which structure do cells rely on for movement

ATI TEAS 7

ATI TEAS Practice Science Test

1. Which structure do cells rely on for movement?

A. Flagellum
B. Microtubule
C. Pili
D. Vesicle

Correct answer: A

Rationale: The correct answer is A: Flagellum. Cells rely on flagella for movement, which are whip-like structures that propel the cell forward through their whipping motion. Flagella provide motility to single-celled organisms and certain cells in multicellular organisms. Microtubules, on the other hand, provide structural support to the cell and play a role in intracellular transport. Pili are short, hair-like structures used for attachment to surfaces or other cells, not for movement. Vesicles are membrane-bound sacs involved in intracellular transport, aiding in the movement of substances within the cell, but not in the movement of the cell itself.

2. What is the significance of a healthy gut microbiome?

A. Production of digestive enzymes
B. Boosting the immune system and nutrient synthesis
C. Breakdown of complex carbohydrates
D. Regulation of appetite

Correct answer: B

Rationale: A healthy gut microbiome plays a crucial role in boosting the immune system by defending against harmful pathogens, synthesizing essential nutrients like vitamins, aiding in the digestion of certain foods, and maintaining overall gut health. While the gut microbiome does contribute to the breakdown of complex carbohydrates and regulation of appetite, its significance extends beyond these functions to include immune support and nutrient synthesis. Choice A, production of digestive enzymes, is not the primary significance of a healthy gut microbiome. Choice C is a function related to the gut microbiome but is not the sole significance. Choice D, regulation of appetite, is important but not as central as the immune system support and nutrient synthesis provided by a healthy gut microbiome.

3. Which class of hormones is most likely to be released after a serious injury?

A. Acetylcholine
B. Oxytocin
C. Luteinizing hormone
D. Endorphins

Correct answer: D

Rationale: Endorphins are the class of hormones most likely to be released after a serious injury. Endorphins are the body's natural pain relievers and are produced in response to stress or pain, helping to alleviate discomfort and promote a sense of well-being. Acetylcholine is a neurotransmitter, not a hormone. Oxytocin is mainly involved in childbirth and lactation. Luteinizing hormone is involved in reproductive functions such as ovulation. Therefore, choices A, B, and C are incorrect in the context of a hormone release following a serious injury.

4. Which of the following areas has the least amount of sweat glands?

A. Back
B. Palms
C. Axilla
D. Forehead

Correct answer: B

Rationale: The correct answer is B - Palms. The palms have the least amount of sweat glands compared to the other options listed. The back, axilla (armpits), and forehead are all areas with a higher concentration of sweat glands in the body. The palms have fewer sweat glands to minimize water loss and maintain a better grip for activities requiring precise and controlled movement. The back, axilla, and forehead have more sweat glands to assist in thermoregulation and cooling of the body, while the palms have fewer sweat glands for functional reasons related to grip and dexterity.

5. What is the role of surfactant in the respiratory system?

A. To trap dust particles
B. To increase lung compliance
C. To produce mucus
D. To generate oxygen during respiration

Correct answer: B

Rationale: The correct answer is B: To increase lung compliance. Surfactant is a substance produced by type II alveolar cells in the lungs that reduces surface tension in the alveoli. This reduction in surface tension helps to increase lung compliance, making it easier for the lungs to expand and contract during breathing. Improved lung compliance is essential for efficient gas exchange in the respiratory system, facilitating oxygen uptake and carbon dioxide removal. Choices A, C, and D are incorrect because surfactant does not trap dust particles, produce mucus, or generate oxygen during respiration. Instead, its primary function lies in reducing surface tension to prevent alveolar collapse and improve lung compliance for optimal gas exchange.