Environment and Evolution

The environment and evolution of Homo sapiens are intrinsically related to one another. A harsh landscape, with particular climatological circumstances, favored evolution for the better, which was the result of forced adaptation. The disappearance of tropical rain forest and the proliferation of grass and grassy plains during the Miocene and Pliocene boosted the proliferation of ruminants. When these grass-eating quadruped thrived, so did the carnivores and, later, the meat-eating hominid, who was at the beginning a bone breaker that ate the bone marrow of big animals as source of calories.

Idealist people, especially vegans, think that the human evolution took place in an ideal paradise-like environment; a tropical land covered by a jungle full of fruit trees and black soil that spat out potatoes and pumpkin onto the surface of the ground. The bloated minds of utopian people imagine that our ancestors could grab a banana by simply stretching their arm, and if they got tired of banana, he could simply walk a few meters and pick peaches from the peach tree; or he could walk over to the apple tree. Vegans think like that because that is what they do when they go to a supermarket. They just pick the fruit they feel like eating on that particular day, but they never stop to think that all those fruit and vegetable come from different far-flung lands, with different weather patterns, and they are brought to site and concentrated in such great amount by modern means of transportation, and that they are not the product of nature’s generosity but of modern agriculture and industry.

Things were not that easy for our ancestors hundreds of thousands of years ago, for the relation between environment and evolution of Homo sapiens is the story of fighting for survival. There was no tropical fruit or potatoes cropping up out of the earth by magic, for the strife to keep themselves alive took place on the dry grassland of the African savanna and on the cold grassland of the Asian and European steppes and plains. Every discovery of Homo erectus (as well as of the Neanderthal and Cro-Magnon) fossil remains took place in rough environments where the grass grow wild.

Where there is grass growing, there is no jungle. But, on the grassland, there were more important and vital things to eat than fancy fruit, and these things were key to the evolution of our brains. Those vital things are the ruminants (bison, gnu, deer, springbok, goats, sheep, etc) and horses. Homo erectus, the first human, did not have a digestive enzyme that enabled him to break down the coarse grass of the plain, but he did have (as well as today) two powerful enzymes that could digest the four-legged animals that ate the grass: lipase, which breaks down fat, and chymotripsin, which dissolve proteins; these are innate enzymes.

At the beginning, as he lacked the strength and speed of the ferocious feline beasts, he could only wait until a bison or a gnu was hunted by lions as he watched from a distance; his erect posture and stereoscopic vision made of him a sharp observer. Once the big cats ate the entrails and soft meat, the hyenas came over to eat the sinewy muscles and tendons. Then it was man’s turn to chase away the vultures and proceeded to tap the hardest pieces of the carcass to obtain the most delicious and nutritious part of an animal; the bone marrow and the brains.

Although he did not have fangs, serrated teeth, and strong jaws to crack open the long bones and skulls, he had a pair of hands with powerful thumbs opposing the other four fingers which gave him a powerful grab on a stone with which he was able to hammer the bones and skulls open with precision and skills. Then he would discover what an efficient weapon a long bone shard could be when tied to the end of a sturdy stick.

Bone marrow and brains contain high concentration of high quality calories as well as vitamin B12, B6, and B1, vitamin A retinol, zinc, etc. One gram of today’s junk food carbs has only 4 calories, while one gram of saturated fat contains 9 calories, and these are good calories because fat does not raise your sugar level in your bloodstream the way carbs do, but it give you more energy in the form of ketone bodies. Ketone bodies (β-hydroxybutirate and acetoacetate) promotes the bioneogenesis of mitochondria (the production of more mitochondria within a cell, especially within the neurons, accelerating the production of ATP, which means a fast metabolism). This induces the division of the cell and the production of myelin, especially around the cerebral cortex neurons axons.

Below, the grassland of Africa. As on the Asian steppes, there were no bananas, no apples, no pears, no peaches, no flour, no bread, no cereals, no pancakes, no jam, no cakes, no cookies, no beer. There was only tall grass, grove of flat-topped trees in the distance, and wild beasts and ruminants, and slim-wiry, crafty Homo erectuses that strove for survival, using his hands and his good vision.

 

Artery vs Vein

In the artery vs vein comparison, there are clear functional and structural differences between these two blood vessels. Although they are both parts of the cardiovascular system, there are three important distinctions between them; the function they perform, the type of blood they convey, and the structural feature which one has and the other lacks. Nevertheless, at their extreme ends they are connected by the capillaries, which close the circulatory circuit. At this connection point the arteries and veins are so thin they are called arteriole and venule respectively.

The arteries carry oxygenated blood from the left ventricle of the heart to the rest of the body, with the aorta being the main artery, from which branches arise to supply the different tissues and organs with oxygen and nutrients. The oxygen gets into the blood when we breathe in. They transport the blood under the steady pressure of every systolic contraction of the myocardium; to put it plainly, arteries are able to carry blood thanks to the pumping action of the heart. This is the reason that when we measure somebody’s blood pressure, we do it on an artery.

The veins convey deoxygenated blood from the body tissues and organs back to the heart, to the right atrium, from which it runs into the right ventricle and finally into the lungs. By ‘deoxygenated’ I mean it contains carbon dioxide (CO2), which is expelled from the lungs when we exhale. CO2 is the main byproduct of the cellular respiration when the cells produce ATP (energy). Since they carry the blood back to the heart, that returning blood flow does not depend on the systole (heart ventricles contraction) but on the diastole, which is the heart relaxation; when it relaxes, the myocardium expands outwards as it returns to the normal shape as the right ventricle sucks in the returning blood.

Therefore, when the heart is in diastole, it has a suction action as it draws the blood into the right atrium. This is the opposite to the pumping action of the left ventricle (systole). Since the diastole (relaxation) suction effect is weaker than the systole (contraction), veins are aided by a series of valves, which prevent the deoxygenated blood from flowing back to the capillaries. These valves are located along the lumen of the veins; these valves are not present in arteries.

Below, a picture/diagram of the cardiovascular system, showing the arteries (in red) and veins (in blue).

 

Medial Inferior Genicular Artery

The medial inferior genicular artery is a blood vessel which lies in the posterior aspect of human knee, right under the medial head of the gastrocnemius muscle. It originates from the medial side of the popliteal artery. Then it runs medially and slightly downwards, curving around the medial periphery of the knee-joint under the medial ligament of knee.

Along its course, the medial inferior genicular gives off secondary branches which anastomose with branches of the medial superior genicular and descending genicular artery, thus being part of the knee vascular network. It supplies the head and tendon of the gastrocnemius, proximal end of tibia, and ligament of knee.

Below, the popliteal artery with its branches, which include the medial inferior genicular artery.

 

Human Humerus

The human humerus is a long tubular bone of the upper limb (arm). It consists of a shaft and two ends, which are called epiphysis. The upper portion of the shaft is round, while the lower part is trihedral.

The posterior surface of the shaft of humerus features the spiral groove, which lodges the radial nerve. It runs downwards and laterally. Meanwhile, the anterior surface is divided by a poorly defined border into an anteromedial surface and an anterolateral surface, which is the site of origin of the brachialis muscle. The lower half of the anteromedial surface has a nutrient foramen, which leads into a distally running nutrient canal. The deltoid tuberosity is lacated on the anterolateral surface of this bone.

The proximal epiphysis, which is the upper end, is thickened and it features the semispherical head of humerus. The head articulates with the glenoid cavity of scapula and it is separated from the rest of the bone by a shallow annular constriction, which is the anatomical neck.

The greater tuberosity and the lesser tuberosity are located right below the anatomical neck, on the anterolateral surface. They are separated from one another by the intertubercular groove. The greater tuberosity provides attachment to the supraspinatus, infraspinatus, and teres minor muscle, while the lesser tuberosity is the site of attachment for the subscapularis muscle.

The distal epiphysis, or lower end, is flattened in the anteroposterior direction. The distal segment of this bone bears in its lateral part a rounded eminence called the capitulum of the humerus, which is for articulation with the head of the radius bone. The trochlea of humerus is found next to this eminence, which is for articulation with trochlear notch of the ulna.

The distal epiphysis ends up in the lateral and medial epicondyle. The medial epicondyle is larger, with its posterior surface bearing the groove of the ulnar nerve. This groove and the epicondyles are easily palpated (felt with the tips of fingers) under the skin.

Below, the anterior and posterior view of the human humerus (right arm).

Sphenoid Bone

The sphenoid bone is a large butterfly-shaped bone of the skull. Together with the lower part of the occipital bone, it constitutes the biggest part of the base of the human cranium. It is much wider than it is long as its lateral sides stretches out from the center to form the greater wings (right and left) and the lesser wings of bone.

Anteriorly and superiorly, the sphenoid is bounded by the lower border of the frontal bone. Laterally, it is bounded by the temporal, and posteriorly by both the temporal and occipital bone, with which it forms the foramen magnum, which is a large opening for the passage of the spinal cord into the skull. The inferior surface of the orbitofrontal lobe of the brain rests on the lowest part of the greater wing.

Right at the center of the sphenoid, there is a small bone structure called the sella turcica, which is formed by a deep depression known as the hypophyseal fossa; the pituitary gland sits in the sella turcica. The size of the hypophyseal fossa depends on the size of the pituitary. In the greater wing, there are two small openings; one of them is the foramen ovale, which is a passage for nerves and blood vessels; the other the foramen rotundum, which is an small aperture for the maxillary branch of the trigeminal nerve (CN V).

Below, drawing of sphenoid and occipital bone (superior aspect), with names of different parts