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How are children different than adults

Birth - 12 months 5 - 7 years old 12-14 years old Expecting mothers Grownups

The most obvious difference between an adult and a child is their size: most children weigh less than adults. Infants and children have a greater body surface area to body weight ratio than adults. This ratio is more than two times greater in an infant than in an adult.1 This difference is important when evaluating the safety of chemicals that can be absorbed through the skin. As a result, products and chemicals considered safe for an adult could be harmful for a child: the same exposure by an adult would be significantly higher for a child.

Secondly, less than 50% of the US population is male. If the standard of safety is based on a healthy adult male, it fails to consider the impact on women. Many of the chemicals used today may affect men and women and boys and girls differently. There are entire groups of chemicals that behave like human hormones once they enter the body.

Other critical differences between an adult and a typical child include:

• Children have a significantly higher number of ways to be exposed to chemicals. A fetus in its mother’s womb is exposed to anything to which the mother is exposed, which is why expectant mothers have to be careful about the products they use and the foods they eat. After birth, nursing infants can be exposed through their mother’s breast milk.

• As toddlers, children put anything they can into their mouths. They also play close to the ground where they are more likely to be exposed to various chemicals and chemical residues in the form of dust and dirt. Heavier gases accumulate lower to ground and chemicals applied to lawns and floors are closer to a child.

Other critical differences between an adult and a typical child include:

• Children’s rapidly developing bodies are more susceptible to chemicals from the time of conception through their early twenties. As the brain develops, for example, billions of brain cells are busy arranging and rearranging themselves in precise positions. Anything that interferes with that process may have long-lasting impacts.

• Children generally have longer to live than adults so any exposure to dangerous substances has a longer time to accumulate and cause health problems.

• Children drink more water, eat more food, and breathe more air pound-for-pound than adults.

• Children in the first six months of life drink seven times as much for their size than adults. Children between the ages of one and five eat three-to-four times as much on a bodyweight basis than the average adult. An infant inhales twice as much air for its size than a typical adult.

• Children are less able to remove harmful substances from their bodies than adults because their organs and immune systems are not fully developed. If an organ is damaged during development the damage may be permanent.

“Many organ systems in young children – the nervous system in particular, but also the lungs, the immune system, and the reproductive organs – undergo extensive growth and development throughout pregnancy and in the first months and years of extra-uterine life. During this period, structures are developed and vital connections established. These systems are not well adapted to repair any damage that may be caused by environmental toxicants. Thus, if cells in the developing brain, immune system, or reproductive organs are destroyed by neurotoxicants, or if development is diverted by endocrine disruptors, there is high risk that the resulting dysfunction will be permanent and irreversible. Depending on the organ damaged, the consequences can include loss of intelligence, immune dysfunction, or reproductive impairment.”2
 

1 Prioritization of Toxic Air Contaminants Under Children’s Env. Health Protection Act: California Environmental Protection Agency.

2 Landrigan PJ, JE Carlson, CF Bearer, JS Cranmer, RD Bullard, RA Etzel, J Groopken, JA McLachlan, FP Perera, JR Reigart, L Robison, L Schell, WA Suk. Children’s health and the environment: A new agenda for prevention research. Environmental Health Perspectives 106, Supplement 3, June 1998

Early childhood: One to four years old

Contrary to previous widely held beliefs, the human brain is not fully developed at birth. In fact, a newborn's brain is about 25% of its approximate adult weight. After birth, it grows dramatically by producing billions of cells and hundreds of trillions of connections between these cells. These cells form a complex control centre for sensing the world and enabling the baby not only to see, hear, move, taste and touch but also to think, feel, and behave in particular ways.

Babies are born without the ability to control their head and neck muscles. Muscles begin to develop during the first year of life and the child learns how to coordinate muscle movement.

Muscle development enables the child to learn to roll, sit up and eventually walk. During this stage the child is close to the ground and more susceptible than an adult to hazards at ground level: toxins, pesticides, dirt and other foreign substances.

Eyesight develops during the first year of life and by four months the child’s sight should be able to see as well as an adult.

In the first year of life the child does not comprehend right and wrong. The ability to understand direction improves as the child gets closer to the age of four; however, during this stage, the child is incapable of ascertaining situations that may place them in harm and are incapable to protect themselves.

Reading skills develop at this stage and children are not capable to understand warning labels or safety measures created for adults. Keep all chemicals out of reach of children at all times.

Organs are still growing and developing. Many organs will continue to grow throughout adolescence. This makes these organs susceptible to toxic exposure and can retard the growth of these organs.

Proper nutrition is essential for a child’s growth. A poor diet can affect how much a child weighs and how the child grows. The developing child is vulnerable to toxic exposure and environmental contaminates. Benchmarks for safety regarding environmental hazards do not exist and the level of safety currently used in by the US EPA is for a 170 pound healthy adult. Children should avoid areas where there is smoking, drugs, and areas that may expose the child to higher levels of toxins. At this stage the child is unable to determine right from wrong and is unable to take care of itself.

For more information of developmental milestones: http://www.aap.org/healthtopics/stages.cfm

Resources:  

Adolescence: 11-21 years old

Organs are still growing and developing.  Many organs will continue to grow throughout adolescence.  This makes these organs susceptible to toxic exposure and can retard the growth of these organs. 

Sexual identity and the maturation of sexual organs occur with the offset of puberty.  This results in physiological and psychological changes. 

Experimentation also occurs in this stage and can expose the child to toxic substances from alcohol, tobacco or drugs. 

Proper nutrition is essential for a child’s growth.  A poor diet can affect how much a child weighs and how the child grows.  The developing child is vulnerable to toxic exposure and environmental contaminates.  Benchmarks for safety regarding environmental hazards do not exist and the level of safety currently used in by the US EPA is for a 170 pound healthy adult.  Children should avoid areas where there is smoking, drugs, and areas that may expose the child to higher levels of toxins.   At this stage the child is unable to determine right from wrong and is unable to take care of itself.   

For more information of developmental milestones:
http://www.aap.org/healthtopics/stages.cfm

Resources:  

Pregnancy

  • Week 1 (3rd week of pregnancy)

    • Fertilization of the ovum to form a zygote which undergoes mitotic cellular division, but does not increase in size. A hollow cavity forms marking the blastocyst stage.

    • The blastocyst contains only a thin rim of trophoblast cells and a clump of cells at one end known as the "embryonic pole" which include embryonic stem cells.

    • The blastocyst hatches from its protein shell (zona pellucida) and implants onto the endometrial lining of the mother's uterus.

  • Week 2 (4th week of pregnancy)

    • Trophoblast cells surrounding the embryonic cells proliferate and invade deeper into the uterine lining. They will eventually form the placenta and embryonic membranes.

    • Formation of the yolk sac.

    • The embryonic cells flatten into a disk, two-cells thick.

Embryonic Period

Toxic exposures often cause major congenital malformations

Week 1-4 After conception, the embryo will begin to "search" for a place to attach to the woman's uterus. When it finds one and plants itself there, the connections between the mother and the embryo will begin to form, including the umbilical cord

  • Week 3 (5th week of pregnancy - first missed menstrual period)

    • A notochord forms in the center of the embryonic disk.

    • A neural groove (future spinal cord) forms over the notochord with a brain bulge at one end.

    • Heart tubes begin to fuse.

  • Week 4 (6th week of pregnancy)

    • The embryo measures 4 mm (1/8 inch) in length and begins to curve into a C shape.

    • Somites, the divisions of the future vertebra, form.

    • The heart bulges, further develops, and begins to beat in a regular rhythm.

    • Branchial arches, grooves which will form structures of the face and neck, form.

    • The neural tube closes.

    • The ears begin to form as otic pits.

    • Arm buds and a tail are visible.

  • Week 5 (7th week of pregnancy)

    • The embryo measures 8 mm (1/4 inch) in length.

    • Lens pits and optic cups form the start of the developing eye.

    • A primitive mouth and nasal pits form.

    • The brain divides into 5 vesicles, including the early telencephalon.

    • Leg buds form and hands form as flat paddles on the arms.

    • Rudimentary blood moves through primitive vessels connecting to the yolk sac and chorionic membranes.

Week 5-8 Chemicals produced by the embryo stop the mother's menstrual cycle. The brain begins to develop, and the heart will begin to beat. Stubs begin to be visible where arms and legs will grow later. All the main organs begin to grow. The embryo's blood type becomes apparent. Embryo is capable of motion, and the eyes begin to form. Most organs have developed or have begun developing. At the end of the 8th week, the embryonic stage is over, and the fetal stage begins

In humans, a fetus develops from the end of the 8th week of pregnancy, when the major structures and organ systems have formed, until birth. 

There is much natural variation in the growth of the fetus. Approximately 52% of the variation in birth weight can be accounted for by genetic factors, whereas 48% can be accounted for by environmental factors. Ultimately, the offspring should be able to live up to its term growth potential. Factors affecting fetal growth can be maternal, placental, or fetal.

  • Week 6 (8th week of pregnancy)

    • The embryo measures 13 mm (1/2 inch) in length.

    • Lungs begin to form.

    • The brain continues to develop.

    • Arms and legs have lengthened with foot and hand areas distinguishable.

    • The hands and feet have digits, but may still be webbed.

  • Week 7 (9th week of pregnancy)

    • The embryo measures 18 mm (3/4 inch) in length.

    • Nipples and hair follicles begin to form.

    • Location of the elbows and toes are visible.

    • Spontaneous limb movements may be detected by ultrasound.

    • All essential organs have at least begun formation.

  • Week 8 (10th week of pregnancy)

    • Embryo measures 30 mm (1.2 inches) in length.

    • Intestines rotate.

    • Facial features continue to develop.

    • the eyelids are more developed.

    • the external features of the ear begin to take their final shape.

Fetal Period

During the fetal period, toxic exposures often cause physiological abnormalities or minor congenital malformation

  • Weeks 9 to 12 (11th to 14th week of pregnancy)

    • The fetus reaches a length of 8 cm (3.2 inches).

    • The head comprises nearly half of the fetus' size.

    • The face is well formed and develops a human appearance.

    • The eyelids close and will not reopen until about the 28th week.

    • Tooth buds, which will form the baby teeth, appear.

    • The limbs are long and thin.

    • The fetus can make a fist with its fingers.

    • Genitals appear well differentiated.

    • Red blood cells are produced in the liver.

  • Weeks 13 to 16 (15th to 18th week of pregnancy)

    • The fetus reaches a length of about 15 cm (6 inches).

    • A fine hair called lanugo develops on the head.

    • Fetal skin is almost transparent.

    • More muscle tissue and bones have developed, and the bones become harder.

    • The fetus makes active movements.

    • Sucking motions are made with the mouth.

    • Meconium is made in the intestinal tract.

    • The liver and pancreas produce fluid secretions.

  • Week 18 (20th week of pregnancy)

    • The fetus reaches a length of 20 cm (8 inches).

    • Lanugo covers the entire body.

    • Eyebrows and eyelashes appear.

    • Nails appear on fingers and toes.

    • The fetus is more active with increased muscle development.

    • "Quickening" usually occurs (the mother can feel the fetus moving).

    • The fetal heartbeat can be heard with a stethoscope.

  • Week 22 (24th week of pregnancy)

    • The fetus reaches a length of 28 cm (11.2 inches).

    • The fetus weighs about 725 g (1 lb 10 oz).

    • Eyebrows and eyelashes are well formed.

    • All of the eye components are developed.

    • The fetus has a hand and startle reflex.

    • Footprints and fingerprints continue forming.

    • Alveoli (air sacs) are forming in lungs.

  • Weeks 23 to 26 (25th to 28th week of pregnancy)

    • The fetus reaches a length of 38 cm (15 inches).

    • The fetus weighs about 1.2 kg (2 lb 11 oz).

    • The brain develops rapidly.

    • The nervous system develops enough to control some body functions.

    • The eyelids open and close.

    • The respiratory system, while immature, has developed to the point where gas exchange is possible.

    • A baby born prematurely at this time may survive, but the possibilities for complications and death remain high.

  • Weeks 27 to 31 (29th to 33rd week of pregnancy)

    • The fetus reaches a length of about 38-43 cm (15-17 inches).

    • The fetus weighs about 2 kg (4 lb 6 oz).

    • The amount of body fat rapidly increases.

    • Rhythmic breathing movements occur, but lungs are not fully mature.

    • Thalamic brain connections, which mediate sensory input, form.

    • Bones are fully developed, but are still soft and pliable.

    • The fetus begins storing iron, calcium, and phosphorus.

  • Week 34 (36th week of pregnancy)

    • The fetus reaches a length of about 40-48 cm (16-19 inches).

    • The fetus weighs about 2.5 to 3 kg (5 lb 12 oz to 6 lb 12 oz).

    • Lanugo begins to disappear.

    • Body fat increases.

    • Fingernails reach the end of the fingertips.

    • a baby born at 36 weeks has a high chance of survival, but may require medical interventions.

  • Weeks 35 to 38 (37th to 40th week of pregnancy)

    • The fetus is considered full-term at the 37th week of pregnancy.

    • It may be 48 to 53 cm (19 to 21 inches) in length.

    • The lanugo is gone except on the upper arms and shoulders.

    • Fingernails extend beyond fingertips.

    • Small breast buds are present on both sexes.

    • Head hair is now coarse and thicker

 

The circulatory system of a fetus

The circulatory system of a human fetus works differently from that of born humans, mainly because the lungs are not in use: the fetus obtains oxygen and nutrients from the mother through the placenta and the umbilical cord.

Blood from the placenta is carried by the umbilical vein. About half of this enters the ductus venosus and is carried to the inferior vena cava, while the other half enters the liver proper from the inferior border of the liver. The branch of the umbilical vein that supplies the right lobe of the liver first joins with the portal vein. The blood then moves to the right atrium of the heart. In the fetus, there is an opening between the right and left atrium (the foramen ovale), and most of the blood flows from the right into the left atrium, then into the left ventricle from where it is pumped through the aorta into the body. Some of the blood moves from the aorta through the internal iliac arteries to the umbilical arteries, and re-enters the placenta, where carbon dioxide and other waste products from the fetus are taken up and enter the mother's circulation.

Some of the blood from the right atrium does not enter the left atrium, but enters the right ventricle and is pumped into the pulmonary artery. In the fetus, there is a special connection between the pulmonary artery and the aorta, called the ductus arteriosus, which directs most of this blood away from the lungs (which aren't being used for respiration at this point as the fetus is suspended in amniotic fluid).

Remnants of the fetal circulation can be found in adults.

In addition to differences in circulation, the developing fetus also employs a different type of oxygen transport molecule than adults (adults use adult hemoglobin). Fetal hemoglobin enhances the fetus' ability to draw oxygen from the placenta. Its association curve to oxygen is shifted to the right, meaning that it will take up oxygen at a lower concentration than adult hemoglobin will. This enables fetal hemoglobin to absorb oxygen from adult hemoglobin in the placenta, which has a lower pressure of oxygen than at the lungs.

A human being's heart is about the size of that human being's fist. As the body develops, the heart grows at the same rate as the fist. So an infant's heart and fist are about the same size at birth. In the womb, however, that similarity was not always true. During the first few weeks after conception, the fetal heart occupies most of the fetus' mid-section. The heart size to body size ratio is nine times greater in the fetus than in the infant. During those first few weeks, the fetal heart lies high in the chest. Soon, it moves down to occupy its position in the chest cavity.

Proper nutrition is essential for a baby's growth in the uterus and beyond. A poor diet during pregnancy can affect how much a newborn weighs and how the infant grows.  The developing fetus is vulnerable to toxic exposure and environmental contaminates.  Benchmarks for safety regarding environmental hazards do not exist and the level of safety currently used in by the US EPA is for a 170 pound healthy adult.  Mothers should avoid smoking, areas where there is smoking, consumption of alcohol, drugs, and areas that may expose the mother to higher levels of toxins. 

Resources:  
Pennsylvania Institute for Children's Environmental Health

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