A 10-day-old male infant is brought to the emergency room for abdominal distension for the past day. His mother reports that he has been refusing feeds for about 1 day and appears more lethargic than usual. While changing his diaper today, she noticed that the baby felt warm. He has about 1-2 wet diapers a day and has 1-2 seedy stools a day. The mother reports an uncomplicated vaginal delivery. His past medical history is significant for moderate respiratory distress following birth that has since resolved. His temperature is 101°F (38.3°C), blood pressure is 98/69 mmHg, pulse is 174/min, respirations are 47/min, and oxygen saturation is 99% on room air. A physical examination demonstrates a baby in moderate distress with abdominal distension. What is the best initial step in the management of this patient?

Start IV fluids and antibiotics

An infant boy of unknown age and medical history is dropped off in the emergency department. The infant appears lethargic and has a large protruding tongue. Although the infant exhibits signs of neglect, he is in no apparent distress. The heart rate is 70/min, the respiratory rate is 30/min, and the temperature is 35.7°C (96.2°F). Which of the following is the most likely cause of the patient’s physical exam findings?

Congenital agenesis of an endocrine gland in the anterior neck

Autosomal dominant mutation in the SERPING1 gene

Genetic imprinting disorder affecting chromosome 11p15.5

Type I hypersensitivity reaction

Excess growth hormone secondary to pituitary gland tumor

Two days after delivery, a 4300-g (9-lb 8-oz) newborn has difficulty feeding and has become increasingly lethargic. His cry has become weak. He was born at term. His mother has a history of intravenous drug use. His temperature is 36.4°C (96.5°F), pulse is 170/min, respirations are 62/min, and blood pressure is 70/48 mm Hg. Examination shows midfacial hypoplasia, diaphoresis, and tremor of the lower extremities. Macroglossia is present. There are folds in the posterior auricular cartilage. The left lower extremity is larger than the right lower extremity. Abdominal examination shows an umbilical hernia. The liver is palpated 4 cm below the right costal margin. Neurological examination shows decreased tone in all extremities. Which of the following is the most appropriate intervention?

Administer ampicillin and gentamicin

A 42-year-old man undergoes therapeutic hypothermia (target temperature 33°C/91.4°F) following cardiac arrest with return of spontaneous circulation. During the cooling phase, he develops shivering, which increases oxygen consumption and interferes with target temperature achievement. He is already on sedation and neuromuscular blockade is being considered. Evaluate the most appropriate management strategy considering both efficacy and safety.

Increase sedation and add surface counter-warming of extremities before neuromuscular blockade

Administer meperidine alone to reduce shivering threshold

Abandon therapeutic hypothermia due to complications

Use only mechanical restraints to prevent movement

Immediate neuromuscular blockade without additional measures

A 72-year-old woman with end-stage renal disease on hemodialysis develops fever (103°F/39.4°C) with rigors during dialysis. Blood cultures from both the dialysis catheter and peripheral site grow gram-positive cocci. Despite appropriate antibiotics and catheter removal, she has persistent fevers of 101-102°F (38.3-38.9°C) for 7 days. She feels better and inflammatory markers are decreasing. Evaluate the most likely explanation for persistent fever.

Appropriate lag in temperature resolution despite adequate treatment

Undrained abscess requiring surgical intervention

Drug fever from antibiotic therapy

Inadequate dialysis causing uremic fever

Antibiotic-resistant organism requiring regimen change

Temperature regulation in neonates for USMLE Step 1: High-Yield Physiology Lessons

Neonatal Vulnerability - Why They're Chilly

Heat loss mechanisms in neonates

Neonates are prone to hypothermia due to several key factors:

High Surface Area-to-Volume Ratio: Leads to ↑ heat loss to the environment.
↓ Subcutaneous Fat & Thin Skin: Provides poor insulation.
Limited Voluntary Muscle Activity: Cannot generate heat via shivering.
Immature Vasomotor Control: Inefficient at conserving heat through vasoconstriction.

⭐ A term infant has ~3x the surface area to body mass ratio of an adult, significantly increasing their risk of cold stress.

Heat Production - Brown Fat to the Rescue

Neonates primarily use non-shivering thermogenesis (NST) to produce heat, as they cannot effectively shiver.
This process occurs in Brown Adipose Tissue (BAT), which is densely packed with specialized mitochondria.
Mechanism: The sympathetic nervous system releases norepinephrine, activating uncoupling protein 1 (UCP1/thermogenin) in BAT mitochondria. UCP1 creates a proton leak, uncoupling the electron transport chain from ATP synthesis and releasing energy directly as heat.

⭐ BAT is prominent around the scapulae, kidneys, and adrenal glands in neonates.

📌 Brown Adipose Tissue Burns Awfully Toasty!

Mechanisms of Heat Loss - The Great Escape

Radiation: Transfer of heat to cooler objects not in direct contact.
- Clinical Example: An infant's crib placed near a cold outside wall or window.
Convection: Loss of heat from the infant's skin to moving air currents.
- Clinical Example: Drafts from open doors, windows, or air conditioning vents.
Conduction: Direct transfer of heat to a cooler surface in contact with the infant.
- Clinical Example: Placing a neonate on a cold weighing scale or using a cold stethoscope.
Evaporation: Heat loss as surface liquid converts to vapor.
- Clinical Example: A wet infant immediately after birth or during a bath.

⭐ Evaporation is the most significant source of heat loss immediately after birth.

Four mechanisms of neonatal heat loss

Cold Stress - The Downward Spiral

When a neonate's temperature drops, a cascade of physiological events occurs to generate heat, often with dangerous consequences.

Metabolic: ↑ Glucose use leads to profound hypoglycemia. Anaerobic metabolism results in metabolic acidosis.
Respiratory: ↑ O₂ demand can cause respiratory distress. Hypoxia and acidosis trigger pulmonary vasoconstriction, impairing surfactant production and worsening the distress.

⭐ Exam Favourite: Cold stress can displace bilirubin from albumin, increasing the risk of kernicterus even at lower total bilirubin levels.

High‑Yield Points - ⚡ Biggest Takeaways

Neonates have a high surface area-to-volume ratio, leading to rapid heat loss.

Non-shivering thermogenesis in brown adipose tissue (BAT) is the primary mechanism for heat production.

This process is mediated by thermogenin (UCP1), which uncouples oxidative phosphorylation.

Infants have limited shivering capacity and less insulating subcutaneous fat.

Cold stress can rapidly cause hypoglycemia, metabolic acidosis, and respiratory distress.

Kangaroo care (skin-to-skin) and swaddling are key to prevent hypothermia.

Continue reading on Oncourse

CONTINUE READING — FREE

or get the app

App Store|Google Play