You are up very high where barometric pressure is 447 mmHg. What is the partial pressure of oxygen in the air up there?

Correct Answer: C

Rationale: The correct answer is C (80 mmHg) because the partial pressure of oxygen in the air is directly proportional to the percentage of oxygen in the air. In the atmosphere, oxygen makes up approximately 21% of the air. Therefore, to calculate the partial pressure of oxygen, you would multiply the total barometric pressure by the percentage of oxygen (0.21). So, 447 mmHg x 0.21 = 94.07 mmHg. This is the partial pressure of oxygen at sea level. To find the partial pressure of oxygen at a higher altitude, you would consider the decrease in total barometric pressure. At 447 mmHg, the partial pressure of oxygen would be around 80 mmHg. Summary: A: Incorrect because it is too low. B: Incorrect because it is too low. D: Incorrect because it is too high.

Correct Answer: C

Rationale: The correct answer is C: Use diaphragmatic breathing. Diaphragmatic breathing involves using the diaphragm to breathe deeply, allowing more air to enter the lungs and improving oxygenation. This is beneficial for clients with chronic bronchitis as it helps improve lung function and efficiency. Making inhalation longer than exhalation (Choice A) may lead to hyperventilation. Exhaling through an open mouth (Choice B) can lead to loss of carbon dioxide. Using chest breathing (Choice D) is less efficient and can exacerbate breathing difficulties in clients with chronic bronchitis. Diaphragmatic breathing is the most effective technique for improving breathing and should be emphasized in teaching.

Correct Answer: A

Rationale: The correct answer is A. A client with suspected tuberculosis is likely to experience fatigue, weight loss, low-grade fevers, and night sweats due to the chronic infection affecting the body. Fatigue and weight loss are common symptoms of active tuberculosis due to the systemic impact of the infection. Low-grade fevers and night sweats are characteristic of tuberculosis due to the body's immune response. These symptoms are key indicators of tuberculosis infection. Choices B, C, and D are incorrect because they describe symptoms that are not typically associated with tuberculosis. Dyspnea, chest pain, and cough (Choice B) are more commonly seen in respiratory conditions such as pneumonia or bronchitis. Rapid shallow breathing, prolonged labored expiration, and stridor (Choice C) are indicative of airway obstruction rather than tuberculosis. Dyspnea, hypoxemia, and decreased pulmonary compliance (Choice D) are more characteristic of conditions such as chronic obstructive pulmonary disease (COPD) rather than tuberculosis.

Correct Answer: C

Rationale: The correct answer is C: Chronic obstructive bronchitis. The term "blue bloater" is a classic descriptor used in the context of chronic obstructive bronchitis. It refers to patients who exhibit cyanosis (blue discoloration of the skin due to lack of oxygen) and are often overweight and edematous. This term is used to differentiate from "pink puffers" who have emphysema. Both conditions are part of chronic obstructive pulmonary disease (COPD), but the "blue bloater" presentation is more characteristic of chronic bronchitis due to the chronic hypoxia and retained carbon dioxide. Now, let's evaluate why the other choices are incorrect: A: Acute respiratory distress syndrome (ARDS) typically presents with severe difficulty breathing and rapid onset of respiratory failure. It is not referred to as a "blue bloater." B: Asthma is characterized by reversible airway obstruction and wheezing, usually triggered by allergens or irrit

Correct Answer: D

Rationale: The correct answer is D because for the integumentary exchange of gases to occur efficiently, the surface of the animal must meet all three criteria: be thin and soft to allow gases to pass through easily, have a high number of blood vessels to facilitate gas exchange, and have a mucus or moist covering to prevent desiccation and aid in gas diffusion. If the surface is not thin and soft, gases cannot diffuse effectively. Without a high number of blood vessels, there wouldn't be sufficient transport of gases to and from the surface. And without a mucus or moist covering, the surface may dry out, hindering gas exchange. Therefore, all of the above factors are essential for the integumentary exchange of gases to function optimally.