Citizendia
Your Ad Here

The term neuroprotection refers to mechanisms within the nervous system which protect neurons from apoptosis or degeneration, for example following a brain injury or as a result of chronic neurodegenerative diseases. The nervous system is a Network of specialized cells that communicate information about an animal's surroundings and itself Neurons (ˈnjuːɹɒn also known as neurones and nerve cells) are responsive cells in the Nervous system that process and transmit information This article deals with the social-philosophical meaning of degeneration Injury or bodily injury is Damage or Harm caused to the Structure or function of the Body caused by an outside agent or Neurodegenerative Disease ( Greek νέυρο- néuro-, "nerval" and Latin dēgenerāre, "to decline" or "to A disease is an abnormal condition of an organism that impairs bodily functions and can be deadly The word derives from the words "neuron" (Greek for nerve cell) and "protection" (Latin for "saving"). Neurons (ˈnjuːɹɒn also known as neurones and nerve cells) are responsive cells in the Nervous system that process and transmit information

Currently, there is a broad interest in how apoptosis and neuroprotection act on the brain in situations as different as growing up and learning or being ill (stroke, schizophrenia, Parkinson's disease).

A recent post-mortem study of the anterior cingulate cortex of persons with schizophrenia found increased levels of cellular signaling proteins, primarily PEBP, that may lead to increased levels of neuroprotection. The Anterior cingulate cortex (ACC is the frontal part of the Cingulate cortex, which resembles a "collar" form around the Corpus callosum, the fibrous Schizophrenia ( from the Greek roots schizein (σχίζειν "to split" and phrēn Cell signaling is part of a Complex system of Communication that governs basic cellular activities and coordinates cell actions Proteins are large Organic compounds made of Amino acids arranged in a linear chain and joined together by Peptide bonds between the Carboxyl (Clark, 2006)

Contents

Neuroprotection: Introduction to Erythropoietin and Erythrogenesis

Erythrogenesis

Erythropoietin (Epo) is a glycoprotein that controls erythropoiesis, or red blood cell production. Erythropoietin (ɨˌɹɪθɹoʊˈpɔɪɨtɨn /ɨˌɹɪθɹoʊˈpɔɪtən/ or /ɨˌɹiːθɹoʊ-/ or EPO is a Glycoprotein Hormone that controls Erythropoiesis is the process by which Red blood cells (erythrocytes are produced It is synthesized by renal peritubular cells in adults, with a small amount being produced in the liver (Jacobson 1957; Fisher 1996). It binds to the erythropoietin receptor (EpoR) on the red cell surface and activates a JAK2 cascade. This receptor is also found in a large number of tissues such as bone marrow cells, lymphocytes, and peripheral/central nerve cells, many of which activate intracellular biological pathways upon binding with Epo.

Primary Role in Red Cell Blood Line

Erythropoietin has its primary effect on red blood cells by promoting red blood cell survival through protecting these cells from apoptosis. It also cooperates with various growth factors involved in the development of precursor red cells. It has a range of actions including vasoconstriction-dependent hypertension, stimulating angiogenesis, and inducing proliferation of smooth muscle fibers. Hypertension, also referred to as high blood pressure, HTN or HPN, is a medical condition in which the Blood pressure is chronically elevated Angiogenesis is a physiological process involving the growth of new Blood vessels from pre-existing vessels Smooth muscle is a type of non- Striated muscle, found within the Tunica media layer of large and small Arteries and Veins, the bladder

History of Erythropoietin Research

Discovery of Erythropoietin

In 1906 Paul Carnot, a Professor of Medicine in Paris, and his assistant DeFlandre proposed the idea that erythropoiesis was regulated by hormones. After conducting experiments on rabbits subject to bloodletting, Carnot and DeFlandre attributed an increase in red blood cells in rabbit subjects to a hemotopic factor called hemopoietin. Eva Bonsdorff and Eeva Jalavisto continued to study red cell production and later called the hemopoietic substance ‘erythropoietin. ’ Further studies investigating the existence of Epo by Reissman and Erslev demonstrated that a certain substance circulated in the blood was able to stimulate red blood cell production and increase hematocrit. The hematocrit ( Ht or HCT) or packed cell volume ( PCV) or erythrocyte volume fraction (EVF is the proportion of Blood This substance was finally purified and confirmed as erythropoietin, opening doors to therapeutic uses for Epo in diseases like anemia (Jelkmann 2007; Hoke 2006). Anemia ( AmE) or anæmia/anaemia ( BrE) (from the Ancient Greek grc-Latn anaîmia, meaning “without blood” is defined as a qualitative

Recombinant Erythropoietin

In 1985, Lin et al. isolated the human erythropoietin gene from a genomic phage library and were able to characterize it for research and production (Lin 1985). Their research demonstrated that the gene for erythropoietin encoded the production of Epo in mammalian cells that is biologically active in vitro and in vivo. This opened up the door for the industrial production of recombinant erythropoietin (RhEpo) for treating anemia patients.

Novel Erythropoiesis Stimulating Protein

More recently a novel erythropoiesis stimulating protein (NESP) has been produced (MacDougall 2000). This glycoprotein demonstrates anti-anemic capabilities and has a longer terminal half-life than erythropoietin. NESP offers chronic renal failure patients a lower dose of hormones to maintain normal hemoglobin levels. Hemoglobin ( also spelled haemoglobin and abbreviated Hb or Hgb) is the Iron -containing Oxygen -transport Metalloprotein

Erythropoietin and the Central Nervous System

Erythropoietin and its receptor are both present in the central nervous system with erythropoietin alpha capable of crossing the blood brain barrier via active transport (Juul 1998). The blood-brain barrier (BBB is a metabolic or cellular structure in the Central nervous system (CNS that restricts the passage of various chemical substances and microscopic Active transport is the mediated process of moving particles across Biological membrane against the concentration gradient This was demonstrated by Juul et al. in their experiment to show the presence of Epo within the spinal fluid of infants and the presence of Epo-R in the spinal cord. Grimm et al reported on the detection of Epo and Epo-R expression in the mammalian retina, and a potential therapy to protect photoreceptors via hypoxic pretreatment (Grimm 2002).

The administration of erythropoietin protecting nerve cells from hypoxia-induced glutamate toxicity was demonstrated in experiments by Grimm et al in 2002 and Morishita et al in 1997 (Grimm 2002, Morishita 1997). Excitotoxicity is the pathological process by which nerve cells are damaged and killed by glutamate and similar substances Grimm and his collaborators showed that acute hypoxia inducement in the adult mouse retina stimulates expression of Epo in addition to other growth factors. Epo response is stimulated by hypoxia and is capable of protecting against apoptosis of erythroid progenitors via a mechanism that is described in the Mechanism of Action section (Grimm 2002). Chronic Hypoxia is a pathological condition in which the body as a whole ( generalized hypoxia) or region of the body ( tissue hypoxia) is deprived of adequate The work of Morishita and his colleagues has provided evidence for the presence of Epo-R in cultured hippocampal and cerebral cortical neurons in rat embryos. Epo was capable of protecting the cultured neurons from glutamate neurotoxicity after only a short exposure. They concluded that since erythropoietin exposure induces increases in intracellular calcium concentration, it must play a neuroprotective role in brain injury from hypoxia or ischemia (Morishita 1997). In Medicine, ischemia ( Greek ισχαιμία, isch- is restriction hema or haema is Blood) is a restriction

Erythropoietin’s role in reducing immune response has been described recently by Michael Brines through his research in administering recombinant human Epo into the blood circulation, which was translocated to the cerebrospinal fluid. RhEpo administer in rats prevented apoptosis of neurons during a cerebral arterial occlusion. It also reduced infarction volume by 75% and decreased post-infarct inflammation (Brines 2002).

Epo has also been demonstrated to enhance nerve recovery after spinal trauma. Celik and associates investigated motor neuron apoptosis in rabbits with a transient global spinal ischemia model (Celik 2002). In Vertebrates the term motor neuron (or motoneuron) classically applies to Neurons located in the Central nervous system (or CNS that project This allowed them to test if administered Epo can cross the blood-spinal cord barrier and protect motor neurons in the spinal cord. They produced spinal cord ischemia in rabbits and administered RhEpo. After comparison with a control administration of saline, the functional neurological status of animals given RhEpo was better after recovery from anesthesia, and kept improving over a two day period. The animals given saline demonstrated a poor functional neurological status and showed no significant improvements. These results showed that RhEpo has both an acute and delayed beneficial action in ischemic spinal cord injury.

Development with Mutant Epo and EpoR

While EpoR has been found in high levels in the embryonic brain, its role in brain development is unclear. Yu and colleagues proved evidence that Epo stimulates neural progenitor cells and prevents apoptosis in the embryonic brain using mice model experiments (Yu 2002). Mice without EpoR demonstrated severe anemia, defective heart development, and eventually death around embryonic day 13. 5 from apoptosis in the liver, endocardium, myocardium, and fetal brain. The liver is a vital organ in the human body and is present in Vertebrates and some other animals The endocardium is the innermost layer of tissue that lines the chambers of the heart Myocardium is the muscular tissue of the Heart. Relationship to other layers The other tissues of the heart are the Endocardium As early as embryonic day 10. 5 the lack of EpoR can affect brain development by increasing fetal brain apoptosis and decreasing the number of neural progenitor cells. By exposing cultures of EpoR positive embryonic cortical neurons to stimulation by Epo administration, the cells decreased apoptosis, as opposed to the decrease in neuron generation in EpoR negative cells. Yu et al demonstrated that the neuroprotective activity of Epo can be observed as early as embryonic day 10. 5 in the developing brain and contributes to selective cell survival in the developing brain.

However, Suzuki and colleagues questioned whether EpoR may or may not be a determining factor for the nervous system function (Suzuki 2002). The nervous system is a Network of specialized cells that communicate information about an animal's surroundings and itself They suggest that the contribution of Epo and EpoR to neuroprotection and development are not as clearly understood as its role in erythropoiesis in hematopoietic tissue. Haematopoiesis (from Ancient Greek haima blood poiesis to make (or hematopoiesis in the United States sometimes also haemopoiesis or This group studied a line of mice that expressed EpoR exclusively in hematopoietic cells and found that the mice developed normally and were fertile, despite the lack of EpoR in nonhematopoietic tissue. They analyzed this line of mice and found differential expression of EpoR between erythroid cells. Most notably, they found that plasma Epo concentration is regulated by nonhematopoietic EpoR expression when they timed the peak of plasma concentrations for induced anemia in mutant and wild-type mice. Anemia ( AmE) or anæmia/anaemia ( BrE) (from the Ancient Greek grc-Latn anaîmia, meaning “without blood” is defined as a qualitative As such, they concluded that the expression of EpoR in nonhematopoietic tissue is dispensable in normal mouse development, but that the sensitivity of erythroid progenitors to Epo is regulated by the expression of EpoR.

Erythropoietin and the Peripheral Nervous System

Production and Localization in PNS

Erythropoietin and its receptor are also present in the peripheral nervous system, specifically in the bodies and axons of ganglions in the dorsal root, and at increased levels in Schwann cells after peripheral nerve injury (Campana 2001). The peripheral nervous system ( PNS) resides or extends outside the Central nervous system (CNS which consists of the Brain and Spinal cord. The distribution of EpoR is different than Epo, specifically in some neuronal cell bodies in the dorsal root ganglion, endothelial cells, and Schwann cells of normal nerves. In Anatomy and Neurology, the dorsal root Ganglion (or spinal ganglion) is a nodule on a Dorsal root that contains cell bodies of The endothelium is the thin layer of cells that line the interior surface of Blood vessels forming an interface between circulating Blood in the Named after the German physiologist Theodor Schwann, Schwann cells (also referred to as neurolemmocytes) are a variety of Glial cell that mainly Most importantly, experiments with immunostaining revealed that the distribution and concentration of EpoR on Schwann cells doesn’t change after peripheral nerve injury. This is in agreement with research that showed Epo is up-regulated according to mRNA expression in astrocytes and hypoxia-induced neurons, while EpoR is not (Bernaudin 2000). Messenger ribonucleic acid ( mRNA) is a molecule of RNA encoding a chemical "blueprint" for a Protein product Astrocytes (also known collectively as astroglia) are characteristic star-shaped glial cells in the Brain and Spinal cord. A correlation between the expression of Epo-R in ganglion cells and binding to sensory receptors in the periphery like Pacini bodies and neuromuscular spindles suggests that Epo-R is related to touch regulation (Lykissas 2007).

Erythropoietin in Peripheral Nerve Injury

Site of Injury

After nerve injury, the increased production of Epo may induce activation of certain cellular pathways, while the concentration of EpoR doesn’t change. In Schwann cells, increased erythropoietin levels may stimulate Schwann cell proliferation via JAK2 and ERK/MAP kinase activation to be explained later. Janus kinase ( JAK) is a family of intracellular non-receptor Tyrosine kinases that transduce Cytokine -mediated signals via the JAK-STAT pathway Similar to stimulation of red blood cell precursor cells (erythrogenesis), erythropoietin stimulates non-differentiated Schwann cells to proliferate (Lykissas 2007)

Anti-apoptosis Mechanisms

Although the mechanism is unclear, it is apparent that erythropoietin has anti-apoptotic action after central and peripheral nerve injury. Cross-talk between JAK2 and NF-kB signaling cascades has been demonstrated to be a possible factor in central nerve injury. NF-κB ( nuclear factor-kappa B) is a protein complex that is a Transcription factor. Erythropoietin has also been shown to prevent axonal degeneration when produced by neighboring Schwann cells with nitrous oxide as the axonal injury signal (Keswani 2004). Nitrous oxide, commonly known as " laughing gas," is a Chemical compound with the Chemical formula N 2 O.

Erythropoietin’s Mode of Action

Direct and Indirect Effects

Erythropoietin exerts its neuroprotective role directly by activating transmitter molecules that play a role in erythrogenesis and indirectly by restoring blood flow (Springborg 2002). Springborg and colleagues investigated the effects of a subcutaneous administration of RhEpo on cerebral blood flow autoregulation after experimental subarachnoid hemorrhage. By examining different groups of male Sprague-Dawley Rats they found that the injection of Epo after induction of hemorrhage normalized the autoregulation of cerebral blood flow, while those treated with a vehicle showed no autoregulation. Bleeding, technically known as hemorrhaging / haemorrhaging (see American and British spelling differences) is the loss of Blood from

Pathway of Action

The pathway for erythropoietin in both the central and peripheral nervous systems begins with the binding of Epo to EpoR. This leads to the enzymatic phosphorylation of PI3-K and NF-kb and results in the activation of proteins that regulate nerve cell apoptosis (Chong 2002). Phosphoinositide 3-kinases (PI 3-kinases or PI3Ks are a family of related enzymes that are capable of phosphorylating the 3 position Hydroxyl group of the Inositol Recent research shows that Epo activates JAK2 cascades which activate NF-kB, leading to the expression of CIAP and c-IAP2, two apoptosis-inhibiting genes. Research conducted in rat hippocampal neurons demonstrates that the protective role of Epo in hypoxia-induced cell death acts through extracellular signal-regulated kinases ERK1, ERK2 and protein kinase Akt-1/PKB (Siren 2001). They found that the action of Epo is not limited to just promoting cell survival and that the inhibition of neural apoptosis underlies short latency protective effects of Epo after brain injury. Accordingly, the neurotrophic actions may demonstrate longer-latency effects, but more research needs to be conducted on its clinical safety and effectiveness.

Pathway for Cerebral Damage and Inflammation

Additionally to the anti-apoptotic effect, Epo reduces inflammatory response during different types of cerebral injury via the NF-kB pathway (Digicaylioglou 2001). Inflammation ( Latin, inflamatio, to set on fire is the complex biological response of vascular tissues to harmful stimuli such as Pathogens The NF-kB pathway activated by Epo/EpoR phosphorylation plays a role in regulating inflammatory and immune response, in addition to preventing apoptosis due to cellular stress (Yamamoto 2001). NF-kB proteins regulate immune response through B-lymphocyte control and T-lymphocyte proliferation. B cells are Lymphocytes that play a large role in the humoral immune response (as opposed to the cell-mediated immune response, which is governed by T cells belong to a group of White blood cells known as Lymphocytes, and play a central role in Cell-mediated immunity. These proteins are all important for the expression of genes specific to immune and inflammatory response regulation.

Neuroprotective Effects

As a neuroprotective agent erythropoietin has many functions: antagonizing glutamate cytotoxic action, enhancing antioxidant enzyme expression, reducing free radical production rate, and affecting neurotransmitter release. In Chemistry, radicals (often referred to as free radicals) are atoms molecules or ions with Unpaired electrons on an otherwise Open shell It exerts its neuroprotective effect indirectly through restoration of blood flow or directly by activating transmitter molecules in neurons that also play a role in erythrogenesis. Although apoptosis is not reversible, early intervention with neuroprotective therapeutic procedures such as erythropoietin administration may reduce the number of neurons that undergo apoptosis (Lykissas 2007).

Recombinant Human EPO Administration

The systemic administration of RhEpo has been shown to reduce dorsal root ganglion cell apoptosis (Campana 2003). While animals treated with RhEpo weren’t initially protected from mechanical allodynia after spinal nerve crush, they showed a significantly improved recovery rate compared to animals not treated with RhEpo. Allodynia, meaning "other pain" is a Painful response to a usually non-painful stimulus and can be either static or mechanical This RhEpo therapy increased JAK2 phosphorylation, which has been found to be a key signaling step in Epo-induced neuroprotection by an anti-apoptotic mechanism. These findings demonstrate Epo therapy as a feasible treatment of neuropathic pain by reducing the protraction of pain after nerve injury. However, more studies need to be conducted to determine the optimal time and dosage for RhEpo treatment.

Neonatal Brain Injury

In infants with poor neurodevelopment, prematurity and asphyxia are typical problems. These conditions can lead to cerebral palsy, mental retardation, and sensory impairment. Cerebral palsy ( CP) is an Umbrella term encompassing a group of non-progressive, non- contagious conditions that cause Physical disability Mental retardation is a generalized triarchic disorder characterized by subaverage cognitive functioning and deficits in two or more adaptive behaviors with onset before the age However, recent research has demonstrated that high doses of recombinant erythropoietin can reduce or prevent this type of neonatal brain injury if administered early (McPherson 2007). A high rate of neuronal apoptosis is evident in the developing brain due to initial overproduction. Neurons that are electrically active and make synaptic connections survive, while those that do not undergo apoptosis. While this is a normal phenomenon, it is also known that neurons in the developing brain are at an increased risk to undergo apoptosis in response to injury. A small amount of the RhEpo can cross the blood-brain barrier and protect against hypoxic-ischemia injury. Epo treatment has also shown to preserve hemispheric brain volume 6 weeks after neonatal stroke (Gonzalez 2007). A stroke is the rapidly developing loss of brain functions due to a disturbance in the blood vessels supplying blood to the brain It demonstrated both neuroprotective effects and a direction towards neurogenesis in neonatal stroke without associated long-term difficulties.

Cognitive and Behavioral Effects

Systemic administration of RhEpo has also been shown to reduce lesion-associated behavioral impairment in hippocampally injured rats (Mogensen 2007). The study confirmed that Epo administration improved posttraumatic behavioral and cognitive abilities versus a saline control that experienced no improvement, although it had no detectable effect on task acquisition in non-lesioned animals. Epo is able to reduce or eliminate the consequences of mechanical injury to the hippocampus but also demonstrates possible therapeutic effects in other cognitive domains. The hippocampus is a part of the Forebrain, located in the medial Temporal lobe.

Dopaminergic Neurons

Epo was shown to specifically protect dopaminergic neurons, which are closely tied in to attention deficit hyperactivity disorder (McPherson 2007). Dopaminergic means "related to the Neurotransmitter Dopamine " Attention-Deficit Hyperactivity Disorder (ADHD is a neurobehavioral developmental disorder affecting about 3-5% of the world's population Specifically in mice, Epo demonstrated protective effects on nigral dopaminergic neurons in a mouse model of Parkinson’s Disease (Xue 2007). Parkinson's disease (also known as Parkinson disease or PD) is a degenerative disorder of the Central nervous system that often impairs the sufferer's This recent experiment tested the hypothesis that RhEpo could protect dopaminergic neurons and improve the neurobehavioral outcome in a rat model of Parkinson’s Disease. The intrastriatal administration of RhEpo significantly reduced the degree of rotational asymmetry, and the RhEpo-treated rats demonstrated improvement in skilled forearm use. These experiments demonstrated that intrastriatal administration of RhEpo can protect nigral dopaminergic neurons from 6-OHDA induced cell death and improve neurobehavioral outcome in a rat model of Parkinson’s Disease.

Current Treatment

Currently methylprednisolone (Medrol) is only pharmaceutical agent used to treat spinal cord trauma (Lykissas 2007). Methylprednisolone is a synthetic Glucocorticoid drug It is sold in the USA and Canada under the brand names Medrol and Solu-Medrol It is a corticosteroid that reduces damage to nerve cells and decreases inflammation near injury sites. It is typically administered within the first 8 hours after injury, but demonstrates poor results both in patients and experimental models. Some controversy has come about concerning the use of methylprednisolone because of its associated risks and poor clinical results, but it is the only medication available at this time.

Neurotherapeutic Role

If administered within a specific timeframe in experiments with erythropoietin in central nervous system, Epo has a favorable response in brain and spinal cord injuries like mechanical trauma or subarachnoid hemorrhages (Brines 2002). Brines’ research also demonstrates a therapeutic role in modulating neuronal excitability and acting as a trophic factor both in vivo and in vitro. This administration of erythropoietin functions by inhibiting the apoptosis of sensor and motor neurons via stimulation of intracellular anti-apoptotic metabolic paths. The action of erythropoietin on Schwann cells and inflammatory response after neurological trauma also points to initial stimulation of nerve regeneration after peripheral nerve injury (Lykissas 2007).

Role in Neurogenesis

Recent study by Tsai and colleagues demonstrated that erythropoietin and its receptor have an essential role in neurogenesis, specifically in post-stroke neurogenesis and in the migration of neuroblasts to areas of neural injury (Tsai 2006). Neurogenesis ( birth of Neurons ' is the process by which neurons are created A neuroblast is a dividing cell that will develop into Neurons or Glia. They used genetics to evaluate the role of endogenous Epo and EpoR in mammalian neurogenesis. They found severe embryonic neurogenesis defects in animals that were null for Epo or EpoR genes. They also experimented with EpoR knock-down animals and found deletion of EpoR genes specific to the brain lead to a reduction in cell growth in the subventricular zone and impaired neurogenesis after stroke. This post-stroke neurogenesis was characterized by an impaired migration of neuroblasts in the peri-infarct cortex. This research agrees with the classical approach to Epo/EpoR contributions in development in that it demonstrated an Epo/EpoR requirement for embryonic neural development, adult neurogenesis, and neuron regeneration after injury. They also found that high doses of exogenous erythropoietin could demonstrate a neuroprotective role by binding to a receptor that contains the common beta receptor but lacks EpoR. These types of studies into Epo and EpoR null animals have seen and are further elucidating the neuroprotective role of Epo/EpoR in genetics and development.

A Different View: Neuroregeneration

While the neuroprotective effects of Epo administration in models of brain injury and disease have been well described, the effects of Epo on Neuroregeneration are currently being investigated. Neuroregeneration refers to the regrowth or repair of the nervous tissues cells or cell products Epo administration during optic nerve transaction was used to assess the neuroprotective properties in vivo as well as demonstrate the neuroregenerative capabilities (King 2007). The intravitreal injection of Epo increased [[retinal ganglion cell somata and axon survival after transaction. A small amount of axons penetrated the transaction site and regenerated up to 1 mm into the distal nerve. In a second experiment, Epo doubled the number of retinal ganglion cell axons regenerating along a length of nerve grafted onto the retrobulbar optic nerve. This evidence of Epo as a neuroprotective and neuroregenerative agent is extremely promising for Epo as therapy in central nerve injury and repair.

Hope for the Future

Erythropoietin has shown to have a neuroprotective role in both the central and peripheral nervous system through pathways that inhibit apoptosis. It has been successful in demonstrating neuroprotective effects in many models of brain injury and in some experiments. It is also capable of influencing neuron stimulation and promoting peripheral nerve regeneration. Epo has a lot of potential uses and could provide a therapeutic answer for nervous system injury. However, more studies need to be conducted to determine the optimal time and dosage for Epo treatment.

Glaucoma

Brain Cooling

Ashfaq Shuaib, MD, FRCPC, Director of Neurology at the University of Alberta Hospital in Edmonton, led studies which showed that post-ischemic hypothermia can provide neuroprotection, as well, given that it is of a sufficient duration and degree. 48 hours of 32 to 34 degree hypothermia of rats, initiated two and a half hours after the initiated onset of middle cerebral artery occlusion, preserved the rats' ability to retrieve food pellets in a "staircase test" of independent forelimb reaching ability.

References

Dictionary

neuroprotection

-noun

  1. The protection of neurons from neurodegeneration
© 2009 citizendia.org; parts available under the terms of GNU Free Documentation License, from http://en.wikipedia.org
 Dapyx Software network: MP3 Explorer | Ebook Manager | Zenithic