Everything today is a product of evolution. From apes to Homo sapiens, humans have evolved from crawling on all fours to walking on two, flat feet. Mammals have grown from tiny rodents to a diverse category of cats, horses, dogs, elephants, dolphins, and many others. However, there wouldn't be evolution without natural selection; it's what sets everything apart and gives unique genes a purpose. Without this, species would not have the chance to adapt and thrive in the various, ever-changing climates of the world. Polar bears have thick coats to keep them warm in the arctic, cactus have spikes to protect them from the harsh, desert environments, and dolphins use sonar to communicate and detect objects underwater. However, the traits that help certain species survive may, in turn, hurt others. For example, humans have been fighting with pathogenic bacteria for hundreds of years. When antibiotics came along, it seemed that humans were winning the war against sickness. Yet recently, harmful bacteria are making a comeback and slowly, but surely, are becoming resistant to the many antibiotics that are available today. Through evolution and natural selection, bacteria have mutated and multiplied so quickly scientists can hardly keep up. Soon the world could be facing another pandemic, and the ones from the past left more than a small dent on the human population. Though evolution is impossible to stop, humans have also played a role in speeding up the process of antibiotic resistant bacteria; from misdiagnosing illnesses to dumping old antibiotics in the trash, all over the world people play a role in whether we win or lose this battle against bacteria.
Antibiotics are essential for fighting off illnesses caused by pathogenic bacteria....
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What do bacteria need to grow? For bacteria to grow the most typical thing that they like ate a warm and moist environment, but that is not all that they like. Bacteria also like and environment with a PH that is normal or close to a human PH and bacteria also like an oxygen rich environment. The places that could be common to find bacteria in a building are a keyboard, a water fountain, and restrooms. A keyboard is a common place for bacteria because it is being touched constantly with hands when people type and hands are warm, so bacteria like them. The water fountain is another place that is common for bacteria to grow because people's warm hands are touching it and also it has water, which causes it to be moist. The last place that bacteria will we commonly found in buildings are restrooms. The bacteria like restrooms because many people are in then and also there is a lot of water in them.
In her book, Dorothy Crawford gives biographies of the history of microbes which have brought humans diseases on a large scale. These include epidemics like yellow fever, tuberculosis, smallpox, acute respiratory syndrome, bubonic plague, syphilis HIV, the Black Death, malaria and cholera. It is worth to point out that her work is up to date because most of these microbes are still with us in this era. Crawford uses the historical bibliography of humans experience with microbes to show a fact that microbes shaped our culture through infection, disease, and pandemic. At the same time, the ever changing human culture has also largely influenced the evolutionary nature of microbes.
Others include defenses, genes, and design compromises. Some health practitioners treat symptoms without consideration of evolution. This is dangerous both to the individual and to society as a whole. If a fever is viewed as a highly evolved bodily defense, then the decision to treat that fever takes on a new level of consideration. If iron deficiency is a defense to chronic infection, should a supplement be prescribed? If the defense threatens the well being of the patient, then treatment is necessary. If the defense presents discomfort, but is fighting the pathogen, treatment may present the greater danger. On a societal scale, failure to consider evolution combined with over prescription of antibiotics to treat bodily defenses has lead to “superbugs” resistant to
An Evolving Epidemic Head scientist at the antibiotic research center at McMaster University in Hamilton, Ohio, Gerry Wright, has studied the genes of 500 streptomyces strains, a type of bacteria, many of which had never previously been identified. All 500 strains held antibiotic-resistance genes and on average were resistant to 8 of 21 tested antibiotics (Sachs). With an average resistance rate as high as 67 percent in some of these streptomyces species, it is evident that antibiotic resistance is a rising problem. Regardless of the countless studies proving antibiotic resistance and articles about the subject, it is one the public knows little about. With such a history of antibiotic benefits, it is difficult to perceive the negative effects these drugs have.
The Centers for Disease Control and Prevention (CDC), describes antibiotic resistance is the ability of bacteria or other microbes to resist the effects of antibiotic treatment. () So instead of being destroyed by the medications, the bacteria survives and continues to reproduce, resultant in new communicable diseases that even more difficult to treat.
As every species in the world developed, it's sub-species and it's further strains and breeds under those have evolved for a very specific reason - the preservation of the species, and ultimately, life itself. Each species is like a tree, with hundreds of branches, each leading to thousands of other branches. Each branch of the tree is slightly different from the one beside it, due to living in a different environment it has had to adapt and the resulting differences are due to the combination - the formula - of genes, which has survived the best in whatever environment it has encountered. Because of this branching of the species, whenever a particular disease, a natural phenomenon, or a new predator has arrived on the scene, the species has always been diverse enough to continue, as there will be one branch of the tree which has the immunity, adapted over time, in order to defend itself or escape from the catastrophe. This method, special branching, has ensured the survival of various species for thousands of years, and is in fact the reason for the existance of different species.
If the thousands of mutations continued to occur without natural selection, humans would have thousands of subspecies, and resources would be scarce. Natural selection brings diseases that are connected to mutations to create a pathway for evolution, but without natural selection humans are evolving with no direction. Modern medicine has become so advanced, diseases are no longer a threat to the population. When an epidemic breaks out, a cure or vaccination is created within two years. “Medicine can be described as ‘the comprehensive attempt to frustrate the course of nature’” as said by John Harris. When cancer was first introduced to mankind, it was because humans are living too long. Now cancer is being found in children and babies. Cancer is nature’s way of reintroducing natural
Evolution in general, is a hard concept to grasp. There are multiple factors that effect the outcome a species, for example: genetics, nurture, nature, and the environment all play an important role. It was once said that species do not survive due to the fact that they are the strongest or the most intelligent, but because that species is the most responsive to change.
It also allows species to survive. It produces new and different species through ancestral populations of organisms and moves them to new populations. Both natural selection and genetic drift decrease genetic variation. If they were the only mechanisms of evolution, populations would eventually become homogeneous and further evolution would be impossible. There are, however, mechanisms that replace variation depleted by selection and drift (Colby).
E. Coli 0157, written by Mary Heersink, is a nerve-racking, adrenaline-filled story of a mother's experience with a then unknown deadly bacteria. The book brings up many reactions in its readers, especially the questioning of the practice of doctors in hospitals. The reader's knowledge base of scientific procedures in emergency centers was widened as well as the knowledge of how to the human body reacts to different agents in its system.
In the last decade, the number of prescriptions for antibiotics has increases. Even though, antibiotics are helpful, an excess amount of antibiotics can be dangerous. Quite often antibiotics are wrongly prescribed to cure viruses when they are meant to target bacteria. Antibiotics are a type of medicine that is prone to kill microorganisms, or bacteria. By examining the PBS documentary Hunting the Nightmare Bacteria and the article “U.S. government taps GlaxoSmithKline for New Antibiotics” by Ben Hirschler as well as a few other articles can help depict the problem that is of doctors prescribing antibiotics wrongly or excessively, which can led to becoming harmful to the body.
Bacterial cells, like plant cells, are surrounded by a cell wall. However, bacterial cell walls are made up of polysaccharide chains linked to amino acids, while plant cell walls are made up of cellulose, which contains no amino acids. Many bacteria secrete a slimy capsule around the outside of the cell wall. The capsule provides additional protection for the cell. Many of the bacteria that cause diseases in animals are surrounded by a capsule. The capsule prevents the white blood cells and antibodies from destroying the invading bacterium. Inside the capsule and the cell wall is the cell membrane. In aerobic bacteria, the reactions of cellular respiration take place on fingerlike infoldings of the cell membrane. Ribosomes are scattered throughout the cytoplasm, and the DNA is generally found in the center of the cell. Many bacilli and spirilla have flagella, which are used for locomotion in water. A few types of bacteria that lack flagella move by gliding on a surface. However, the mechanism of this gliding motion is unknown. Most bacteria are aerobic, they require free oxygen to carry on cellular respiration. Some bacteria, called facultatibe anaerobes can live in either the presence or absence of free oxygen. They obtain energy either by aerobic respiration when oxygen is present or by fermentation when oxygen is absent. Still other bacteria cannot live in the presence of oxygen. These are called obligate anaerobes. Such bacteria obtain energy only fermentation. Through fermentation, different groups of bacteria produce a wide variety of organic compounds. Besides ethyl alcohol and lactic acid, bacterial fermentation can produce acetic acid, acetone, butyl alcohol, glycol, butyric acid, propionic acid, and methane, the main component of natural gas. Most bacteria are heterotrophic bacteria are either saprophytes or parasites. Saprophytes feed on the remains of dead plants and animals, and ordinarily do not cause disease. They release digestive enzymes onto the organic matter. The enzymes breakdown the large food molecules into smaller molecules, which are absorbed by the bacterial cells. Parasites live on or in living organisms, and may cause disease. A few types of bacteria are Autotrophic, they can synthesize the organic nutrients they require from inorganic substances. Autotrophic bacteria are either photosynthetic or Chemosynthetic. The photosynthetic bacteria contain chlorophyll that are different from the plant chlorophyll. In bacterial photosynthesis, hydrogen is obtained by the splitting of compounds other than water.
Infection control is very important in the health care profession. Health care professionals, who do not practice proper infection control, allow themselves to become susceptible to a number of infections. Among the most dreaded of these infections are: hepatitis B (HBV), hepatitis C (HCV), and human immunodeficiency virus (HIV). Another infection which has more recently increased in prevalence is methicillin-resistant Staphylococcus aureus (MRSA). These infections are all treated differently. Each infection has its own symptoms, classifications, and incubation periods. These infections are transmitted in very similar fashions, but they do not all target the same population.
Throughout all of history, humans have been evolving not only genetically, but also culturally. Of the two evolutionary processes, cultural evolution happens more quickly, and has had a more noticeable effect on the environment compared to genetic evolution. Early hunter/gatherer societies evolved to agrarian society, which then had technological changes that affected the culture of the society. Unfortunately, while humans have been culturally evolving towards what is perceived to be progress, the environment has been compromised, marginalized, and degraded as it is continually exploited for human benefit and consumption.
Natural selection is based on the concept “survival of the fittest” where the most favourable individual best suited in the environment survive and pass on their genes for the next generation. Those individual who are less suited to the environment will die.