Which of the following structures in the brain forms part of the blood-brain barrier

Author: Lorenzo Crumbie MBBS, BSc • Reviewer: Jerome Goffin
Last reviewed: June 28, 2022
Reading time: 15 minutes

Inhaltsverzeichnis Show

Blood–brain barrier structure
Blood–nerve barrier
Blood–cerebrospinal fluid barrier
Circumventricular organs
Secretory organs
Sensory organs
Clinical points
Kernicterus
Blood–brain barrier disruption
Which of the following structures in the brain forms parts of the blood
Which of the following structures forms the blood
What is associated with blood
What is the blood

The brain is the epicentre of an eclectic array of physiological activity. It integrates information from the external environment with signals from the internal environment in order to execute specific activities.

With all the special activities that occur at the neuronal level, it is paramount that the chemical environment in which these cells operate is strictly regulated. This is the primary function of the blood-brain barrier.

This article will look at the overall structure of the blood-brain, blood-nerve, and blood-cerebrospinal fluid barriers found throughout the nervous system. Additionally, special attention will be paid to those areas within the brain that lack a blood-brain barrier and to clinically relevant points with respect to this membrane.

Blood–brain barriers

Definition

Blood-Brain Barrier (BBB) is a selectively permeable membrane regulates the passage of a multitude of large and small molecules into the microenvironment of the neurons. It achieves this feat by with the aid of multiple cellular transport channels scattered along the membrane. These include:

amino acid transporters
glucose transporter 1 (GLUT1)
nucleouside & nucleotide transporters
monocarboxylate transporters (MCT1 and MCT2)
ion transporters (Na+/K+-ATPase pumps) that facilitate the transport of essential molecules into the brain.

In addition to facilitating the uptake of amino acids, the amino acid transporters may inadvertently transport undesirable heavy metals into the brain’s immediate environment. Consequently, at high enough concentrations, this will result in neurotoxicity. GLUT1 and the MCT transporters carry glucose, and lactate and ketones, respectively.

Blood–brain barrier structure

The brain has a large network of arterial and venous vessels taking blood to and from (respectively) brain tissue. However, most of the action occurs at the level of the capillaries. Both the luminal and abluminal (outer surface of the vessel) sides are lined by key structures that contribute to the integrity of the cells. Firstly, squamous epithelial cells form the endothelial wall of the capillaries; the luminal surface of these cells comes into contact with circulating blood and its constituents. The abluminal surface is in contact with a circumferentially continuous basement membrane.

Squamous epithelium and basement membrane (simple squamous epithelium in green)

The endothelial cells are anchored to each other by zonula occludens or tight junctions, as well as zonulae adherens. The former provide structural support to the endothelial wall, while the latter physically connects adjacent cells. Additionally, the tight junctions circumscribe the cells and provide a seal with all adjacent cells. Therefore, the endothelium functions as an impermeable barrier between the capillary lumen and brain tissue.

Studies conducted on other mammals have implicated pericytes as integral components in the formation of the blood-brain barrier. These cells encircle endothelial cells of capillaries and are able to contract in order to regulate capillary blood flow. Consequently, the contractility also regulates the amount of blood flowing through the capillaries, thus enhancing the blood-brain barrier. Furthermore, some theories suggest that pericytes not only promote the formation of tight junctions, but they also inhibit the production of chemicals that promote vascular permeability.

Astrocytes are highly branched cells with small bodies found both in white matter (fibrous astrocytes) as well as in grey matter (protoplasmic astrocytes). The podocytes of both fibrous and protoplasmic astrocytes not only encircle nerve fibres and neuronal somas (respectively), but they also surround the abluminal surface of the capillaries. At this point, the processes are referred to as perivascular endfeet.

Blood–nerve barrier

A similar architectural construct exists in the peripheral nervous system that also limits the interaction between the peripheral nerves and circulating blood. This system is informally referred to as the blood-nerve barrier.

Blood–cerebrospinal fluid barrier

There is a similar barrier system in place that acts as an interface between blood and cerebrospinal fluid. This is known as the blood-cerebrospinal fluid barrier. The main similarities between the blood-cerebrospinal fluid barrier and the blood-brain barrier are:

Endothelial cells found in the capillary beds
Circumferential basement membrane around the abluminal surface of the capillary
And perivascular endfeet of the astrocytes also on the abluminal surface of the capillaries

The blood-cerebrospinal fluid barrier, however, also has fenestrated endothelial cells which allow easier passage of water, gases and lipophilic substances from the blood to the cerebrospinal fluid. Additionally, there are choroidal epithelial cells that are integral to the production of cerebrospinal fluid.

Choroid epithelium consists of ciliated cuboidal cells, equipped with microvilli, encompassing capillary tufts. Although the choroid epithelium is continuous with the ependymal layer (simple ciliated columnar cells) of the ventricle, it contains more tight junctions and consequently act as an effective barrier between blood and cerebrospinal fluid.

Circumventricular organs

There are regions of the brain where the blood-brain barrier is absent. This anatomical adaptation allows areas of the brain to monitor homeostatic changes within the systemic circulation. As a result, the brain is able to detect these changes and effect necessary protective physiological processes to mitigate these activities. There are seven such areas that are collectively referred to as the circumventricular organs. They can be further subdivided in secretory and sensory organs:

Secretory organs

Secretory organs, as the name suggests, are structures that release their products directly into the bloodstream or cerebrospinal fluid. The products may either be neurohormonal or other proteins. The secretory circumventricular organs include the neurohypophysis (posterior pituitary gland), pineal gland, subcommissural organ and median eminence.

Neurohypophysis – is also known as the posterior pituitary gland. It is the region of the hypophysis cerebri that originates from neuroectoderm and stores hypothalamic hormones (namely oxytocin and vasopressin). Hormones are delivered to the posterior pituitary gland by way of nerve fibres travelling from the paraventricular and supraoptic hypothalamic nuclei.

Pituitary gland (medial view)

Pineal gland – is a pine-shaped organ situated in the posterior aspect of the third ventricle. It lies just superior to, and in the midline of, the corpora quadrigemina (superior and inferior colliculi). The gland is encapsulated and lobulated (internally). Its constituent cells – pinealocytes – produce and cyclically release melatonin with the oscillating circadian rhythm (which is regulated by the suprachiasmatic nucleus). The absence of a blood-brain barrier here allows melatonin to be secreted into the rich blood supply coming from the posterior choroidal artery (branch of the posterior communicating artery) and internal cerebral veins (tributary to the great vein of Galen).

Pineal gland (medial view)

Subcommissural organ – is situated near to the caudal limit of the pineal recess (in the third ventricle) at the opening of the cerebral aqueduct of Sylvius. Here, it is caudally and ventrally related to the posterior commissure. The ependymal cells here, unlike those covering the other circumventricular organs, are tall ciliated columnar cells. The capillaries at this level are not as abundant or significantly fenestrated as those in other circumventricular organs. The subcommissural organ releases SCO-spondin, which is a glycoprotein that aggregates within the third ventricle and forms Reissner’s fibres. These fibres have been implicated in maintaining the patency of the aqueduct of Sylvius and their absence results in congenital hydrocephalus.

Subcommissural organ (sagittal view)

Median Eminence – has an intricate communication with the hypophyseal portal system that permits communication between systemic circulation and cerebrospinal fluid by way of the large number of fenestrated capillary beds it contains. The median eminence, which is located at the floor of the hypothalamus, is anterior to the tuber cinereum (ventral extent of the third ventricle). The median eminence also contains specialized cells known as tanycytes, which assist in modifying the permeability of the membrane to allow macromolecules to enter the peripheral circulation.

While we're on the subject, why not test your knowledge on the pituitary gland and hypophyseal portal system? Based on your quiz results, you will know your weak spots and what to study next!

Sensory organs

Sensory organs are responsible for monitoring the peripheral circulation and responding appropriately to reverse these changes or eliminate toxins. These organs include the subfornical organ, the organum vasculosum of the lamina terminalis and the area postrema.

Subfornical organ – is a small region at the interventricular foramen of Monro that is comprised of glial cells, neurons and a densely packed tuft of fenestrated capillaries. Like other circumventricular organs, the subfornical organ is covered by flattened ependymal cells. The subfornical organ has multiple homeostatic functions, including cardiovascular regulation, osmoregulation and energy regulation, among others. This concept is supported by its efferent projections to the lateral hypothalamus, the median preoptic area and organum vasculosum.

Subfornical organ (sagittal view)

Organum vasculosum – also known as the organum vasculosum of the lamina terminalis (OVLT) or simply, the vascular organ, it is cranial to the optic chiasm and caudal to the anterior commissure. The vascular bed of this organ is highly fenestrated and the ependyma contains flattened cells with very sparsely distributed cilia. The primary role of the vascular organ is to regulate fluid balance. As such, it receives afferent fibres from the subfornical organ, several hypothalamic nuclei and the locus coeruleus. It then projects to the supraoptic and median preoptic nuclei.

Area postrema – is probably the most commonly known circumventricular organ. It is a paired structure that is located at the caudal extent of the floor of the fourth ventricle. This bilateral structure is an important component of what is commonly termed the vomiting center. The absence of a blood-brain barrier in this location allows the area postrema to identify chemical irritants and stimulate a vomiting response.

Clinical points

Kernicterus

During the first few days of life, the neonate is at risk for a treatable condition known as physiological jaundice. In utero, there is a high concentration of foetal haemoglobin (HbF) which is completely replaced by adult haemoglobin (HbA) by about six months of age. However, this subtype of haemoglobin has a relatively high turnover rate.

A problem arises because the breakdown of haemoglobin results in the production of bilirubin. Haem is broken down by haem oxygenase to soluble biliverdin, which is then reduced to insoluble bilirubin by biliverdin reductase. Owing to its lipophilic nature, the insoluble bilirubin is able to cross lipid layers; including the blood-brain barrier. Fortunately, the carrier protein albumin typically binds to bilirubin to facilitate its transport in the vascular system to the liver for further processing.

However, in cases where bilirubin levels exceed that of albumin (i.e. saturation of the carrier proteins), excess bilirubin can then travel to the CNS and cross the blood-brain barrier. If left untreated, this could result in a pathological condition known as kernicterus, which is a bilirubin induced neuropathy.

There is a commonly accepted notion that neonates are at a higher risk of brain toxicity secondary to neurotoxin exposure as a result of poorly developed blood-brain barriers. However, new studies suggest that the blood-brain barrier is adequately formed during early foetal life. The alternative explanation for greater susceptibility of neonates to brain injury from agents such as bilirubin is that there are more transport proteins present in the blood-cerebrospinal fluid barrier in neonates that is not observed in adult blood-cerebrospinal fluid barriers.

As a result, these chemicals can gain access to the cerebrospinal fluid and from there, enter the brain. Additionally, unconjugated bilirubin is able to disrupt the tight junctions and gain access to the brain.

Blood–brain barrier disruption

Insults to the brain either by hypertensive encephalopathy, status epilepticus, or ischaemia may render the blood-brain barrier defective for two to three weeks. This disruption of the barrier will allow molecules that were typically barred from contacting brain tissue to enter the microenvironment of the central nervous system. One proposition for the exact mechanism by which this occurs is that the insult results in endothelial damage and subsequent disruption of the tight junctions.

Neoplastic lesions also provide a unique issue for the blood-brain barrier. One of the hallmarks of tumours is rapid angiogenesis. In the case of the barrier, the newly formed vessels, however, are devoid of a blood-brain barrier. Therefore, the tumour site also serves as a point of entry for neurotoxic agents to enter nervous tissue.

Sources

All content published on Kenhub is reviewed by medical and anatomy experts. The information we provide is grounded on academic literature and peer-reviewed research. Kenhub does not provide medical advice. You can learn more about our content creation and review standards by reading our content quality guidelines.

References:

Anderson, J., & Van Itallie, C. (2009). Physiology and Function of the Tight Junction. Cold Spring Harbor Perspectives In Biology, 1(2). (accessed 15/03/2016)
Elgot, A., Ahboucha, S., Bouyatas, M., Fèvre-Montange, M., & Gamrani, H. (2009). Water deprivation affects serotoninergic system and glycoprotein secretion in the sub-commissural organ of a desert rodent Meriones shawi. Neuroscience Letters, 466(1), 6-10. (accessed 15/03/2016)
Kiernan, J., Barr, M., & Rajakumar, N. (2014). Barr's the Human Nervous System(10th ed.). Philadelphia, PA: Lippincott Williams & Wilkins.
Rodríguez, E., Blázquez, J., & Guerra, M. (2010). The design of barriers in the hypothalamus allows the median eminence and the arcuate nucleus to enjoy private milieus: The former opens to the portal blood and the latter to the cerebrospinal fluid. Peptides, 31(4), 757-776. (accessed 15/03/2016)
Saunders, N., Liddelow, S., & Dziegielewska, K. (2012). Barrier Mechanisms in the Developing Brain. Frontiers In Pharmacology, 3. (accessed 15/03/2016)
Snell, R. (2010). Clinical Neuroanatomy (7th ed.). Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins.
Standring, S., & Gray, H. (2008). Gray's Anatomy. [Edinburgh]: Churchill Livingstone/Elsevier.
Tight Junctions. (2010). Bio.davidson.edu. (accessed 15/03/2016)

Illustrators:

Blood Brain Barriers - Originally from Stolp HB, Liddelow SA, Sá-Pereira I, Dziegielewska KM and Saunders NR (2013) Immune responses at brain barriers and implications for brain development and neurological function in later life. Front. Integr. Neurosci. 7:61. doi: 10.3389/fnint.2013.00061 - Shared under Creative Commons Attribution-Share Alike 3.0 Unported license.
Squamous epithelium and basement membrane (simple squamous epithelium in green) - Irina Münstermann
Pituitary gland (medial view) - Paul Kim
Pineal gland (medial view) - Paul Kim
Subcommissural organ (sagittal view) - Paul Kim
Subfornical organ (sagittal view) - Paul Kim
Organum vasculosum of lamina terminalis (sagittal view) - Paul Kim
Area postrema (sagittal view) - Paul Kim

Blood–brain barrier: want to learn more about it?

Our engaging videos, interactive quizzes, in-depth articles and HD atlas are here to get you top results faster.

What do you prefer to learn with?

“I would honestly say that Kenhub cut my study time in half.” – Read more.

Kim Bengochea, Regis University, Denver

Which of the following structures in the brain forms parts of the blood

We now know the key structure of the blood–brain barrier that offers a barrier is the “endothelial tight junction”. Endothelial cells line the interior of all blood vessels.

Which of the following structures forms the blood

The blood–brain barrier is formed by endothelial cells of the capillary wall, astrocyte end-feet ensheathing the capillary, and pericytes embedded in the capillary basement membrane.

What is associated with blood

Blood–brain barrier dysfunction contributes to pathology in a range of neurological conditions including multiple sclerosis, stroke, and epilepsy, and has also been implicated in neurodegenerative diseases such as Alzheimer's disease.