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Using the 3d model in medical research and training is worthwhile in most scenarios. Theoretical models are carried out in laboratory experiments and human models are used to teach about medical conditions. As for the human person, brain and hair 3d models can be used for a variety of reasons. Anyone inside the medical field will find different purposes and uses for such models, especially the 3d brain model.

As mentioned, the major reason that three-dimensional models are used is because they enable individuals to physically see areas of the human body as well as the brain that they otherwise would not have the capacity to see. The 3d brain model can be used in a classroom setting as an inexpensive option to having an actual brain to teach with. In addition, it may help students to grasp brain grooves and ridges beyond they had before.

An instructor can actually take a 3d brain model to reveal how the real human brain works right from a computer. Using such a 3d model is so dynamic that it creates a much more interesting learning experience.

In addition to a classroom setting on a college campus or in a medical presentation, a 3d brain model also helps with medical research. In the laboratory, this type of model can be used when conducting experiments on the human brain. Hypothetical situations can be carried out and treatments can be given while calculating the effects that they would have on the brain.

When deciding whether or not to invest in a 3d model, you need to consider the pros against the negatives. There are a couple ways to get your hands on a model of the brain without buying a ready-made stock 3d model. For instance, you could take the task on yourself and create a brain structure model. You could also work with a qualified artist to create a three-dimensional model. The one disadvantage to these options is that it can be expensive, but the benefits may outweigh the negatives.

After getting acquainted with the 3d brain model, you may want to further your insight of the body by taking the next step with a hair 3d model. Adding hair to your 3d brain model will give a complete understanding about the human head as a whole.

With that said, investing in a top, ready-made model will pay off over a stretch of time. You will find other methods around that are used to explain the parts of the brain, but none can rival the brain 3d model. The hair 3d model is an added benefit to the brain 3d model in that it furthers the student’s understanding of the brain and the relationship that it has with other parts of the body.

Basically, there are distinctive uses for a 3d brain model. The healthcare industry is just one of many areas where 3d models are used to advance the student or the professional in his or her field.

Looking for a 3d brain model or 3d hair model? Get started with the best way to learn the makeup of a brain by downloading 3d brain model or supplemental hair 3d model today at Flatpyramid.com, the trusted source for 3d models.

A normal human brain weighs about 2% of the total body weight. Human brain grows up to 75-80% of the adult size with in the first two years and full size at the age of 6 years. It is situated in a bony case called cranium which protect it from injuries. Brain is covered with cranial meninges. Human brain is wrinkled surface and pinkish grey in colour. It is formed of more than 100 billion neurons. Since each neuron can connect with about 25,000 other cells there are about 2.5 million billions inter linked nerve connection in the brain. Human brain can be divided in to three regions, Fore brain, Mid brain and Hind brain..for  details visit

 http://expertscolumn.com/content/different-parts-human-brain-and-its-functions

                                    Fore brain

          Fore brain consists of cerebrum and diencephalons.

A)Cerebrum

Cerebrum is the largest portion and occupies about 2/3 portions of human brain. It is divided by longitudinal fissures in to two cerebral hemispheres. Two hemispheres are connected by a horizontal sheet of nerve fibre called corpus callosum. It consists of long bundles of densely packed nerve fibre which are 10 cm long. There are about 200 millions of nerve fibres in the corpus callosum.

Each cerebral hemisphere is divided in to four lobes by three deep grooves called fissures. From the front to the back they are frontal lobe, temporal lobe, parietal lobe and occipital lobe. The left part of the brain controls the right part of body and right half controls the left part.

 

Functions of various lobes of cerebrum

1)Frontal lobe

  It involves in the inner monitoring of complex thoughts and actions and creative ideas. It helps in the translation of perceptions and memories in to action. Will power and personality is affected by the development of this lobe. Abstracting ability and decision making ability is controlled by this lobe.

2)Temporal lobe

    Temporal lobe helps in the decoding and interpretation of sounds. It helps in the language comprehension. It is the centre for memory and emotions.

3)Parietal lobe

   It is the main area for feeling of touch, hot, cold and pain. It takes informations from surroundings and organizes it and communicates to the other part of the brain. It controls activities like reading a clock, dressing ourselves.

4)Occipital lobe

   Occipital lobe decodes and interprets the visual informations such as shape and colour.

 

 

 Cerebral Cortex

  The outer surface of the cerebrum is called cerebral cortex. It is a layer of 2-4 mm thick. Cerebral complex has a grayish brown appearance . Hence it is referred to as gray matter. Surface of cerebral cortex is divided in to many number of folds. This increases the surface area of the brain.

 

B) Diencephlon

   Diencephlon is hidden by cerebrum. It consists of mainly subcortical nuclei, thalamus and hypothalamus.

 

1)Subcortical Nuclei

 Different collections of neurons are known as nuclei. Each nucleus has its own specific function. The nuclei has its own functions. The nuclei control different activities automatically. In the forebrain at the base of the cortex there is a collection of subcortical nuclei. It is called basal ganglia. Corpus striatum is the largest nucleus present in it. It regulates planning and execution of stereotyped movements.

 2)Thalamus

   Thalamus lies laterally posterior to the cerebrum. It is the important link between   sense organs and cerebral cortex. Thalamus receives majority of the incoming signal  from the sense organs. It determines the source of signals, evaluates their importance and integrates and passes them to the cerebrum.

 3)Hypothalamus

  Hypothalamus lies in the base of thalamus. It is a small vascularised structure weighs about 4 gm. It is only about 1/300 of the total brain mass.

 

  Functions of hypothalamus

1)     It integrate and control visceral activities. The nuclei present in the hypothalamus gives signal to the body to eat, drink, get angry, keep cool, make love etc

2)     Through its connections to the brain stem it maintains homeostasis and internal equilibrium of the body.

3)     It organizes behaviour related to the survival of the species such as fighting, feeding, fleeing and mating. A septum which is linked to the hypothalamus contains another emotion centre for sexual arousal.

4)     It maintains body temperature at constant level by means of a complex thermostat system.

5)     They correct the rate of heart beat and respiration if they are wrong.

 

                                       Mid brain

It forms the middle portion of the brain. It controls the activity of voluntary muscles. It is also concerned with auditory and visual reflexes. Mid brain consists of four small lobes called corpora quadrigemina. The upper lobes are a pair of  superior colliculi and lower lobes are called inferior colliculi. The superior part of colliculi receives sensory informations from eyes and muscles of the head. They control all visual reflexes by co-ordinating the movements of head and eyes. The inferior pair of colliculi receives sensory impulses from the ears and muscles of the head. They control all auditory reflexes.

 

                                       Hind brain

Hind brain consists of cerebellum, medulla oblongata and pons varoli.

1)Cerebellum

   Cerebellum is the second largest part of the brain. It is placed between the cerebral hemispheres and brain stem. It is made up of two cerebral hemispheres.

Functions of cerebellum

A)It maintains of posture and equilibrium of the body is another function.

B)Cerebellum plays an important role in controlling all rapid muscular activities such as running, typing, talking etc

  2)Medulla oblongata

     It is the posterior most part of the brain. It connects the various parts of the  brain with spinal cord. Medulla controls important subconscious activities such as breathing, digestion, heart beat etc

 3)Pons varoli

    Pons varoli forms the floor of the brain stem. It is a neural connection connecting the cerebral cortex with cerebellum. It relays the information between cerebrum and cerebellum.

ANOTHER superb organ is the human brain. It, together with the rest of the nervous system, is often compared to man-made computers. Of course, computers are constructed by humans and operate according to step-by-step instructions predetermined by human programmers. Yet, many people believe that no intelligence was responsible for “wiring” and “programming” the human brain.

Although extremely fast, computers handle only one piece of information at a time, whereas the human nervous system processes millions of pieces of information simultaneously. For example, during a stroll in the springtime, you can enjoy the beautiful scenery, listen to the song of birds, and smell the flowers. All these pleasant sensations are transmitted simultaneously to your brain. At the same time, streams of information flow from the sense receptors in your limbs, informing your brain of the moment-to-moment position of each leg and the state of each muscle. Obstacles in the footpath ahead are noticed by your eyes. On the basis of all this information, your brain ensures that each step is taken smoothly.

Meanwhile, the lower regions of your brain govern your heartbeat, breathing, and other vital functions. But your brain handles much more. As you walk, you can sing, talk, compare present scenes with past scenes, or make plans for the future.

“The brain,” concludes The Body Book, “is much more than a computer. No computer can decide that it is bored or wasting its talents and should embark on a new way of life. The computer cannot drastically alter its own program; before it sets out in a new direction, a person with a brain must reprogram it. . . . A computer cannot relax, or daydream, or laugh. It cannot become inspired or creative. It cannot experience consciousness or perceive meaning. It cannot fall in love.”

The Most Wonderful Brain of All

Animals such as elephants and some large sea creatures have brains larger than that of a human, but in proportion to body size, the human brain is the largest of all. “The gorilla,” explains Richard Thompson in his book The Brain, “is physically larger than a human yet has a brain only one-fourth the size of the human one.”

The number of different pathways between neurons (nerve cells) in the human brain is astronomical. This is because neurons have so many interconnections; one neuron may connect up with over one hundred thousand others. “The figure of possible connections within our modern brain is as good as infinite,” states Anthony Smith in his book The Mind. It is larger “than the total number of atomic particles that make up the known universe,” says neuroscientist Thompson.

But there is something even more remarkable. It is the way this vast network of neurons has been connected that enables humans to think, speak, listen, read, and write. And these things can be done in two or more languages. “Language is the crucial difference between humans and animals,” states Karl Sabbagh in his book The Living Body. Animal communication is simple by comparison. The difference, admits evolutionist Sabbagh, “is not just a trivial improvement on other animals’ abilities to make noises it is the fundamental property that makes humans human, and it is reflected in major differences in brain structure.”

The marvelous structure of the human brain has motivated many to make better use of its potential by becoming skilled at some trade, learning to play a musical instrument, mastering another language, or developing whatever talents add joy to life. “When you learn a new skill,” write Drs. R. and B. Bruun in their book The Human Body, “you are training your neurons to connect in a new way. . . . The more you use your brain, the more efficient it will become.”

Made by Whom?

Could something so highly organized and orderly like the hand, the eye, and the brain have come about by chance? If man is credited with inventing tools, computers, and photographic film, surely someone should be honored for making the more versatile hand, eye, and brain. “O Jehovah,” the Bible psalmist said, “I shall laud you because in a fear-inspiring way I am wonderfully made. Your works are wonderful, as my soul is very well aware.” Psalm 139:1, 14.

Many wonderful functions of the human body take place without our conscious effort. Future post of this blog will discuss some of these amazing mechanisms, and also whether aging, sickness, and death can be conquered, so that we can enjoy life forever!

Your Wonderful Neurons

A NEURON is a nerve cell with all its processes. Your nervous system contains many types of neurons, which total about 500 billion. Some are sense receptors that send information from different parts of the body to your brain. Neurons in the higher region of your brain function like a video recorder. They can permanently store information that comes from your eyes and ears. Years later you can “play back” these sights and sounds, along with thoughts and other sensations that no man-made machine can record.

Human memory is still a mystery. It has something to do with the way neurons connect. “The average brain cell,” explains Karl Sabbagh in his book The Living Body, “links up with about 60,000 others; indeed some cells have links with up to a quarter of a million others. . . . The human brain could hold at least 1000 times as much information in the pathways connecting its nerve cells as is contained in the largest encyclopedia say 20 or 30 big volumes.”

But how does one neuron pass information to another? Creatures with a simple nervous system have many nerve cells that are joined together. In such a case, an electrical impulse crosses the bridge from one neuron to the next. The crossing is called an electrical synapse. It is fast and simple.

Strange as it may seem, most neurons in the human body pass messages via a chemical synapse. This slower, more complex method can be illustrated by a train that reaches a river without a bridge and has to be ferried across. When an electrical impulse reaches a chemical synapse, it has to stop because a gap separates the two neurons. Here the signal is “ferried” across by the transfer of chemicals. Why this complex electro-chemical method of passing nerve impulses?

Scientists see many advantages in the chemical synapse. It ensures that messages pass one way. Also, it is described as plastic because its function or structure can easily change. Here signals can be modified. Through use, some chemical synapses get stronger while others disappear because of disuse. “Learning and memory could not develop in a nervous system that had only electrical synapses,” states Richard Thompson in his book The Brain.

Science writer Smith explains in his book The Mind: “Neurons do not just fire and not fire . . . they must be capable of passing on much more subtle information than yes or no. They are not just hammers hitting the next nail, either more frequently or less so. They are, to complete this analogy, a carpenter’s kit, with screwdrivers, pliers, pincers, mallets and hammers. . . . Each neural impulse is transformed along the way, and nowhere else than at the synapses.”

The chemical synapse has a further advantage. It takes less space than an electrical synapse, which explains why the human brain has so many synapses. The journal Science gives a figure of 100,000,000,000,000 equivalent to the number of stars in hundreds of Milky Way galaxies. “We are what we are,” adds neuroscientist Thompson, “because our brains are basically chemical machines rather than electrical ones.”

 

Why Your Brain Needs So Much Blood

BEFORE diving into a swimming pool, perhaps you dip your toes into the water. If the water is cold, tiny cold receptors in your skin quickly respond. In less than a second, your brain registers the temperature. Pain receptors can transmit information even more quickly. Some nerve impulses reach speeds of 225 miles [360 km] per hour comparable to running the length of a football field in one second.

How, th
ough, does the brain work out the intensity of a sensation? One way is by the frequency with which a neuron fires; some fire a thousand or more times a second. The intense activity that takes place among neurons in the brain would be impossible were it not for the work of pumps and powerhouses.

Each time a neuron fires, atoms with an electrical charge pour into the cell. If these sodium ions, as they are called, are allowed to accumulate, the neuron will gradually lose its ability to fire. How is the problem solved? “Every neuron,” explains science writer Anthony Smith in his book The Mind, “contains about a million pumps each one is a slight bump on the cell membrane and every pump can swap about 200 sodium ions for 130 potassium ions every second.” Even when neurons rest, the pumps keep working. Why? To counteract the effect of sodium ions that leak into the cell and potassium ions that leak out.

The activity of the pumps requires a constant supply of energy. The energy comes from tiny mitochondria, or “powerhouses,” scattered inside each cell. To produce energy, each powerhouse needs oxygen and glucose supplied by the blood. No wonder your brain needs so much blood. “Although it constitutes only about 2 percent of total body weight,” explains Richard Thompson in his book The Brain, it “receives 16 percent of the blood supply . . . Brain tissue receives 10 times as much blood as muscle tissue.”

The next time you feel the temperature of water, be thankful for the trillions of pumps and powerhouses in your brain. And remember that all this activity is possible because of oxygen and glucose transported by your blood.

The human brain processes millions of bits of information simultaneously. As you move, sense receptors in your limbs inform your brain of the moment-to-moment position of each arm and the state of each muscle

The brain is far more complex and versatile than a computer