The Kidneys receive about 25% of the blood flow from the heart through the renal arteries off the Abdominal Aorta. This is a very blood intensive organ because it filters the blood to take the waste out as urine and keep the nutrients, vitamins, salts, and minerals needed by the cells of the body. The blood enters the kidney through the Renal artery. It then branches into Segmental arteries which supply blood to different area's of the kidney. The Segmental arteries branch into Interlobar arteries which go in between the renal columns and pyramids. At the base of the renal pyramids the Interlobar arteries branch into Arcuate arteries that go between the medulla and cortex regions. The Arcuate arteries divide and become the Interlobular arteres that pass between renal lobules. Interlobular arteries continue into the cortex and branch into the Afferent arterioles which go into a Nephron and form a Glomerulus capillary network. The Glomerulus capillary network becomes the Efferent arterioles after they recombine. These Efferent arterioles split into the Peritubular capillaries which surround the tubule parts of the Nephron. The Peritubular capillaries merge into the Interlobular veins. This drains into the Arcuate veins to the Interlobar veins which pass the renal pyramids. The Interlobar veins come together to form the Renal vein that finally goes into the Inferior Vena Cava and back to the heart.
I found this slide show on the web that is pretty helpful in explaining how this works with pictures so all these words don't just run together and give you a head ache. There is even a nice little game to play at the end.
http://www.wisc-online.com/objects/AP2504/AP2504.swf
Wednesday, May 6, 2009
Electrocardiography
The Electrocardiogram or EKG or ECG is a way of monitoring the heart with electrodes on the skin of your body. It graphs a waveform of action potentials produced from the cardiac muscle fibers during each heartbeat. Electrodes are placed on the arms and legs and six positions on the chest to record the EKG. The EKG amplifies the electrode signal and produces a waveform like this.
The first is the P wave which is a small upward deflection that represents atrial depolarization. A fraction of a second after the P wave begins the atria contract. The second wave is the QRS complex. This begins as a downward deflection (Q) then a large upward triangular deflection (R) then ends in another downward deflection (S). The QRS complex represents ventricular depolarization as the action potential goes through the ventricular fibers. Very quickly after the start of the QRS the ventricals start to contract. The last wave is a upward dome shaped deflection called the T wave. It represents ventricular repolarization and occurs right before the ventricles relax.
The EKG is useful in diagnosing abnormal rhythems and conduction patterns, or used to monitor patients recovering from a heart attack. It can also be used to detect a fetus.
The first is the P wave which is a small upward deflection that represents atrial depolarization. A fraction of a second after the P wave begins the atria contract. The second wave is the QRS complex. This begins as a downward deflection (Q) then a large upward triangular deflection (R) then ends in another downward deflection (S). The QRS complex represents ventricular depolarization as the action potential goes through the ventricular fibers. Very quickly after the start of the QRS the ventricals start to contract. The last wave is a upward dome shaped deflection called the T wave. It represents ventricular repolarization and occurs right before the ventricles relax.
The EKG is useful in diagnosing abnormal rhythems and conduction patterns, or used to monitor patients recovering from a heart attack. It can also be used to detect a fetus.
Cranial Nerves
There are 12 cranial nerves attached to the under side of the brain. CN 1 is the Olfactory nerve which is your sense of smell. CN 2 is the Optic nerve which is your sight. CN 8 is the Vestibulocochlear nerve which is your hearing. CN 1, 2, and 8 are afferent or sensory only.
CN 3 is the Oculomotor nerve it controls the Superior and Inferior Rectus, Inferior Oblique, and Medial Rectus muscles. CN4 is the Trochlear nerve controls the Superior Oblique muscle. CN 6 is the Abducens which controls the Lateral Rectus muscle. CN 11 is the Accessory nerve which controls the Pharynx, Larynx, and Soft Palate that are used in swallowing. CN 12 is the Hypoglossal nerve which controls the tongue. CN 3, 4, 6, 11, 12 are motor neurons or efferent.
CN 3 is the oculomotor nerve which also adjusts your pupil size. CN 7 is the Facial nerve controls muscles in the face, neck, and scalp. It also controls your lacrimal glands (tear producing) and sublingual and submandibular glands (which produce saliva). CN 9 is the Glossopharyngeal nerve that control tastebuds in the posterior 1/3 of the tounge, controls muscles in swallowing. Also stimulates the Parotid gland to secrete saliva. CN10 is the Vagus nerve that controls taste buds in the epiglottis and pharynx. Also controls muscles in the neck and throat. Monitors blood pressure and respiratory function. It also controls smooth muscle in the Gi tract, respiratory passageway, esophagus, stomach, gallbladder, small intestines, and large intestines. CN3, 7, 9, and 10 are all part of the parasymathetic nervous system.
You can click on the picture to enlarge and read.
Tuesday, May 5, 2009
Fetal Blood flow
Blood from the mother and fetus exchange food and oxygen for carbon dioxide and wastes in the placenta. Because a fetus is growing so fast their blood has about 50% more hemoglobin in it to provide much more oxygen to the fetus. Blood flows from the placenta up through the umbilicus and into the fetus. There is about half of it goes to the liver and the other have go into the Ductous Venosus. After a short distance the Ductous Venosus joins the Inferior Vena Cava. Here the blood goes into the Right Atrium and splits again. Some goes into the Right Ventricle and some goes through a hole in the heart called the Foramen Ovale into the Left Atrium. Now most of the blood bypasses the lungs through a vessel called the Ductous Arteriosus which shunts blood from the Pulmonary Trunk into the decending arch of the Aorta. The blood travels down the aorta and splits again. Some goes out to the parts of the body and the rest is taken out to the placenta by the umbilical arteries.After the baby is born the Ductous Venosus becomes the Ligamentium Venosum which no longer carries blood. The Foramen Ovale will become the Fossa Ovalis which closes the hole in the Right Atrium to the Left Atrium. The Ductous Arteriosus become the Ligamentium arteriosum and the shunt from the pulmonary trunk to aorta is closed. This happens over a short period of time after the baby is born not just as it exits the mother. This link is helpful in explaining what happens. http://www.cayuga-cc.edu/people/web_pages/greer/biol204/heart4/heart4.html
Blood Types
There are four types of blood in the human body. They are O, A, B, and AB. As with the chart above each type has an antigen on the surface of every RBC except type O. This is the reason type O is the universal donor however type O people can only receive type O blood. The RBC's won't present an antigen for the immune system to recognize as a foreign substance in the body. Conversely type AB is the universal recipient because it has all the antibodies present, types A, B, AB, and O can all be given to someone with AB blood. The last part of this is the RH factor. This is where + or - come into play. Each blood type has a RH component so there is O+/-, A+/-, B+/-, and AB+/-. The plus simply means there is a marker on the RBC that is not present in the negative. This makes O negative as the universal donor and AB+ as the universal recipient. This chart summes everything up.
| Recipient[1] | Donor[1] | |||||||
|---|---|---|---|---|---|---|---|---|
| O− | O+ | A− | A+ | B− | B+ | AB− | AB+ | |
| O− |  | |||||||
| O+ | | | ||||||
| A− | | | ||||||
| A+ | | | | | ||||
| B− | | | ||||||
| B+ | | | | | ||||
| AB− | | | | | ||||
| AB+ | | | | | | | | |
Blood Flow Around the Heart
Blood moves to fast through the heart for the blood to nourish the heart. The heart is always pumping from before you are born till you die thus using a lot of nutrients and oxygen. Therefore once blood leaves the heart and enters the ascending aorta it branches off and supplies the heart with blood to give oxygen and nutrients and take away carbon dioxide and waste products. Arteries leaving the aorta are the Right Coronary artery which branches into the Right Marginal artery and the Posterior Interventricular artery (which goes around to the posterior of the heart from the bottom.
The other branch is the Left Coronary artery which branches into the Anterior Interventricular artery and the Circumflex artery.Blood is returned to the heart with three viens. The Great Cardiac vein which is beside the Anterior Interventricular artery. The Middle Cardiac vein which is beside the Posterior Interventricular vein. And finally the Lesser Cardiac vein which is beside the marginal artery. These three veins all dump into the Coronary Sinus which drains into the heart.
Monday, May 4, 2009
The Heart
The heart is what moves blood through the body. Blood first enters the heart at the Right Atrium from the Superior and Inferior Vena Cava. Here the blood goes through the Tricuspid valve into the Right Ventricle. On the next contraction the blood goes through the Pulmonary Valve and into the Pulmonary Trunk which splits into the right and left Pulmonary Arteries. Here is where the artery is pumping non-oxygenated blood into the lungs. After the gasses are exchanged in the lungs, (carbon dioxide for oxygen) through capillary networks, the blood goes back to the heart through the right and left Pulmonary Veins. Blood enters the Left Atrium fully oxygenated. Then the blood goes through the Bicuspid (Mitral) Valve into the Left Ventricle. Here blood is pumped into the Aorta to be distributed to the rest of the body through the Aortic Valve.
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