children with HIV/AIDS in third world counties. We have to continue to raise awareness and funds to help support these needy children of the world.
So, what are glyconutrients and how do they benefit people affected with the HIV virus or AIDS?
Glyconutrients are nutrients that have been discovered to be vital to normal immune function and, therefore, good health. Glyconutrients were discovered because of the advances in the research in a field called glycomics, also known as Glycobiology. This science focuses on the structure and function of oligosaccharides, or chains of sugar. Now that scientists have fully identified the entire glycome or range of sugars found in the human body, they are beginning to understand the vital role they play in human health. Their research forms the foundation for the emerging field known as glycomics.
We keep hearing that sugar is bad for us, which is true of refined sugars such as sucrose, but researchers are learning that complex chains of sugars (naturally occurring in plants, fruits, mushrooms, roots, and seaweeds such as Fucoidans and many others) are vital to human health. The problem is that these sugars are difficult to obtain, in the typical, overly refined, westernized diet. Our diets are loaded with simple sugars like sucrose and fructose that raise the glycemic index and contribute to a host of serious health problems such as obesity and diabetes. In contrast, certain oligosaccharides are as essential for the proper functioning of the human body as healthy fats and proteins and vital for cell-to-cell interactions including the vital function of the human immune system.
Scientists are saying that glycomics could fuel a revolution in biology to rival that of the human genome!
Scientists and researchers say "glycomics" may well become one of the most important new words of the 21st century. And glyconutritional products...foods and supplements that incorporate this new science into their formulations...could become an integral part of the protocol for the management of many debilitating conditions, since glyconutrients facilitate cell-to-cell communication in the body.
"This is going to be the future," declares biochemist Gerald Hart of Johns Hopkins University in Baltimore. "We won't understand immunology, neurology, developmental biology or disease until we get a handle on glycobiology."..."If you ask what is the glycome for a single cell type, it's probably many thousands of times more complex than a genome," says Ajit Varki, director of the Glycobiology Research and Training Center at the University of California San Diego,... Raymond Dwek, head of the University of Oxford's Glycobiology Institute, who coined the term "glycobiology" in 1988, says that sugars were often dismissed as unimportant, "as just decorations on proteins - people didn't know how to deal with them." They could not have been more wrong. As recent advances in genetics have unfolded, the importance of sugars has become ever more apparent... Varki sees it as a journey of exploration. "It's like we've just discovered the continent of North America. Now we have to send out the scouting parties to find out how big it is..." New Scientist, October 2002 by Science writer Karen Schmidt
AIDS (Acquired Immunodeficiency Syndrome or Acquired Immune Deficiency Syndrome) is a disease characterized by the destruction of the human immune system. When your immune system cannot function properly and protect your body from disease, all it takes is a common cold to start a disastrous chain of events that leads to many illness and deaths of people affected with AIDS.
Normally, the immune system does a great job of keeping people healthy and preventing infections. Those infected with AIDS, however, have many complications with which to contend. The immune system is the system of specialized cells and organs that protect an organism from outside biological influences. In a broad sense, almost every organ has a protective function (e.g., the skin). When the immune system is functioning properly, it protects the body against bacteria and viral infections, destroying cancer cells and foreign substances. If the immune system weakens, its ability to defend the body also weakens, allowing pathogens, including viruses that cause common colds and flu, to grow and flourish in the body. The immune system also performs surveillance of tumor cells, and immune suppression has been reported to increase the risk of certain types of cancer.
This is where glyconutrients enter the scene. Glyconutrients provide essential nutrients your body requires to modulate (balance) your immune system. The most important function of the immune system begins at the cellular level.
Glyconutrients are nutritional, plant-based carbohydrates (saccharides). When they are consumed in sufficient amounts, they provide what your body must have in order to produce the cell surface structures called glycoproteins for every cell in your entire body.
This is how the human immune system begins to communicate the vast amount of intercellular information that is required on a millisecond basis (the human immune system is truly amazing when it is supported properly). It's all about balance. For example, hormones need to be in the right ratios for defense mechanisms to function properly. Likewise, the body's delicate ph balance cannot be too acidic or too alkaline. These functions are all carefully controlled by microscopic cells of the immune system. When this system breaks down, disease results.
Your immune system begins at the cellular level! The most important thing you can do for your health is to restore the proper function to your cells, and this can only be achieved by restoring cellular health!
In 1984-85, a group of symptomatic HIV-1 positive patients reported that oral aloe juice alleviated their AIDS symptoms. It was found that the active, anti-viral ingredient in aloe leaf gel was polymannose. This is a micronutrient that supports synthesis of innate defense molecules that destroy multiple types of infectious agents including bacteria and viruses. The mechanism of action is not that of antibiotics that poison or block the metabolism of micro-organisms. The biochemistry and immunology supported by this glyconutrient type of micronutrient-based defense is based on the up-regulation of innate, natural mechanisms for protection against and destruction of micro-organisms. Thus, antibiotic resistant organisms are destroyed by this enhancement of natural defense mechanisms through optimal dietary supplementation. The exact site and step in glycoprotein synthesis within the cell where mannose of aloe origin is utilized has been defined. This led to recognizing and formulating a mixture of natural saccharides (dietary sugars) known to be necessary in the golgi to provide a more efficient cellular synthesis of defense and tissue repair molecules.
Glyconutrients provide your body essential nutrients it requires to build and support glycoproteins.
Healthy bodies, comprised of many components working together in sophisticated harmony, must have accurate biochemical communication to function correctly. In its most basic form, this communication occurs at the cellular level and is referred to by molecular biologists as cell-to-cell communication.
So regardless of what condition you have, whether it is HIV, AIDS, heart disease, cancer or any other disease condition, you need to support your body and your bodies systems with essential nutrients that your body requires to function at an optimal level of health and therefore build a strong healthy immune system.
To obtain optimal health you must provide your body what it requires in the form of food and essential nutrients to support and build Cellular Restoration.
Because this AIDS virus attacks the immune system, it is of utmost importance to keep your body as healthy as possible to slow down the progression of the disease. It is absolutely vital that you have a good strong immune system so your body can fight off infections, colds, flus and protect your health and well being!
If you are dealing with HIV or AIDS, the single most important function you must have working for you is a strong vibrant immune system. Your immune system is your body's last line of defense in the prevention of disease.
With the right nutritional and wellness plan, people with HIV or AIDS can dramatically improve the quality of life and extend their lives.
The discovery of glyconutrients is the single most important discovery in nutritional science that will strengthen your immune system, restore cellular health, and create increased vitality.
The AIDS epidemic is affecting millions of lives of young children and adults in Africa and around the world; the average life expectancy in Africa is 47. This is a tragic situation and soon the world will find out what they can do to help. If this epidemic continues no one will even know what an old person looks like in Africa.
On October 15th 2005, the term glyconutrients will enter into the public consciousness and dictionaries of the world. In Los Angeles, California, the first World Wide AIDS Concert will be held to raise money to supply glyconutrients for children in Africa and other third world countries that are devastated with AIDS. Watch for the first and subsequent events on a network station in your area.
During the next three years, six 'Live Aid' type concerts will focus exclusively on Global AIDS Awareness. AIDS is the single largest threat to children in third world countries, and increasingly so in the west, yet it captures few headlines. Other concerts will take place in the UK, Russia, Brazil, Africa and China during the three years. The executive producer of the series is Hal Uplinger, who was the US producer for the Live Aid concerts in the 80's and at the turn of the century for the Millennium Show. He will bring together massive talent to make this his largest undertaking ever!
U2, one of the most popular rock bands in the world, along with the Dave Matthews Band, will be performing at the initial concert in LA. The Global AIDS Awareness Program is a series of live concerts, each of which will be telecasted worldwide. The Program will increase AIDS awareness and raise money to improve the quality of life for AIDS children around the world.
"There are millions of hopeless children who are suffering from AIDS. The discovery of glyconutrients offers one of the best opportunities to impact their quality of life. While researchers continue their struggle to find a future cure, it is imperative that we raise an awareness of the huge impact this new discovery can make today." --Hal Uplinger, Television Producer of these historic fund raising events
Maybe "the cure" is really the human body. The human body is truly the miracle; it is the job of science to find what the body requires to function at optimal wellness. Through history it has been proven time and again that providing essential nutrients through foods that you eat, to support your bodies systems to run efficiently, is truly your best medicine. It is your body that can recover from illness and prevent the onset of a disease or condition, but only when your bodies systems are supported properly.
Recent science has discovered a group of essential nutrients that has been overlooked in the past called glyconutrients.
Glyconutrients have been improving the quality of life of children with HIV/AIDS in third world counties. We have to continue to raise awareness and funds to help support these needy children of the world.
So, what are glyconutrients and how do they benefit people affected with the HIV virus or AIDS?
Glyconutrients are nutrients that have been discovered to be vital to normal immune function and, therefore, good health. Glyconutrients were discovered because of the advances in the research in a field called glycomics, also known as Glycobiology. This science focuses on the structure and function of oligosaccharides, or chains of sugar. Now that scientists have fully identified the entire glycome or range of sugars found in the human body, they are beginning to understand the vital role they play in human health. Their research forms the foundation for the emerging field known as glycomics.
We keep hearing that sugar is bad for us, which is true of refined sugars such as sucrose, but researchers are learning that complex chains of sugars (naturally occurring in plants, fruits, mushrooms, roots, and seaweeds such as Fucoidans and many others) are vital to human health. The problem is that these sugars are difficult to obtain, in the typical, overly refined, westernized diet. Our diets are loaded with simple sugars like sucrose and fructose that raise the glycemic index and contribute to a host of serious health problems such as obesity and diabetes. In contrast, certain oligosaccharides are as essential for the proper functioning of the human body as healthy fats and proteins and vital for cell-to-cell interactions including the vital function of the human immune system.
Scientists are saying that glycomics could fuel a revolution in biology to rival that of the human genome!
Scientists and researchers say "glycomics" may well become one of the most important new words of the 21st century. And glyconutritional products...foods and supplements that incorporate this new science into their formulations...could become an integral part of the protocol for the management of many debilitating conditions, since glyconutrients facilitate cell-to-cell communication in the body.
"This is going to be the future," declares biochemist Gerald Hart of Johns Hopkins University in Baltimore. "We won't understand immunology, neurology, developmental biology or disease until we get a handle on glycobiology."..."If you ask what is the glycome for a single cell type, it's probably many thousands of times more complex than a genome," says Ajit Varki, director of the Glycobiology Research and Training Center at the University of California San Diego,... Raymond Dwek, head of the University of Oxford's Glycobiology Institute, who coined the term "glycobiology" in 1988, says that sugars were often dismissed as unimportant, "as just decorations on proteins - people didn't know how to deal with them." They could not have been more wrong. As recent advances in genetics have unfolded, the importance of sugars has become ever more apparent... Varki sees it as a journey of exploration. "It's like we've just discovered the continent of North America. Now we have to send out the scouting parties to find out how big it is..." New Scientist, October 2002 by Science writer Karen Schmidt
[Glycomics are] known to regulate hormones, organize embryonic development, direct the movement of cells and proteins throughout the body, and regulate the immune system. It shows yet again that the DNA in the genome is only one aspect of the complex mechanism that keeps the body running--decoding the DNA is one step towards understanding, but by itself it doesn't specify everything that happens within the organism. Michael Quinion
AIDS (Acquired Immunodeficiency Syndrome or Acquired Immune Deficiency Syndrome) is a disease characterized by the destruction of the human immune system. When your immune system cannot function properly and protect your body from disease, all it takes is a common cold to start a disastrous chain of events that leads to many illness and deaths of people affected with AIDS.
Normally, the immune system does a great job of keeping people healthy and preventing infections. Those infected with AIDS, however, have many complications with which to contend. The immune system is the system of specialized cells and organs that protect an organism from outside biological influences. In a broad sense, almost every organ has a protective function (e.g., the skin). When the immune system is functioning properly, it protects the body against bacteria and viral infections, destroying cancer cells and foreign substances. If the immune system weakens, its ability to defend the body also weakens, allowing pathogens, including viruses that cause common colds and flu, to grow and flourish in the body. The immune system also performs surveillance of tumor cells, and immune suppression has been reported to increase the risk of certain types of cancer.
This is where glyconutrients enter the scene. Glyconutrients provide essential nutrients your body requires to modulate (balance) your immune system. The most important function of the immune system begins at the cellular level.
Glyconutrients are nutritional, plant-based carbohydrates (saccharides). When they are consumed in sufficient amounts, they provide what your body must have in order to produce the cell surface structures called glycoproteins for every cell in your entire body.
This is how the human immune system begins to communicate the vast amount of intercellular information that is required on a millisecond basis (the human immune system is truly amazing when it is supported properly). It's all about balance. For example, hormones need to be in the right ratios for defense mechanisms to function properly. Likewise, the body's delicate ph balance cannot be too acidic or too alkaline. These functions are all carefully controlled by microscopic cells of the immune system. When this system breaks down, disease results.
Your immune system begins at the cellular level! The most important thing you can do for your health is to restore the proper function to your cells, and this can only be achieved by restoring cellular health!
In 1984-85, a group of symptomatic HIV-1 positive patients reported that oral aloe juice alleviated their AIDS symptoms. It was found that the active, anti-viral ingredient in aloe leaf gel was polymannose. This is a micronutrient that supports synthesis of innate defense molecules that destroy multiple types of infectious agents including bacteria and viruses. The mechanism of action is not that of antibiotics that poison or block the metabolism of micro-organisms. The biochemistry and immunology supported by this glyconutrient type of micronutrient-based defense is based on the up-regulation of innate, natural mechanisms for protection against and destruction of micro-organisms. Thus, antibiotic resistant organisms are destroyed by this enhancement of natural defense mechanisms through optimal dietary supplementation. The exact site and step in glycoprotein synthesis within the cell where mannose of aloe origin is utilized has been defined. This led to recognizing and formulating a mixture of natural saccharides (dietary sugars) known to be necessary in the golgi to provide a more efficient cellular synthesis of defense and tissue repair molecules.
Glyconutrients provide your body essential nutrients it requires to build and support glycoproteins.
Healthy bodies, comprised of many components working together in sophisticated harmony, must have accurate biochemical communication to function correctly. In its most basic form, this communication occurs at the cellular level and is referred to by molecular biologists as cell-to-cell communication.
So regardless of what condition you have, whether it is HIV, AIDS, heart disease, cancer or any other disease condition, you need to support your body and your bodies systems with essential nutrients that your body requires to function at an optimal level of health and therefore build a strong healthy immune system.
To obtain optimal health you must provide your body what it requires in the form of food and essential nutrients to support and build Cellular Restoration.
Because this AIDS virus attacks the immune system, it is of utmost importance to keep your body as healthy as possible to slow down the progression of the disease. It is absolutely vital that you have a good strong immune system so your body can fight off infections, colds, flus and protect your health and well being!
If you are dealing with HIV or AIDS, the single most important function you must have working for you is a strong vibrant immune system. Your immune system is your body's last line of defense in the prevention of disease.
With the right nutritional and wellness plan, people with HIV or AIDS can dramatically improve the quality of life and extend their lives.
The discovery of glyconutrients is the single most important discovery in nutritional science that will strengthen your immune system, restore cellular health, and create increased vitality.
What Snowflakes Tell Us
Overnight, the world turned white..... I always like to go outside before snow plows and shovels ruin a perfect picture. There's something very magical about the light reflected by billions and billions of unique crystals. Fallen from heaven, those tiny flakes perform a timeless, selfless act. Down to earth, they reflect the light of the moon and stars, giving back what they receive, before melting away, only to be reincarnated.
A Buddhist might say that the beauty of snowflakes lies in their transient nature. One moment they're here. The next, they're gone. But leave it to less-philosophical people to attempt to defeat the inevitable passing of time and stop the clock from ticking. We've become quite good at it, actually. I'm not referring to the treatments available in certain celebrity spas. Mankind has developed even more sophisticated time capsules that do not involve the use of Clostridium botulinum.
FACE IT
Instead of smoothing away the ripples of the past, I wish to preserve them as best as I can. Why? Because those wrinkles are the storylines of our life. It's where our 'biology reflects our biography', as Caroline Myss would put it. So, how do I go about my acts of self-preservation? It's quite simple.
I am a professional voice-over actor, so for this purpose I use a clever device that is capable of capturing the moment, right before its echo is about to disappear into nothingness. It's called a microphone. The very moment my sound meets the silence, I catch it; I record it and I store it in a safe place.
A PIONEER
It wasn't as easy for Wilson Bentley. Born in 1865, he grew up on a farm in Jericho, Vermont. As a teenager he became fascinated by snowflakes. When he was fifteen, his mother gave him a microscope, and soon Wilson was on a mission to capture what he affectionately called "ice flowers". Trying to draw them was impossible, because the flakes would vanish before he was able to finish the picture. His breath would take them away.
After years of experimentation, the 19-year old Bentley became the first person ever to photograph a single snow crystal, using a bellows camera to which he adapted a Dutch invention, the compound microscope. And it was Bentley, who discovered that no two snowflakes are alike.
During his lifetime, he captured more than five thousand snowflakes. He also published articles for magazines and journals including National Geographic and Scientific American, and filled nine notebooks with 47 years worth of his observations and analysis. In 1925 he wrote:
COMING HOME
While the world around me was covered up in white, I found myself reminiscing about a year that had nearly come to an end. Most moments had melted away, almost without a trace. But then I had to think of memories that had actually crystallized into something concrete. There's this small collection of blog posts that can still be read, and of course my voice can be heard on countless projects that, hopefully, will be around for a while.
No matter what we do in life, at some point in our journey, all of us have to ask ourselves the big questions:
"Does what I do really matter? What's the purpose? Do I make a difference? What do I leave behind when it's my time to go home?"
I'm no expert in the afterlife, but who knows... long after I'm gone, my grandchildren might even pick up one of the audio books I recorded this year. And as they listen to my voice, painstakingly preserved for posterity, the sounds that were frozen in time become fluid. In a flurry of words, past and present embrace each other in the now of the moment, and nothing, nothing will ever be the same again.
Call me a flake, but I think that's just very cool!
A Buddhist might say that the beauty of snowflakes lies in their transient nature. One moment they're here. The next, they're gone. But leave it to less-philosophical people to attempt to defeat the inevitable passing of time and stop the clock from ticking. We've become quite good at it, actually. I'm not referring to the treatments available in certain celebrity spas. Mankind has developed even more sophisticated time capsules that do not involve the use of Clostridium botulinum.
FACE IT
Instead of smoothing away the ripples of the past, I wish to preserve them as best as I can. Why? Because those wrinkles are the storylines of our life. It's where our 'biology reflects our biography', as Caroline Myss would put it. So, how do I go about my acts of self-preservation? It's quite simple.
I am a professional voice-over actor, so for this purpose I use a clever device that is capable of capturing the moment, right before its echo is about to disappear into nothingness. It's called a microphone. The very moment my sound meets the silence, I catch it; I record it and I store it in a safe place.
A PIONEER
It wasn't as easy for Wilson Bentley. Born in 1865, he grew up on a farm in Jericho, Vermont. As a teenager he became fascinated by snowflakes. When he was fifteen, his mother gave him a microscope, and soon Wilson was on a mission to capture what he affectionately called "ice flowers". Trying to draw them was impossible, because the flakes would vanish before he was able to finish the picture. His breath would take them away.
After years of experimentation, the 19-year old Bentley became the first person ever to photograph a single snow crystal, using a bellows camera to which he adapted a Dutch invention, the compound microscope. And it was Bentley, who discovered that no two snowflakes are alike.
During his lifetime, he captured more than five thousand snowflakes. He also published articles for magazines and journals including National Geographic and Scientific American, and filled nine notebooks with 47 years worth of his observations and analysis. In 1925 he wrote:
Earlier this year, on a trip to Vermont, I visited the Snowflake Bentley Museum at the Old Red Mill in Jericho. There I learned that this pioneer of science and photography, who had dedicated his life to studying snow crystals, eventually died of pneumonia after walking home through a blizzard. But, as that blockbuster movie trailer voice-over guy would say: "His legacy lives on."
"Under the microscope, I found that snowflakes were miracles of beauty; and it seemed a shame that this beauty should not be seen and appreciated by others. Every crystal was a masterpiece of design and no one design was ever repeated. When a snowflake melted, that design was forever lost. Just that much beauty was gone, without leaving any record behind."
COMING HOME
While the world around me was covered up in white, I found myself reminiscing about a year that had nearly come to an end. Most moments had melted away, almost without a trace. But then I had to think of memories that had actually crystallized into something concrete. There's this small collection of blog posts that can still be read, and of course my voice can be heard on countless projects that, hopefully, will be around for a while.
No matter what we do in life, at some point in our journey, all of us have to ask ourselves the big questions:
"Does what I do really matter? What's the purpose? Do I make a difference? What do I leave behind when it's my time to go home?"
I'm no expert in the afterlife, but who knows... long after I'm gone, my grandchildren might even pick up one of the audio books I recorded this year. And as they listen to my voice, painstakingly preserved for posterity, the sounds that were frozen in time become fluid. In a flurry of words, past and present embrace each other in the now of the moment, and nothing, nothing will ever be the same again.
Call me a flake, but I think that's just very cool!
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