Anatomy
3 questionsWhich thalamic nuclei can produce basal ganglia symptoms?
Which of the following is a cerebellar nucleus?
What is the approximate number of cones in the human retina?
NEET-PG 2013 - Anatomy NEET-PG Practice Questions and MCQs
Question 211: Which thalamic nuclei can produce basal ganglia symptoms?
- A. Lateral dorsal
- B. Pulvinar
- C. Ventral anterior (Correct Answer)
- D. Intralaminar
Explanation: ***Ventral anterior*** - The **ventral anterior (VA)** and **ventral lateral (VL)** nuclei of the thalamus receive significant input from the **basal ganglia** and project to the motor cortex [1]. - Dysfunction in these nuclei can disrupt the basal ganglia's influence on motor control, leading to symptoms like **dyskinesia** or **rigidity** [1]. *Lateral dorsal* - The **lateral dorsal nucleus** is primarily involved in **limbic system** functions and episodic memory. - It does not have direct nor significant connections with the basal ganglia motor circuits that would produce typical basal ganglia symptoms. *Pulvinar* - The **pulvinar** is the largest thalamic nucleus, primarily involved in **visual processing**, attention, and eye movements. - While it has extensive cortical connections, it is not directly involved in the motor circuits of the basal ganglia. *Intralaminar* - The **intralaminar nuclei** (e.g., centromedian and parafascicular) receive input from the basal ganglia but primarily project diffusely to the cerebral cortex and are involved in **arousal** and consciousness [2]. - While they modulate cortical activity, their dysfunction typically wouldn't produce the classic motor symptoms associated with basal ganglia disorders.
Question 212: Which of the following is a cerebellar nucleus?
- A. Putamen
- B. Caudate nucleus
- C. Subthalamic nucleus
- D. Fastigial nucleus (Correct Answer)
Explanation: ***Fastigial nucleus*** - The **fastigial nucleus** is one of the four principal deep cerebellar nuclei, involved in regulating **balance** and **posture** [2]. - The deep cerebellar nuclei are crucial for the cerebellum's output, relaying processed information to other brain regions [2]. *Caudate nucleus* - The **caudate nucleus** is part of the **basal ganglia**, a group of subcortical nuclei in the forebrain [1]. - It plays a significant role in **motor control**, learning, memory, and reward processing. *Subthalamic nucleus* - The **subthalamic nucleus** is a small nucleus located in the **diencephalon**, below the thalamus and above the substantia nigra [1]. - It is also part of the **basal ganglia system** and is critical for modulating motor control [1]. *Putamen* - The **putamen** is another structure belonging to the **basal ganglia**, located in the forebrain [1]. - It is primarily involved in regulating various types of **motor behavior** and learning.
Question 213: What is the approximate number of cones in the human retina?
- A. Approximately 3-5 million cones (Correct Answer)
- B. Approximately 25-50 million cones
- C. Approximately 50-100 million cones
- D. Approximately 10-20 million cones
Explanation: Approximately 3-5 million cones - The human retina contains roughly **4.5 million cones**, concentrated in the **fovea**, which is responsible for **high-acuity vision** and color perception [1]. - Cones are light-sensitive cells that detect **fine details** and are essential for vision in **bright light conditions** [1]. *Approximately 10-20 million cones* - This range is significantly higher than the actual number of cones found in the human retina. - While there are millions of photoreceptors, the *majority are rods*, not cones [1]. *Approximately 25-50 million cones* - This figure vastly *overestimates* the number of cones in the human eye. - The total number of photoreceptor cells (rods and cones combined) in the retina typically ranges from **100-125 million** [1]. *Approximately 50-100 million cones* - This range is incorrect as it refers more closely to the *total number of rods* in the human retina, which is about **90-120 million** [1]. - Cones constitute a much smaller proportion of the total photoreceptor population [1].
Pathology
2 questionsWhich of the following statements is false regarding hereditary spherocytosis?
Donath-Landsteiner antibody is seen in?
NEET-PG 2013 - Pathology NEET-PG Practice Questions and MCQs
Question 211: Which of the following statements is false regarding hereditary spherocytosis?
- A. Defect in ankyrin
- B. Reticulocytosis
- C. Decreased MCHC (Correct Answer)
- D. Normal to increased MCV
Explanation: ***Decreased MCHC*** - Hereditary spherocytosis typically presents with an **increased MCHC** due to the spherocytes being more concentrated. - MCHC is a measure of the hemoglobin concentration in red blood cells, and in spherocytosis, this value is often elevated rather than decreased. *Defect in ankyrin* - This is a true statement; hereditary spherocytosis is associated with a defect in **ankyrin**, a protein that helps maintain the cell's membrane structure [2]. - Mutations in ankyrin lead to instability of the red blood cell membrane, resulting in spherocyte formation [2]. *Decreased MCV* - In hereditary spherocytosis, MCV is often **normal or slightly increased**, as it reflects the volume of red blood cells, which can be misinterpreted due to the presence of spherocytes. - Spherocytes are smaller cells, which can mistakenly suggest a falsely decreased MCV if not properly interpreted [1]. *Reticulocytosis* - This condition typically presents with **reticulocytosis** as a response to hemolysis, indicating the bone marrow is producing more red blood cells to compensate [1]. - The presence of reticulocytosis is a common finding in hereditary spherocytosis due to increased destruction of spherocytes. **References:** [1] Cross SS. Underwood's Pathology: A Clinical Approach. 6th ed. Common Clinical Problems From Blood And Bone Marrow Disease, pp. 597-598. [2] Kumar V, Abbas AK, et al.. Robbins and Cotran Pathologic Basis of Disease. 9th ed. Red Blood Cell and Bleeding Disorders, pp. 640-641.
Question 212: Donath-Landsteiner antibody is seen in?
- A. PNH
- B. Waldenstrom's macroglobulinemia
- C. Malaria
- D. Paroxysmal cold hemoglobinuria (Correct Answer)
Explanation: ***Paroxysmal cold hemoglobinuria*** - **Donath-Landsteiner antibody** is a **biphasic IgG autoantibody** that binds to red blood cells in the cold and causes **hemolysis** upon warming, characteristic of paroxysmal cold hemoglobinuria. - This antibody has **anti-P specificity**, meaning it targets the P antigen on red blood cells, leading to complement activation and cell lysis. *PNH* - **Paroxysmal nocturnal hemoglobinuria** (PNH) is characterized by a deficiency in **GPI-anchored proteins** on red blood cells, notably **CD55** and **CD59**, making them susceptible to complement-mediated lysis. - It is not associated with the Donath-Landsteiner antibody; rather, it is identified by **flow cytometry** showing absence of CD55/CD59. *Waldenstrom's macroglobulinemia* - This is a **B-cell lymphoma** characterized by the overproduction of **monoclonal IgM antibodies**, leading to hyperviscosity syndrome and other symptoms. - It does not involve Donath-Landsteiner antibodies or cold-induced hemolysis in the same manner as paroxysmal cold hemoglobinuria. *Malaria* - **Malaria** is caused by **Plasmodium parasites** that infect and destroy red blood cells, leading to hemolytic anemia and fever. - While it causes **hemolysis**, it is not mediated by the Donath-Landsteiner antibody; the destruction is primarily due to parasitic replication and immune responses against infected cells.
Pediatrics
2 questionsAt what age does the tonic neck reflex typically disappear?
What is the significance of the persistence of the asymmetric tonic neck reflex in a 9-month-old infant?
NEET-PG 2013 - Pediatrics NEET-PG Practice Questions and MCQs
Question 211: At what age does the tonic neck reflex typically disappear?
- A. 1 month
- B. 2 months
- C. 3 months
- D. 4 months (Correct Answer)
Explanation: ***Correct Answer: 4 months*** - The **tonic neck reflex**, also known as the **asymmetrical tonic neck reflex (ATNR)**, typically disappears around **4 to 6 months of age**. - Persistence beyond this age can be a sign of **neurological dysfunction** and may interfere with motor development such as rolling or bringing hands to midline. *Incorrect: 1 month* - While the tonic neck reflex is present at 1 month, it does not typically disappear at this early stage. - At 1 month, infants are still relying on a variety of **primitive reflexes** for survival and early motor patterns. *Incorrect: 2 months* - The tonic neck reflex is still usually clearly present at 2 months of age. - This reflex contributes to early **eye-hand coordination** and helps develop unilateral body movements. *Incorrect: 3 months* - While starting to integrate, the tonic neck reflex is not fully integrated or gone by 3 months. - Its presence is normal at this age, and its integration is a gradual process as **voluntary motor control** emerges.
Question 212: What is the significance of the persistence of the asymmetric tonic neck reflex in a 9-month-old infant?
- A. Decreased muscle tone
- B. Increased muscle tone (Correct Answer)
- C. Normal phenomenon
- D. None of the options
Explanation: ***Increased muscle tone*** - The **asymmetric tonic neck reflex (ATNR)** should integrate by **6 months of age**, and its persistence beyond this period is a sign of **neurological dysfunction**. - Persistent primitive reflexes, including ATNR, are often associated with **upper motor neuron lesions** and can manifest as increased muscle tone or **spasticity**. *Decreased muscle tone* - **Decreased muscle tone**, or **hypotonia**, is typically associated with **lower motor neuron lesions** or certain genetic conditions, not the persistence of primitive reflexes. - While some neurological conditions can cause hypotonia, persistent ATNR is a hallmark of problems leading to **hypertonia**. *Normal phenomenon* - The persistence of the ATNR beyond **6 months of age** is considered abnormal and indicates a potential developmental delay or neurological issue. - In a **9-month-old**, the reflex should have fully integrated, and its presence warrants further investigation. *None of the options* - As the persistence of the ATNR is indeed a significant finding, associated with increased muscle tone, this option is incorrect.
Physiology
3 questionsWhich of the following is classified as a pain receptor?
What is the normal cerebral blood flow in milliliters per minute for a healthy adult?
Cell bodies of orexigenic neurons are present in?
NEET-PG 2013 - Physiology NEET-PG Practice Questions and MCQs
Question 211: Which of the following is classified as a pain receptor?
- A. Free nerve endings (Correct Answer)
- B. Meissner's corpuscle
- C. Pacinian corpuscle
- D. Merkel disc
Explanation: ***Free nerve endings*** - **Free nerve endings** are the most common type of sensory receptor in the skin and are responsible for detecting **pain**, temperature, and crude touch. - They lack specialized structures and are found throughout the epidermis and dermis. *Meissner's corpuscle* - **Meissner's corpuscles** are encapsulated nerve endings that detect **light touch** and **vibration**. - They are rapidly adapting and are abundant in sensitive, hairless skin areas like fingertips and lips. *Pacinian corpuscle* - **Pacinian corpuscles** are large, encapsulated receptors that detect **deep pressure** and **vibration**. - They are rapidly adapting and respond to high-frequency stimuli. *Merkel disc* - **Merkel discs** are specialized epithelial cells associated with nerve endings that detect **sustained pressure** and **texture**. - They are slowly adapting receptors crucial for tactile discrimination.
Question 212: What is the normal cerebral blood flow in milliliters per minute for a healthy adult?
- A. 55 ml/min
- B. 150 ml/min
- C. 750 ml/min (Correct Answer)
- D. 1000 ml/min
Explanation: ***750 ml/min*** - The brain receives approximately **15% of the cardiac output**, which for an average adult with a cardiac output of 5 L/min (5000 ml/min) translates to about **750 ml/min**. - This flow rate is essential to meet the high metabolic demands of the brain, which consumes about **20% of the body's total oxygen**. - For reference, this corresponds to approximately **50-55 ml/100g/min** when normalized to brain tissue weight. *55 ml/min* - This value represents the **cerebral blood flow per 100 grams of brain tissue** (50-55 ml/100g/min), not the **total cerebral blood flow**. - As a total flow value, 55 ml/min would be severely **inadequate** for the entire brain (~1400g) and would lead to immediate **ischemia** and neurological dysfunction. *150 ml/min* - While higher than 55 ml/min, this rate is still **grossly insufficient** to maintain the metabolic needs of the entire adult brain. - Such a low total flow would result in widespread **cerebral hypoperfusion** and severe neurological deficits. *1000 ml/min* - Although the brain has significant blood flow, 1000 ml/min is generally **higher than the normal average** for a healthy adult at rest. - The normal range is typically **750-800 ml/min**; sustained flow at 1000 ml/min might be seen in hyperemia or certain physiological states but is not the typical baseline.
Question 213: Cell bodies of orexigenic neurons are present in?
- A. Dorsal raphe
- B. Locus coeruleus
- C. Lateral hypothalamic area (Correct Answer)
- D. Hippocampus
Explanation: ***Lateral hypothalamic area*** - The **lateral hypothalamic area** (LHA) contains neurons that produce **orexin (hypocretin)**, a neuropeptide critical for promoting appetite and wakefulness. - Stimulation of the LHA leads to increased food seeking and consumption, earning it the moniker "**feeding center**." *Dorsal raphe* - The **dorsal raphe nucleus** is a key source of **serotonin** in the brain, involved in mood, sleep-wake cycles, and appetite regulation (often promoting satiety). - It does not primarily house orexigenic neurons that directly stimulate appetite. *Locus coerulus* - The **locus coeruleus** is the primary source of **norepinephrine** in the brain, playing a significant role in arousal, attention, and stress response. - While it modulates appetitive behaviors indirectly, its neurons are not the primary orexigenic cell bodies. *Hippocampus* - The **hippocampus** is crucial for **learning, memory formation**, and spatial navigation. - It is not directly involved in the primary neural circuits that control hunger and satiety through orexigenic neuropeptides.