scholarly journals Functional roles of three cues that provide nonsynaptic modes of communication in the brain: electromagnetic field, oxygen, and carbon dioxide

2018 ◽  
Vol 119 (1) ◽  
pp. 356-368 ◽  
Author(s):  
Luigi F. Agnati ◽  
Diego Guidolin ◽  
Guido Maura ◽  
Manuela Marcoli
Keyword(s):  
Carbon Dioxide ◽  
Central Nervous System ◽  
Brain Function ◽  
Complex Dynamics ◽  
External World ◽  
The Body ◽  
Functional Roles ◽  
Metabolic Substrates ◽  
The Central Nervous System ◽  
The Brain

The integrative actions of the brain depend on the exchange of information among its computational elements. Hence, this phenomenon plays the key role in driving the complex dynamics of the central nervous system, in which true computations interact with noncomputational dynamical processes to generate brain representations of the body and of the body in the external world, and hence the finalistic behavior of the organism. In this context, it should be pointed out that, besides the intercellular interactions mediated by classical electrochemical signals, other types of interactions, namely, “cues” and “coercions,” also appear to be exploited by the system to achieve its function. The present review focuses mainly on cues present in the environment and on those produced by cells of the body, which “pervade” the brain and contribute to its dynamics. These cues can also be metabolic substrates, and, in most cases, they are of fundamental importance to brain function and the survival of the entire organism. Three of these highly pervasive cues will be analyzed in greater detail, namely, oxygen, carbon dioxide, and electromagnetic fields (EMF). Special emphasis will be placed on EMF, since several authors have suggested that these highly pervasive energy fluctuations may play an important role in the global integrative actions of the brain; hence, EMF signaling may transcend classical connectionist models of brain function. Thus the new concept of “broadcasted neuroconnectomics” has been introduced, which transcends the current connectomics view of the brain.

scholarly journals Immune cells and CNS physiology: Microglia and beyond

2018 ◽  
Vol 216 (1) ◽  
pp. 60-70 ◽  
Author(s):  
Geoffrey T. Norris ◽  
Jonathan Kipnis
Keyword(s):  
Central Nervous System ◽  
Immune Cells ◽  
Brain Function ◽  
Brain Parenchyma ◽  
The Body ◽  
Immune Repertoire ◽  
Perivascular Macrophages ◽  
The Central Nervous System ◽  
Cns Immunity ◽  
The Brain

Recent advances have directed our knowledge of the immune system from a narrative of “self” versus “nonself” to one in which immune function is critical for homeostasis of organs throughout the body. This is also the case with respect to the central nervous system (CNS). CNS immunity exists in a segregated state, with a marked partition occurring between the brain parenchyma and meningeal spaces. While the brain parenchyma is patrolled by perivascular macrophages and microglia, the meningeal spaces are supplied with a diverse immune repertoire. In this review, we posit that such partition allows for neuro–immune crosstalk to be properly tuned. Convention may imply that meningeal immunity is an ominous threat to brain function; however, recent studies have shown that its presence may instead be a steady hand directing the CNS to optimal performance.

Gut–brain axis biochemical signalling from the gastrointestinal tract to the central nervous system: gut dysbiosis and altered brain function

2018 ◽  
Vol 94 (1114) ◽  
pp. 446-452 ◽  
Author(s):  
Borros M Arneth
Keyword(s):  
Central Nervous System ◽  
Nervous System ◽  
Brain Function ◽  
Well Being ◽  
Immune System Activation ◽  
Published Evidence ◽  
Bidirectional Communication ◽  
The Central Nervous System ◽  
Intestinal Functions ◽  
The Brain

BackgroundThe gut–brain axis facilitates a critical bidirectional link and communication between the brain and the gut. Recent studies have highlighted the significance of interactions in the gut–brain axis, with a particular focus on intestinal functions, the nervous system and the brain. Furthermore, researchers have examined the effects of the gut microbiome on mental health and psychiatric well-being.The present study reviewed published evidence to explore the concept of the gut–brain axis.AimsThis systematic review investigated the relationship between human brain function and the gut–brain axis.MethodsTo achieve these objectives, peer-reviewed articles on the gut–brain axis were identified in various electronic databases, including PubMed, MEDLINE, CIHAHL, Web of Science and PsycINFO.ResultsData obtained from previous studies showed that the gut–brain axis links various peripheral intestinal functions to brain centres through a broad range of processes and pathways, such as endocrine signalling and immune system activation. Researchers have found that the vagus nerve drives bidirectional communication between the various systems in the gut–brain axis. In humans, the signals are transmitted from the liminal environment to the central nervous system.ConclusionsThe communication that occurs in the gut–brain axis can alter brain function and trigger various psychiatric conditions, such as schizophrenia and depression. Thus, elucidation of the gut–brain axis is critical for the management of certain psychiatric and mental disorders.

Macrophages in the Brain: Friends or Enemies?

Physiology ◽  
1994 ◽  
Vol 9 (2) ◽  
pp. 80-84 ◽  
Author(s):  
D Piani ◽  
DB Constam ◽  
K Frei ◽  
A Fontana
Keyword(s):  
Central Nervous System ◽  
Host Defense ◽  
The Body ◽  
Defense System ◽  
Tissue Destruction ◽  
Brain Macrophages ◽  
Host Defense System ◽  
The Central Nervous System ◽  
The Brain ◽  
Macrophage Lineage

Cells of the macrophage lineage are ubiquitously distributed in the body, including the central nervous system. They represent an essential host defense system to protect from infections. However, recent evidence indicates that brain macrophages may also be responsible for tissue destruction, including loss of neurons and demyelination.

The Pathogenesis of Somatic Disease in Mental Defectives

1951 ◽  
Vol 97 (409) ◽  
pp. 792-800 ◽  
Author(s):  
L. Crome
Keyword(s):  
Blood Pressure ◽  
Central Nervous System ◽  
Nervous System ◽  
Scientific Basis ◽  
The Body ◽  
Normal Person ◽  
Somatic Disease ◽  
The Central Nervous System ◽  
Mental Defectives ◽  
The Brain

The problems of the interdependence and unity of the brain and body have been put on a scientific basis by Pavlov and his successors. Bykov (1947) has, for example, been able to demonstrate that the cortex plays a leading part in the regulation of somatic processes, such as secretion of urine, blood pressure, peristalsis and metabolism. It is therefore reasonable to argue that lesions of the central nervous system will be reflected in the pathogenesis and course of morbid processes in the body. It does not follow, however, that this influence will necessarily be in the direction of greater lability, more rapid pathogenesis or more extensive destruction. The outstanding feature of the central nervous system is its plasticity and power of compensation. It is therefore possible and probable that those parts of the nervous system which remain intact will take over and compensate for the function of the lost ones. Emotion may, for example, lead to polyuria, but it does not follow that urinary secretion will be impaired in a leucotomized patient. The brain may well play an important part in the infective processes of a normal person, but the defence against infection in a microcephalic idiot may remain perfectly adequate, and may even be more effective than in a normal person, provided that the mechanism of the immunity and phagocytosis had been more fully mobilized in the course of his previous life.

scholarly journals Modern aspects of neuropathogenesis and neurological manifestations of COVID-19

2021 ◽  
Vol 17 (2) ◽  
pp. 6-15
Author(s):  
L.A. Dziak ◽  
O.S. Tsurkalenko ◽  
K.V. Chekha ◽  
V.M. Suk
Keyword(s):  
Central Nervous System ◽  
Nervous System ◽  
Psychiatric Symptoms ◽  
Clinical Manifestations ◽  
The Body ◽  
Altered Level ◽  
Wide Range ◽  
The Central Nervous System ◽  
The Brain

Coronavirus infection is a systemic pathology resulting in impairment of the nervous system. The involvement of the central nervous system in COVID-19 is diverse by clinical manifestations and main mechanisms. The mechanisms of interrelations between SARS-CoV-2 and the nervous system include a direct virus-induced lesion of the central nervous system, inflammatory-mediated impairment, thrombus burden, and impairment caused by hypoxia and homeostasis. Due to the multi-factor mechanisms (viral, immune, hypoxic, hypercoagulation), the SARS-CoV-2 infection can cause a wide range of neurological disorders involving both the central and peripheral nervous system and end organs. Dizziness, headache, altered level of consciousness, acute cerebrovascular diseases, hypogeusia, hyposmia, peripheral neuropathies, sleep disorders, delirium, neuralgia, myalgia are the most common signs. The structural and functional changes in various organs and systems and many neurological symptoms are determined to persist after COVID-19. Regardless of the numerous clinical reports about the neurological and psychiatric symptoms of COVID-19 as before it is difficult to determine if they are associated with the direct or indirect impact of viral infection or they are secondary to hypoxia, sepsis, cytokine reaction, and multiple organ failure. Penetrated the brain, COVID-19 can impact the other organs and systems and the body in general. Given the mechanisms of impairment, the survivors after COVID-19 with the infection penetrated the brain are more susceptible to more serious diseases such as Parkinson’s disease, cognitive decline, multiple sclerosis, and other autoimmune diseases. Given the multi-factor pathogenesis of COVID-19 resulting in long-term persistence of the clinical symptoms due to impaired neuroplasticity and neurogenesis followed by cholinergic deficiency, the usage of Neuroxon® 1000 mg a day with twice-day dosing for 30 days. Also, a long-term follow-up and control over the COVID-19 patients are recommended for the prophylaxis, timely determination, and correction of long-term complications.

scholarly journals Several forms of callitachykinins are distributed in the central nervous system and intestine of the blowfly Calliphora vomitoria.

1995 ◽  
Vol 198 (12) ◽  
pp. 2527-2536
Author(s):  
D R Nässel ◽  
M Y Kim ◽  
C T Lundquist
Keyword(s):  
Central Nervous System ◽  
Nervous System ◽  
High Performance ◽  
The Body ◽  
Enzyme Linked Immunosorbent Assay ◽  
Additional Material ◽  
Immunoreactive Material ◽  
The Central Nervous System ◽  
Entire Central Nervous System ◽  
The Brain

We have examined the distribution of two tachykinin-related neuropeptides, callitachykinin I and II (CavTK-I and CavTK-II), isolated from whole-animal extracts of the blowfly Calliphora vomitoria. Extracts of dissected brains, thoracic-abdominal ganglia and midguts of adult blowflies and the entire central nervous system of larval flies were analysed by high performance liquid chromatography (HPLC) combined with enzyme-linked immunosorbent assay (ELISA) for the presence of CavTKs. To identify the two neuropeptides by HPLC, we used the retention times of synthetic CavTK-I and II as reference and detection with an antiserum raised to locustatachykinin II (shown here to recognise both CavTK-I and II). The brain contains only two immunoreactive components, and these have exactly the same retention times as CavTK-I and II. The thoracic-abdominal ganglia and midgut contain immunoreactive material eluting like CavTK-I and II as well as additional material eluting later. The larval central nervous system (CNS) contains material eluting like CavTK-I and II as well as a component that elutes earlier. We conclude that CavTK-I and II are present in all assayed tissues and that additional, hitherto uncharacterised, forms of tachykinin-immunoreactive material may be present in the body ganglia and midgut as well as in the larval CNS. An antiserum was raised to CavTK-II for immunocytochemistry. This antiserum, which was found to be specific for CavTK-II in ELISA, labelled all the neurones and midgut endocrine cells previously shown to react with the less selective locustatachykinin antisera. It is not clear, however, whether CavTK-I and II are colocalised in all LomTK-immunoreactive cells since there is no unambiguous probe for CavTK-I.

scholarly journals Purinergic Receptors of the Central Nervous System: Biology, PET Ligands, and Their Applications

2020 ◽  
Vol 19 ◽  
pp. 153601212092760
Author(s):  
Hamideh Zarrinmayeh ◽  
Paul R. Territo
Keyword(s):  
Central Nervous System ◽  
Nervous System ◽  
Purinergic Receptors ◽  
P2y Receptors ◽  
Cns Disorders ◽  
Extracellular Adenosine ◽  
Functional Roles ◽  
Positron Emission ◽  
The Central Nervous System ◽  
The Brain

Purinergic receptors play important roles in central nervous system (CNS). These receptors are involved in cellular neuroinflammatory responses that regulate functions of neurons, microglial and astrocytes. Based on their endogenous ligands, purinergic receptors are classified into P1 or adenosine, P2X and P2Y receptors. During brain injury or under pathological conditions, rapid diffusion of extracellular adenosine triphosphate (ATP) or uridine triphosphate (UTP) from the damaged cells, promote microglial activation that result in the changes in expression of several of these receptors in the brain. Imaging of the purinergic receptors with selective Positron Emission Tomography (PET) radioligands has advanced our understanding of the functional roles of some of these receptors in healthy and diseased brains. In this review, we have accumulated a list of currently available PET radioligands of the purinergic receptors that are used to elucidate the receptor functions and participations in CNS disorders. We have also reviewed receptors lacking radiotracer, laying the foundation for future discoveries of novel PET radioligands to reveal these receptors roles in CNS disorders.

Influence of Starvation on Absorption, Distribution, and Action of Barbital in Mice and Rats

1974 ◽  
Vol 52 (6) ◽  
pp. 1192-1200 ◽  
Author(s):  
J. Brodeur ◽  
S. Lalonde ◽  
J. Leroux
Keyword(s):  
Central Nervous System ◽  
Early Phase ◽  
The Body ◽  
Total Blood ◽  
Blood Concentrations ◽  
Influence Of Food ◽  
The Central Nervous System ◽  
Righting Reflex ◽  
The Moment ◽  
The Brain

The influence of food deprivation on the disposition of barbital during the early phase following administration of the drug was studied in mice and rats. Starvation consisted of withholding solid food, but not water, for 24–72 h in mice, and 72 h in rats. The results show that starvation leads to higher blood concentrations of barbital given intraperitoneally (i.p.) and subcutaneously to mice and rats, and intramuscularly to rats. This effect was observed 2.5–10 min following the injection of the barbiturate. In mice, starvation significantly reduced the interval between injection of the drug and loss of the righting reflex, but it extended the duration of the sleeping period. When barbital was given intravenously, starvation no longer resulted in higher blood concentrations of the drug, although starved mice went to sleep more rapidly than fed controls. At the moment of loss of the righting reflex. starved mice had significantly lower concentrations of barbital in the brain than fed controls. The total blood and plasma volumes of starved animals were moderately increased when expressed as a percentage of the body weight. These results suggest that starvation might influence the early phase of barbital absorption following its parenteral administration. There is also an indication that starvation could induce a state of hypersensitivity of the central nervous system to barbital.

scholarly journals Brain-derived neurotrophic factor as a potential therapeutic tool in the treatment of nervous system disorders

2020 ◽  
Vol 74 ◽  
pp. 517-531
Author(s):  
Wioletta Kazana ◽  
Agnieszka Zabłocka
Keyword(s):  
Central Nervous System ◽  
Nervous System ◽  
Neurotrophic Factor ◽  
Intracellular Transport ◽  
Brain Derived Neurotrophic Factor ◽  
Nerve Cells ◽  
The Body ◽  
Bdnf Level ◽  
The Central Nervous System ◽  
The Brain

Brain-derived neurotrophic factor (BDNF) plays an important role in the proper functioning of the nervous system. It regulates the growth and survival of nerve cells, and is crucial in processes related to the memory, learning and synaptic plasticity. Abnormalities related to the distribution and secretion of BDNF protein accompany many diseases of the nervous system, in the course of which a significant decrease in BDNF level in the brain is observed. Impairments of BDNF transport may occur, for example, in the event of a single nucleotide polymorphism in the Bdnf (Val66Met) coding gene or due to the dysfunctions of the proteins involved in intracellular transport, such as huntingtin (HTT), huntingtin-associated protein 1 (HAP1), carboxypeptidase E (CPE) or sortilin 1 (SORT1). One of the therapeutic goals in the treatment of diseases of the central nervous system may be the regulation of expression and secretion of BDNF protein by nerve cells. Potential therapeutic strategies are based on direct injection of the protein into the specific region of the brain, the use of viral vectors expressing the Bdnf gene, transplantation of BDNF-producing cells, the use of substances of natural origin that stimulate the cells of the central nervous system for BDNF production, or the use of molecules activating the main receptor for BDNF – tyrosine receptor kinase B (TrkB). In addition, an appropriate lifestyle that promotes physical activity helps to increase BDNF level in the body. This paper summarizes the current knowledge about the biological role of BDNF protein and proteins involved in intracellular transport of this neurotrophin. Moreover, it presents contemporary research trends to develop therapeutic methods, leading to an increase in the level of BDNF protein in the brain.

scholarly journals Nanotherapeutics in Neuropathologies: Obstacles, Challenges and Recent Advancements in CNS Targeted Drug Delivery Systems

2020 ◽  
Vol 18 ◽  
Author(s):  
Vimal Patel ◽  
Vishal Chavda ◽  
Jigar Shah
Keyword(s):  
Drug Delivery ◽  
Central Nervous System ◽  
Nervous System ◽  
Targeted Drug Delivery ◽  
Drug Dose ◽  
The Body ◽  
Brain Drug Delivery ◽  
The Central Nervous System ◽  
Targeted Drug ◽  
The Brain

: Neurology and associated nanotherapeutics is a complex field in terms of therapeutics and neurological disorder complexity. Brain is an intricate appendage and requires more precise embattled treatment for the particular diseases and hence it’s a broad scale for developing more targeted drug deliveries. The brain is one of the most inaccessible tissues of the body due to the existence of the blood-brain barrier (BBB), thus delivery of drugs inside the brain is a striking dare and it is also tricky to treat central nervous system (CNS) complications pharmacologically. The therapeutic aspiration is to accomplish a lowest drug meditation in the brain tissues so as to gain favoured therapeutic results. To devastate this obstacle, nanotechnology is engaged in the field of targeted brain drug delivery and neuropathology targeting. These carriers hold myriad ability as they may augment the drug delivery into the brain by shielding them from degradation and prolonging their transmission in the blood, as well as promoting their transport through the BBB. Nanopharmaceuticals are quickly sprouting as new avenue that is engaged with the drug-loaded nanocarriers to demonstrate unique physicochemical properties and tiny size range for penetrating into the central nervous system. The enchantment behind their therapeutic achievement is the condensed drug dose and inferior toxicity, whereby restricting the therapeutic compound to the specific site. Therefore, in this article we have tried to recapitulate the advances the novel scopes for the brain targeted drug delivery for complex neurological disorders.

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