Name the polysaccharide synthesized by human cells and stored in the liver and skeletal muscles.
Lactose
Glucose
Glycogen
Cellulose
The Correct Answer is C
Polysaccharides are complex carbohydrates composed of long chains of monosaccharide units, primarily glucose. In humans, these molecules play a major role in energy storage and structural support. The body must maintain a readily available energy reserve to sustain metabolic demands between meals and during physical activity. Glycogen is the primary storage polysaccharide in humans, synthesized in liver and skeletal muscle cells and tightly regulated by hormonal control.
A. Lactose: Lactose is a disaccharide composed of glucose and galactose and is primarily found in milk and dairy products. It is not a storage polysaccharide in human tissues. Instead, it functions as a dietary carbohydrate that is digested in the small intestine by lactase. Since it is not synthesized for long-term energy storage in liver or muscle, it is incorrect.
B. Glucose: Glucose is a monosaccharide and serves as the primary immediate energy source for cellular metabolism. It is not a polysaccharide and therefore cannot be stored in long polymerized form as glycogen. Excess glucose in the body is converted into glycogen for storage or into fat for long-term energy reserves.
C. Glycogen: Glycogen is the storage polysaccharide synthesized in humans and stored mainly in the liver and skeletal muscles. It consists of highly branched chains of glucose molecules linked by α-1,4 and α-1,6 glycosidic bonds. In the liver, glycogen helps maintain blood glucose levels during fasting, while in muscle, it provides a rapid energy source for contraction. Its structure allows rapid mobilization when energy is required.
D. Cellulose: Cellulose is a structural polysaccharide found in the cell walls of plants and is composed of β-glucose units linked by β-1,4 glycosidic bonds. Humans lack the enzyme cellulase required to digest cellulose, making it a dietary fiber rather than a storage molecule. It is not synthesized or stored in human tissues.
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Related Questions
Correct Answer is C
Explanation
During embryonic development, the central nervous system originates from three primary brain vesicles: the forebrain (prosencephalon), midbrain (mesencephalon), and hindbrain (rhombencephalon). Each of these vesicles differentiates into specific structures of the mature brain. The forebrain is the most complex and gives rise to higher-order processing centers involved in cognition, sensory integration, and autonomic regulation. It ultimately forms both the cerebrum and diencephalon, which are essential for conscious thought and homeostatic control.
A. Medulla oblongata and spinal cord: these structures develop from the hindbrain (rhombencephalon) and neural tube, not the forebrain. The medulla oblongata is part of the brainstem and is responsible for autonomic functions such as respiration and heart rate regulation. The spinal cord arises caudal to the brainstem from the neural tube. Therefore, they are not derivatives of the forebrain.
B. Cerebellum and pons: both the cerebellum and pons arise from the hindbrain, specifically the metencephalon. The cerebellum is responsible for coordination and balance, while the pons acts as a relay center between different parts of the brain. These structures are not derived from the embryonic forebrain.
C. Cerebrum and diencephalon: the embryonic forebrain (prosencephalon) differentiates into the telencephalon and diencephalon. The telencephalon develops into the cerebrum, which is responsible for higher cognitive functions, voluntary movement, and sensory perception. The diencephalon forms structures such as the thalamus and hypothalamus, which are involved in sensory relay and autonomic regulation. These structures collectively represent the mature derivatives of the forebrain.
D. Midbrain and medulla oblongata: the midbrain develops from the mesencephalon (midbrain vesicle), and the medulla oblongata develops from the hindbrain. The forebrain does not contribute to either of these structures.
Correct Answer is B
Explanation
Homeostasis is a fundamental physiological principle that describes how the human body maintains a relatively stable internal environment despite continuous changes in the external environment. This stability is essential for normal cellular function and survival, as enzymes, metabolic processes, and cellular activities operate within narrow optimal ranges. The body achieves homeostasis through coordinated feedback mechanisms involving the nervous and endocrine systems. These regulatory systems continuously monitor and adjust variables such as temperature, blood glucose, pH, and fluid balance.
A. The changing external conditions of the environment: This option describes environmental variability rather than internal regulation. Homeostasis is not about external changes themselves but about the body’s response to those changes. External conditions such as temperature, humidity, or atmospheric pressure may fluctuate, but homeostasis refers specifically to how the internal environment remains stable despite these fluctuations.
B. The maintenance of stable internal conditions: homeostasis refers to the body’s ability to maintain a constant internal environment within narrow physiological limits. This includes regulation of core temperature, blood glucose levels, blood pressure, and electrolyte balance. These processes are controlled through negative feedback mechanisms involving the nervous and endocrine systems. Stability of the internal environment is essential for proper cellular and organ function.
C. The breakdown of nutrients for energy production: This option describes metabolism, specifically catabolism, which involves the chemical breakdown of nutrients to release energy in the form of ATP. While metabolism is essential for life and is regulated in part by homeostatic mechanisms, it is not the definition of homeostasis itself. Therefore, this statement refers to a specific physiological process rather than the overall regulatory balance of the internal environment.
D. The transmission of electrical signals in neurons: This describes neural conduction, which is the process by which neurons transmit electrical impulses through action potentials. It is a key function of the nervous system involved in communication and coordination. However, it does not define the regulation of internal physiological stability.
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