Neural tube defect

Neural tube defects are a group of birth defects in which an opening in the spine or cranium remains from early in human development. In the third week of pregnancy called gastrulation, specialized cells on the dorsal side of the embryo begin to change shape and form the neural tube. When the neural tube does not close completely, an NTD develops.
Specific types include: spina bifida which affects the spine, anencephaly which results in little to no brain, encephalocele which affects the skull, and iniencephaly which results in severe neck problems.
NTDs are one of the most common birth defects, affecting over 300,000 births each year worldwide. For example, spina bifida affects approximately 1,500 births annually in the United States, or about 3.5 in every 10,000, which has decreased from around 5 per 10,000 since [|folate fortification] of grain products was started. The number of deaths in the US each year due to neural tube defects also declined from 1,200 before folate fortification was started to 840.

Types

There are two classes of NTDs: open, which are more common, and closed. Open NTDs occur when the brain and/or spinal cord are exposed at birth through a defect in the skull or vertebrae. Open NTDs include anencephaly, encephaloceles, hydranencephaly, iniencephaly, schizencephaly, and the most common form, spina bifida. Closed NTDs occur when the spinal defect is covered by skin. Types of closed NTDs include lipomeningocele, lipomyelomeningocele, and tethered cord.

Anencephaly

is a severe neural tube defect that occurs when the anterior-most end of the neural tube fails to close, usually during the 23rd and 26th days of pregnancy. This results in an absence of a major portion of the brain and skull. Infants born with this condition lack the main part of the forebrain and are usually blind, deaf and display major craniofacial anomalies. The lack of a functioning cerebrum will prevent the infant from even gaining consciousness. Infants are either stillborn or usually die within a few hours or days after birth. For example, anencephaly in humans can result from mutations in the NUAK2 kinase.

Encephaloceles

s are characterized by protrusions of the brain through the skull that are sac-like and covered with membrane. They can be a groove down the middle of the upper part of the skull, between the forehead and nose, or the back of the skull. Due to the range in its location, encephaloceles are classified by the location as well as the type of defect it causes. Subtypes include occipital encephalocele, encephalocele of the cranial vault, and nasal encephaloceles, with approximately 80% of all encephaloceles occurring in the occipital area. Encephaloceles are often obvious and diagnosed immediately. Sometimes small encephaloceles in the nasal and forehead are undetected. Despite the wide range in its implications, encephaloceles are most likely to be caused by improper separation of the surface ectoderm and the neuroectoderm after the closure of the neural folds in the fourth week of gastrulation.

Hydranencephaly

is a condition in which the cerebral hemispheres are missing and instead filled with sacs of cerebrospinal fluid. People are born with hydranencephaly, but most of the time, the symptoms appear in a later stage. Newborns with hydrancephaly can swallow, cry, sleep and their head is in proportion to their body. However, after a few weeks, the infants develop increased muscle tone and irritability. After a few months, the brain start to fill with cerebrospinal fluid. This has several consequences. Infants start to develop problems with seeing, hearing, growing, and learning. The missing parts of the brain and the amount of cerebrospinal fluid can also lead to seizures, spasm, problems with regulating their body temperature, and breathing and digestion problems. Besides problems in the brain, hydranencephaly can also be seen on the outside of the body. Hydrocephalus leads to more cerebrospinal fluid in the brain, which can result in an enlarged head.
The cause of hydranencephaly is not clear. Hydranencephaly is a result of an injury of the nervous system or an abnormal development of the nervous system. The neural tube closes in the sixth week of the pregnancy, so hydranencephaly develops during these weeks of the pregnancy. The cause of these injuries/development is not clear.
Theories regarding the causes of hydrancephaly include:

blockage in the carotid artery: some researchers think that a blockage of the carotid artery leads to the under-/no development of the brain.
inherited condition.
infections: during the pregnancy, a woman can develop an infection in the uterus what can lead to problems with the neural tube.
environmental toxins: during the pregnancy, a woman can be exposed to environmental toxins that may have effect on the health of the infant.
Iniencephaly

is a rare neural tube defect that results in extreme bending of the head to the spine. The diagnosis can usually be made on antenatal ultrasound scanning, but if not will undoubtedly be made immediately after birth because the head is bent backwards and the face looks upwards. Usually the neck is absent. The skin of the face connects directly to the chest and the scalp connects to the upper back. Individuals with iniencephaly generally die within a few hours after birth.

Spina bifida

is further divided into two subclasses, spina bifida cystica and spina bifida occulta.

Spina bifida cystica includes meningocele and myelomeningocele. Meningocele is less severe and is characterized by herniation of the meninges, but not the spinal cord, through the opening in the spinal canal. Myelomeningocele involves herniation of the meninges as well as the spinal cord through the opening.
Spina bifida occulta means hidden split spine. In this type of neural tube defect, the meninges do not herniate through the opening in the spinal canal. The most frequently seen form of spina bifida occulta is when parts of the bones of the spine, called the spinous process, and the neural arch appear abnormal on a radiogram, without involvement of the spinal cord and spinal nerves. The risk of recurrence in those who have a first degree relative is 5–10 times greater compared to the general population.
Causes

Folate deficiency

Inadequate levels of folate and vitamin B₁₂ during pregnancy have been found to lead to increased risk of NTDs. Although both are part of the same biopathway, folate deficiency is much more common and therefore more of a concern. Folate is required for the production and maintenance of new cells, for DNA synthesis and RNA synthesis. Folate is needed to carry one carbon groups for methylation and nucleic acid synthesis. It has been hypothesized that the early human embryo may be particularly vulnerable to folate deficiency due to differences of the functional enzymes in this pathway during embryogenesis combined with high demand for post translational methylations of the cytoskeleton in neural cells during neural tube closure. Failure of post-translational methylation of the cytoskeleton, required for differentiation has been implicated in neural tube defects. Vitamin B₁₂ is also an important receptor in the folate biopathway such that studies have shown deficiency in vitamin B₁₂ contributes to risk of NTDs as well. There is substantial evidence that direct folic supplementation increases blood serum levels of bioavailable folate even though at least one study have shown slow and variable activity of dihydrofolate reductase in human liver. A diet rich in natural folate can show as much increase in plasma folate as taking low levels of folic acid in individuals However a comparison of general population outcomes across many countries with different approaches to increasing folate consumption has found that only general food fortification with folic acid reduces neural tube defects. While there have been concerns about folic acid supplementation being linked to an increased risk for cancer, a systematic review in 2012 shows there is no evidence except in the case of prostate cancer which indicates a modest reduction in risk.
Choline, closely linked to folate metabolism, is essential for fetal development and is tenfold enriched in amniotic fluid compared to maternal serum levels. Its deficiency is strongly associated with NTDs, possibly due to hypomethylation in fetal progenitor cells or impaired acetylcholine synthesis, which may regulate neuronal growth and differentiation. Studies in mice show that perinatal choline supplementation reduces neurodevelopmental abnormalities and improves memory, spatial skills, and exploratory behavior in offspring.
There have been studies showing the relationship between NTDs, folate deficiency and the difference of skin pigmentation within human populations across different latitudes. There are many factors that would influence the folate levels in human bodies: the direct dietary intake of folic acid through fortified products, environmental agents such as UV radiation. In concern with the latter, the UV radiation-induced folate photolysis has been shown via in vitro and in vivo studies to decrease the folate level and implicate in etiology of NTDs not only in humans but other amphibian species. Therefore, a protection against the UV radiation-induced photolysis of folate is imperative for the evolution of human populations living in tropical regions where the exposure to UV radiation is high over the year. One body natural adaptation is to elevate the concentration of melanin inside the skin. Melanin works as either an optical filter to disperse the incoming UV radiation rays or free radical to stabilize the hazardous photochemical products. Multiple studies have demonstrated the highly melanized integument as a defense against folate photolysis in Native Americans or African Americans correlates with lower occurrence of NTDs in general.