I belive that the correct answer is you will undergo a condition called metabolic acidosis.
The pH of blood is 7.35 and the pH of pure water ranges from 7-8.5 but it is most steady at a pH of 7. Infusing tap water would prove to be detrimental due to a combination of problems. Pure water contains minerals and ions that make the pH of the water more acidic. Adding an acidic liquid into the bloodstream directly will cause a spike of blood pH. To balance this acidic pH, the respiration of the person will increase so that breathing will be shallow to provide oxygen while removing more carbon dioxie. CO2 contributes to the pH of the body by making the blood more acidic when it forms carbonic acid. Reducing it in circulation will increase the pH of blood. Using the lungs to balance the pH is called respiratory compensation and in the instance of metabolic acidosis, the situation will be metabolic acidosis with respiratory compensation. The body will also turn to the kidney where the kidneys will stop reabsorbing more sodium ions so that when the ions are released in urine, the pH in blood will try to stabilize. This will be a problem because water will be lost as sodium ions are lost and the person involved will start to have cardiovascular conditions such as arrhythmias and muscle spasms since sodium is essential for muscles to communicate. Dehydration would range from moderate to severe and if left unattended, the person is going to have a stroke in the brain. With the brain shutting down due to the stroke, the person will not be able to breathe as ast as the body wanted to regulate the pH. So basically, the body would sabotage itself and it is a very bad idea to try to infuse pure water. Pure water is also not sterile meaning there are microorganisms that live in it and if added into the bloodstream, they can cause severe blood infections that can lead to sepsis and this will just worsen the condition of the person over time. To diagnose the acidosis, a test called Arterial Blood Gases (ABGs) is done to asses the balance of acids and bases in the blood and find out how to correct them to return homeostasis back to normal.
Learn more about the circulatory system: brainly.com/question/2093482
Learn more about homeostasis: brainly.com/question/1601808?source=aid8181116
Learn more about the heart: brainly.com/question/967969?source=aid8181676
Level: College
Subject: Clinical Chemistry
Topic: Metabolic Disorders
Answer:
A) Does not change the activation energy
B) Raises the activation energy
C) Lowers the activation energy
D) Eliminates the activation energy
Answer:
c. lowers the activation energy
Explanation:
Enzymes are biological catalysts. Catalysts lower the activation energy for reactions. The lower the activation energy for a reaction, the faster the rate. Thus enzymes speed up reactions by lowering activation energy.
b. egg cells.
c. stem cells.
d. somatic cells. E. germ cells
(1) increased warming of local ecosystems
(2) increased exposure to ultraviolet light
(3) reduction in the pH of acid precipitation
(4) reduction in the frequency of floods and
droughts
Answer:
The correct answer is option (2) "increased exposure to ultraviolet light".
Explanation:
The ozone shield or the ozone layer is a region of the atmosphere comprised of high concentrations of ozone that absorbs most of the Sun's ultraviolet radiation. Therefore, damage to the ozone shield will cause increased exposure to ultraviolet light over the United States. This could cause harmful consequences such as an increase of cases of skin cancer, sunburn and cataracts.
A) nervous system
B) a mouth
C) stinging cells
D) spicules
Answer:
A mouth
Explanation:
The answer is that cnidarians lack triploblastic development. Cnidarians, such as jellyfish, sea anemone, and hydra, exhibit diploblastic development. This means that they have only two germ layers: the ectoderm and the endoderm. To understand triploblastic development, let's break it down. Triploblastic development refers to the formation of three germ layers: the ectoderm, the mesoderm, and the endoderm. These germ layers give rise to different tissues and organs in the body. In contrast, cnidarians lack the mesoderm layer. The mesoderm layer is responsible for forming muscles, connective tissues, and other internal structures. Since cnidarians do not have this layer, they are considered diploblastic. Let's use an example to illustrate this. Imagine you have a triploblastic organism, like a human. In a human, the mesoderm layer gives rise to muscles, which allow us to move. But in cnidarians, since they lack the mesoderm layer, they do not have true muscles. So, to summarize, cnidarians lack triploblastic development because they do not have the mesoderm layer. Instead, they exhibit diploblastic development, with only two germ layers: the ectoderm and the endoderm