Table of Contents
As soon as the placental circulation stops as a result of severed umbilical cord, the glucose supply to the infant through maternal blood ends. This leads to a fall in blood glucose levels immediately after birth. An infant has a low store of glycogen and insulin and increased glucagon.
Gluconeogenesis, glycogenolysis, lipolysis, and ketogenesis replace the processes of glycogenesis and lipogenesis right after birth. This results in a metabolic switch from glucose to fat. The newborn therefore has a diet initially higher in fats and lower in carbohydrates.
- Mitochondrial density increases as the metabolic rate increases, which occurs after birth.
- A surge in catecholamine and glucagon is observed in infants at birth which aims to maintain blood glucose levels after birth.
- Insulin levels are decreased to prevent hypoglycemia.
- Serum cortisol levels also peak at the time of delivery.
- Renin-angiotensin and vasopressin levels are also elevated after birth.
- There is increased ketone body formation in newborns.
- Increased chances of hypothermia, hypoglycemia, hypoxia, and acidosis
- Relative hepatic maturity is seen near six months after birth.
- Thyroid hormones also show a surge after birth in response to hypothermia and the cold extra-uterine environment.
- The brain of a newborn has a weight of 400 grams.
- By one year of age the weight increases to 1,000 grams.
- By two years, it is 80 percent of the size of the brain of an adult.
- By 18 years of life, an adult brain weighs 1,400 grams.
The process of myelination begins in the 7th month of intrauterine life. Myelination occurs most rapidly in the first two years after birth. The structures that are necessary for reflex behavior are myelinated first. These include:
- Motor-sensory roots
- Special senses
- The brainstem
The pattern for axon myelination also follows the cephalocaudal gradient of growth. The shortest axons of the corticospinal tract are myelinated first. Upper extremities and trunk axons myelinate next. The longest axons that are present in the lower extremities are the last to myelinate. The whole process completes by 24 months of age.
Cerebral hemisphere myelination
The areas that myelinate first in the cerebral hemisphere are:
- Posterior portion of the frontal lobes
- The parietal lobes
- Areas of the occipital lobes
The frontal and temporal lobes myelinate next. The cerebrum is mostly completed regarding myelination by the end of the second year of life. However, certain interconnections of associated cortex continue to myelinate until the second and third decades of life.
The right and the left cerebral hemispheres are myelinated at different rates, the left one is almost entirely developed in early childhood, while the right one continues to grow until 11 years of age. The left hemisphere is the predominant one in earlier stages of life. This explains why children can learn languages with ease.
A newborn comes from a warm intrauterine environment to the cold outer world. Right after birth, infants are wet and naked. They have a large surface area–to–mass ratio which results in radiant heat loss.
Neonates lack the ability to shiver and hence rely upon non-shivering thermogenesis that occurs in brown fat, the adipose tissue. It has a higher concentration of mitochondria that is designed to oxidize fatty acids and generate heat rapidly. Moreover, it has high vascularity, four-to-six times that of white adipose tissue, and high innervation. Norepinephrine release stimulates metabolism for adipose tissue. The subcutaneous adipose tissue decreases with age.
Thermoregulation is a critical physiologic phenomenon influenced by prematurity, illness and environmental conditions. The temperature in newborns increases during the day reaches its maximum by the evening and is low during night time. With growth and development, surface area–to–mass ratio decreases and therefore there is a decreased heat loss in cold environment and vice versa.
There are the following circadian temperature variations:
- Low nightly temperature for 1 to 3 months
- Rhythm with a lower degree of magnitude for 3 to 6 months
- Adult rhythm is achieved in 2-to-5 years of life
The average sleeping time decreases with age. Neonates spend 16-17 hours per day sleeping. They can enter the REM stage of sleep cycle immediately upon falling asleep, and more than 50 percent of the sleep is REM contrary to less than 25 percent in adults. They can sleep for a duration of 4 hours at one time. Four- to five-month infants can sleep 8-to-10 hours at a time. By the age of 1 year, REM sleep drops to 40 percent.
For a child who is 2-to-5 years of age, average sleep during the day drops to 10-12 hours. It is at this age that the child begins to acquire adult sleeping patterns though they face higher arousal rates when compared to adults. REM sleep drops to 25 percent, as seen in adults. By this age, they have gained a sleep cycle of 90 to 110 minutes.
After birth, the newborn goes through various circulatory changes and changes in oxygenation. The increased oxygenation of the extra-uterine environment results in decreased erythropoietin production and subsequent decrease in erythropoiesis in the first month of life. This influences the hematopoiesis. Given below are the normal hemoglobin and hematocrit values:
- Newborn: 16.5 g/dl, Hct 50 %
- Early childhood: 12g/dl, Hct 36 %
- Late childhood: 13 g/dl, Hct 37—38 %
- Males: 14—18 g/dl, Hct 40—54 %
- Females: 12—16 g/dl Hct 37—47 %
Fetal hemoglobin is the main protein for oxygen transportation until 6 months of life. It has a greater affinity for oxygen binding, hence different from adult hemoglobin, giving the newborn an adequate supply of oxygen. The amount of fetal hemoglobin decreases with age. It is up to 85% of the total hemoglobin at birth and reduces to 2% of the total hemoglobin after 2 years of age.
- Newborns: 20—157 g/dl
- 6 weeks–3 years: 20—115g/dl
- 3–9 years: 20—141 g/dl
- 9–14 years: 21—151 g/dl
- 14–16 years: 20—181 g/dl
- Adults: 44—196 g/dl
The newborn acquires passive immunity from the mother. Immune factors produce IgG early and IgA, IgD, and IgE later in life. IgM is produced at birth. The table below shows the different values of immunoglobulins at various ages.
|Age||IgG mg/dl||IgA mg/dl||IgM mg/dl|
There is a redistribution of workload between the right ventricle and the left ventricle after birth. These changes produce a change in cardiac output. The right ventricle ejects blood against a lower afterload, while the left ventricle has to eject blood against a high afterload. This results in left ventricular hypertrophy, mainly because of a faster rate of cell replication in the left myocardium.
Left ventricular dominance can be seen in the first 3—6 months of life. Both left and right ventricles, however, are equal in size by the age of 6—10 months. By 7 years, the left ventricle is once again larger than the right one. This is the adult relation. There is increased P wave duration, RR interval and QRS duration on an ECG. These changes disappear by the age of 6 and after that, the ECG is similar to that of an adult.
Heart size doubles by the age of 1 year. There is a 4-fold increase by the age of 5 and a 6-fold increase by 9 years of age. This rapid change in size is associated with changes in height and weight. Pulse rate decreases and the range becomes narrower with age. Blood pressure increases with age. It reaches the plateau by 17 years in females and 20 years in males.
|Heart rate||145 bpm||72 bpm|
|Stroke volume||9 ml/beat||70 ml/beat|
|Cardiac output||1.3 L/min||5.0 L/min|
Potential obstructive issues and potential restrictive issues
Lung volume values in infants are usually lower than in adults.
|Tidal volume||6 ml/kg||6 ml/kg|
|Residual volume||23 ml/kg||16 ml/kg|
|Total lung capacity||63 ml/kg||86 ml/kg|
|Functional residual capacity||30 ml/kg||34 ml/kg|
|Vital capacity||35 ml/kg||70 ml/kg|
- Oxygen consumption in infants is 6—8 ml/kg/min which is higher than the 3—4 ml/kg/min in adults.
- Respiratory rate in infants is 35 bpm, and in adults, it is 15 bpm.
- Closing volume is higher in infants and decreases with age.
- Lower diffusing capacity of the lungs for carbon monoxide (DLCO)
- Pulmonary function test cannot be performed before 4 years of age. Asthma and other obstructive disorders are therefore difficult to diagnose.
- Alveoli number increases rapidly in the first 18 months, and the functional development continues until the first decade of life.
- There are potential obstructive and restrictive issues in newborns.
- There is a low amount of collagen in the lung matrix of a neonate. The elastin–to–collagen ratio increases with age. Over 6 years of age, lung recoil increases.
- Compliance of lungs increases to 150 % during the first year of life.
- Chest wall compliance decreases with age.
- Rib’s orientation in infants is horizontal and changes to a downward direction by the age of 10.
GFR at birth is low, rapidly rises over the first few weeks, and by the age of 2, it reaches adult levels. Intravascular resistance at birth is low along with systemic blood pressure. This reduces kidney perfusion. 15—20 % of the cardiac output goes to the infant’s kidney, in contrast to 25 % in adults.
- GFR in neonates: 20 ml/min/1.73 m2 with low urine concentration ability of 450 mOms
- GFR in infants: 35—45 ml/min/1.73 m2 with low urine concentration ability of 600—700 mOms
- GFR in children 2 years of age: 90—110 ml/min/1.73 m2
Acid-base balance and other substances
Up to 2 years, potassium excretion, reabsorption of bicarbonate and H-ion buffer capacity is low. This capability increases with age. Bicarbonate levels in neonates are 18—20 mEq/L while adults have 24—26 mEq/L bicarbonate. The adult level is reached within the first year of life. Fractional excretion of sodium (FENa) is as high as 5 % immediately after birth, contrary to 1 % in the adult.
Kidney maturation occurs rapidly in the first 6 months and is slower after that. Despite that it reaches adult maturation level in 2 years, children are more prone to injuries due to lower adaptation capacities.
Serum creatinine is an index of renal function in neonates and children. Its concentration is highest at birth with a rapid drop in the first 2 weeks. It stabilizes at 0.3—0.4 mg/dl in infancy. Little changes occur in the first 2 years of life, and after that, the serum creatinine level increases with increased muscle mass.