Amidato de N-acetil Selank 10 mg

N-Acetyl Selank Amidate is a modified form of the peptide Selank. Selank is a short nootropic and anxiolytic peptide originally developed in Russia. It is an analogue of naturally occurring tuftsin and has been shown to have immunomodulatory effects. Research suggests that Selank modifies gene expression in the brain, reducing the effects of the neurotransmitter GABA, altering cell membrane permeability, and enhancing production of brain-derived neurotrophic factor (BDNF).

The modified form of Selank, N-Acetyl Selank Amidate has a longer half-life and greater ability to cross the blood-brain barrier. It also has tighter receptor binding due to the amidation. Selank is currently being researched in animal models for the treatment of stroke and other ischemic brain diseases. It is also under consideration as a treatment of generalized anxiety disorder and to protect memory in the setting of neurodegenerative disease.

Secuencia de aminoácidos:Ac-TPRKEPV-NH2
Fórmula molecular: C₃₃h₅₇norte₁₁oh₉
Peso molecular: 751.9 g/mol
PubChem CID: 11765600
Número CAS: 129954-34-3
Sinónimos: Seleccionar, TP-7, UNII – TS9JR8EP1G

Fuente: PubChem

Here in the sequence, “Ac-” represents the Acetyl group attached to the N-terminus of the peptide, y “-NH2” represents the Amidated group at the C-terminus. The amino acid sequence “TPRKEPV” corresponds to the core Selank peptide. Acetyl-Selank-Amidate is a modified version of Selank, a synthetic peptide with anxiolytic and immunomodulatory properties. The addition of the Acetyl and Amidated groups may enhance its stability, biodisponibilidad, y eficacia.

Selank has several effects, particularmente en el sistema nervioso central, that are of interest to scientists. Research from Dr. Anastasiya Volkova (Institute of Molecular Genetics, Rusia) indicates that Selank produces these effects because of modulating gene expression. En otras palabras, Selank can turn on or off parts of DNA to affect the function of our bodies. Research in rats shows that Selank modifies the function of at least 52 different genes[1].

Selank and Anxiety

Perhaps the most carefully and thoroughly studied property of Selank is its ability to modulate anxiety. Research shows that Selank has clinical effects that are like those of drugs like benzodiazepines used in the treatment of serious anxiety disorders. Selank has been shown to effectively reduce anxiety, lower stress, and improve mood. It appears to do so via interaction (probably indirect) with the GABA_A receptor, just as benzodiazepines do. It even has similar sedative effects when compared to benzodiazepines.

Where Selank differs from drugs like Ativan and Valium, sin embargo, is that it does not appear to be habit-forming. Benzodiazepines have a well-known abuse potential and can cause physical dependence or even lead to addiction. Selank does not appear to have this problem and may, En realidad, be useful in helping those who are dependent on benzodiazepines to safely and effectively wean off of them.

Research shows that of the 84 genes linked to GABA, Selank modifies at least 45 of them. Como se señaló anteriormente, the effects of Selank on the GABA_A receptor are likely indirect. It is thought that Selank, rather than binding to the GABA receptor, instead modifies the affinity of the receptor for its natural ligand and thus helps to reduce anxiety by reducing the effect but not the concentration of natural GABA[1].

Curiosamente, Selank and traditional benzodiazepines have been tested in combination. The use of both appears to be more successful in treating certain types of anxiety than the use of either alone. En particular, the combination appears to be very useful in treating the often resistant form of anxiety known as unpredictable chronic mild stress[2].

Selank and the Blood-Brain Barrier

Selank is a member of the peptide family known as glyprolines. Glyprolines are well known for their regulatory functions in biological systems. En particular, glyprolines are known to exert protective and repair-promoting effects throughout the body[3]. Where their effects are seen is dependent on the amino acid sequence of the specific glyprotein. Some are active in the GI tract or pancreas while others, like Selank, are active in the central nervous system.

En general, the glyproline family has been neglected in research settings. A few traits that are common to these highly stable oligopeptides have been elucidated, sin embargo. Perhaps most important in the case of Selank is the ability of glyprolines to penetrate the blood-brain barrier. The blood-brain barrier (BBB) is a formidable amalgamation of cellular and extracellular components that limit the kinds of things that can pass from the general circulation into the central nervous system. Glyprolines more readily penetrate this barrier than most other oligopeptides.

N-Acetyl Selank Amidate and the Immune System

Según la Dra.. Olga Uchakina (Mercer University School of Medicine and Rockefeller Foundation grant recipient), Selank has been shown in animal studies to suppress the production of the inflammatory cytokine IL-6[4]. IL-6 (interleukin-6) is secreted by macrophages as well as by cells of the bone marrow and blood vessels. It is an inflammatory marker of severe COVID-19 infection. IL-6 is an important mediator of fever, neutrophil production, and B cell growth. In the central nervous system, IL-6 plays roles in sleep-associated consolidation of emotional memories and may be important as a mediator of pain perception.

It is as a mediator of pain perception that is of particular interest to researchers looking at IL-6 and Selank interactions. Research in rats suggests that Selank may modulate IL-6 expression in the central nervous system and may therefore help to reduce pain in the so-called asthenic symptoms[5]. It as long been controversial in the medical community whether there is a link between psychiatric conditions and physical pain. The ability of Selank to mitigate physical pain in psychiatric conditions seems to point to the accuracy of the hypothesis and offers a solution at the same time. It is unclear at present whether Selank might offer relief from other types of neurogenic pain. Future research could help to uncover a role of glyprolines as regulators of pain generated by the nervous system, and thus help scientists to better understand how to treat and control neuropathic pain.

Selank as Anticoagulant

Much research has been performed on the role of Selank in treatment and recovery of ischemic brain disease. Much of this research has focused on the role of Selank as a gene regulator and on its ability to enhance the process of neurogenesis. Como resulta, Selank may have other potential benefits in the setting of ischemic brain disease as well.

Animal studies have revealed that Selank (and Semax) can help to regulate the process of coagulation (coagulación de la sangre). Both peptides may help to maintain homeostasis in the coagulation cascade and offset the effects of both hypercoagulation (coagulación de la sangre) y, to a lesser extent, bleeding[6], [7]. Selank has shown early promise as an anti-coagulant. Though continued research is needed, this property may make Selank a potential dual therapeutic in the setting of stroke. En este caso, it could not only protect neurons against excitotoxic damage, but could protect them from disordered coagulation as well.

Supporting the observations that Selank is beneficial in hypercoagulable states is research in rat mesenteric vessels. This research shows that, in general, can help to prevent the microcirculation hypercoagulation that occurs in mesenteric vessels as a result of immobilization[8]. Tal como, glyprolines like Selank are of increasing interest for their ability to regulate coagulation cascades in the setting of prolonged immobilization common due to surgery or hospitalization. Blood clots following these cases are currently treated with heparin injections, which can shift the balance too far and lead to bleeding. The ability of Selank and other glyprolines to gently regulate coagulation without overcompensation and causing bleeding makes them very attractive as for the development of blood clot prophylactics.

N-Acetyl Selank Amidate as Nootropic

No discussion of Selank would be complete without exploring the potential of this peptide to enhance cognition. Extensive research has linked Selank to alterations in gene expression patterns in anxiety and coagulation. Additional research, in rats, reveals that nasal administration of Selank produces changes in mRNA levels for 36 different genes associated with plasma membrane function and ion-dependent learning and memory functions[9].

Rats treated with Selank show increased memory trace stability, which results in greater long-term retention of learning. Además, Selank appears to rescue memory and learning following brain damage and can restore cognitive processes in some circumstances. It is though that Selank can inhibit the catecholamine system in the brain, thereby offsetting what is known as excitotoxic neuron death. Excitotoxic neuron death is seen in a wide variety of conditions including head injury, drug overdose, and neurodegenerative diseases like Parkinson’s disease.

Selank administration in rats is associated with increases in levels of BDNF, a chemical messenger in the central nervous system that stimulates the growth and differentiation of neurons. Higher BDNF levels are associated with increased learning, improved memory, and reductions in the effects of neurological injury. Many nootropics have been found to alter BDNF expression patterns in the brain. The ability of N-Acetyl Selank Amidate to penetrate the BBB likely makes more readily it a more potent nootropic than standard Selank.

The Purpose of N-Acetylation

N-Acetyl Selank Amidate is similar in its effects to Selank, as already discussed, so it begs the question of why go to the trouble of modifying the original compound. N-acetylation is a common modification found in natural peptides, particularly peptides in eukaryotes. De hecho, most proteins in our bodies are N-acetylated. In yeast and humans, N-acetylation has multiple roles including

In synthetic chemistry, N-acetylation is used to alter the charge, hydrophobicity, and size of a protein. This can impact how long the protein lasts, where it localizes to in the body, and what receptors it binds to. In most cases, N-acetylation is done to prolong the half-life of a protein without affecting its overall function[11]. It is a relatively simple process, making it an affordable and well-known mechanism for improving the potency of a peptide.

The Purpose of Amidation

Amidation is another minor peptide modification, this time to the carboxyl group on the other end of the amino acid chain. Like N-acetylation, amidation is a natural process that occurs in up to half of all known peptides. Amidation makes peptides less sensitive to proteolytic degradation and extends their half-life in the blood stream. Amidated peptides are less sensitive to changes in pH and more easily bind to their receptors. They also bind more tightly to their target receptors, a feature that extends the effects of amidated proteins as compared to their non-amidated counterparts. Oxytocin, thyroid releasing hormone, and vasopressin are natural peptides in which amidation is known to greatly enhance biological activity[12].

In synthetic biology, amidation serves three major functions. Primero, amidation helps to protect orally administered peptides from the harsh environment in the stomach and GI tract. With a pH of less than 2, the environment of the stomach is a place that many peptides do not survive intact. The presence of an amide group helps proteins to pass through the stomach intact, which lowers the total amount of peptide that needs to be consumed to reach certain concentrations in the bloodstream.

The second reason that most synthetic peptides are amidated is to improve their potency after absorption. Amidated proteins not only survive longer in the bloodstream, they bind more tightly to their target receptors and produce enhanced signaling as a result[12]. This latter fact is particularly important for peptides that are active in the central nervous system, like Selank. Selank, while more effective than most compounds in penetrating the BBB, is still limited in its ability to enter the central nervous system. Having a higher potency allows the effects of the peptide in the CNS to be more robust.

Finalmente, amidation tends to alter the lipid solubility of a compound. While this isn’t as critical of a function as the two listed above, it is still the case that amidation increases lipid solubility and thus increases the amount of Selank crossing the BBB. Entonces, not only is amidated Selank more potent due to enhanced receptor binding, but more of it also reaches the receptors in the central nervous system. En este caso, the single step of amidation provides two distinct benefits that end up being synergistic.

N-Acetyl Selank Amidate: Resumen

N-Acetyl Selank Amidate is best thought of as an enhanced version of Selank. N-Acetyl Selank Amidate improves on every aspect of Selank by increasing its potency, half-life, absorbability, and the ease with which it crosses the blood-brain barrier. These features help to enhance the effects of Selank, which has been found in animal studies to protect the central nervous system from disease and trauma, reduce anxiety, improve learning, mejorar la memoria, and alter the process of blood clotting. While more research remains to be done, Selank and other glyprolines offer an insight into how DNA expression patterns can be altered by a single peptide to produce dramatic effects.

La literatura anterior fue investigada, editado y organizado por el Dr.. mi. logan, MARYLAND. Dr. mi. Logan tiene un doctorado de Facultad de Medicina de la Universidad Case Western Reserve y una licenciatura. en biología molecular.

The main research direction of Svetlana Limborska is molecular human genetics, including the study of the structural and functional organization of the genome, molecular genetic analysis of populations and the identification of the molecular basis of hereditary and socially important diseases including stroke. It was determined the molecular mechanisms of genomic alterations for a number of human diseases, including hemoglobinopathies, thalassemia, myodystrophy, torsion dystonia, Enfermedad de Parkinson, Wilson’s disease and others; it was discovered a family of hypervariable DNAs, which were universally distributed in the genomes of all living organisms and were found to be suitable for both the personal identification and kinship purposes; some new brain-specific human genes were found and characterized, and it was identified wide-scale changes in the transcriptome of nerve cells after ischemia and under the action of peptide drugs.

Dr. Svetlana Limborska is being referenced as one of the leading scientists involved in the research and development of Cardiogen. De ninguna manera este médico/científico respalda o defiende la compra, venta, o uso de este producto por cualquier motivo. No hay afiliación o relación., implícito o no, entre

1. A. Volkova et al. “La administración de Selank afecta la expresión de algunos genes implicados en la neurotransmisión GABAérgica," Frente. farmacología., volumen. 7, pag. 31, Feb. 2016, doi: 10.3389/fphar.2016.00031.
2. A. Kasian et al. “La administración de Selank afecta la expresión de algunos genes implicados en la neurotransmisión GABAérgica," Frente. farmacología., volumen. 7, pag. 31, Feb. 2016, doi: 10.3389/fphar.2016.00031.
3. z. V. Bakaeva et al., “Glyprolines exert protective and repair-promoting effects in the rat stomach: potential role of the cytokine GRO/CINC-1,” j. fisiol. farmacología. Apagado. j. Pol. fisiol. sociedad. volumen. 2017, pag. 5091027, 2017, doi: 10.1155/2017/5091027.
4. “Efectos inmunomoduladores de selank en pacientes con trastornos de ansiedad-asténicos” oh. norte. Uchakina et al., “[Efectos inmunomoduladores de selank en pacientes con trastornos de ansiedad-asténicos]," zh. neurol. Psikhiatr. Soy. S. S. Korsakov, volumen. 108, No. 5, páginas. 71–75, 2008.
5. A. A. Zozulia et al., “Efficacy and possible mechanisms of action of a new peptide anxiolytic selank in the therapy of generalized anxiety disorders and neurasthenia," zh. neurol. Psikhiatr. Soy. S. S. Korsakov, volumen. 108, No. 4, páginas. 38–48, 2008.
6. l. A. Liapina, V. mi. Pastorova, t. I. Obergan, GRAMO. mi. Samonina, I. PAG. Ashmarin, y norte. F. Miasoedov, “Comparison of anticoagulant effects of regulatory proline-containing oligopeptides. Specificity of glyprolines, semax, and selank and potential of their practical application," Asociación. Contrato. Ciencia. Ser. biol., No. 2, páginas. 193–203, Abr. 2006.
7. l. A. Liapina, V. mi. Pastorova, t. I. Obergan, GRAMO. mi. Samonina, I. PAG. Ashmarin, y norte. F. Miasoedov, “Comparison of anticoagulant effects of regulatory proline-containing oligopeptides. Specificity of glyprolines, semax, and selank and potential of their practical application,"
8. GRAMO. norte. Kopylova, mi. A. Smirnova, l. t. Sanzhieva, B. A. Umarova, t. V. Lelekova, y G. mi. Samonina, “Glyprolines and semax prevent stress-induced microcirculatory disturbances in the mesentery," Toro. Exp. biol. Con., volumen. 136, No. 5, páginas. 441–443, Nov. 2003, doi: 10.1023/b:bebé.0000017087.90585.a9.
9. t. A. Kolomin et al., “Transcriptome alteration in hippocampus under the treatment of tuftsin analog Selank," zh. Vysh. Nervio. Dios. Soy. I. PAG. Pávlova, volumen. 63, No. 3, páginas. 365–374, Jun. 2013, doi: 10.7868/s0044467713030052.
10. mi. Linster and M. Wirtz, “N-terminal acetylation: an essential protein modification emerges as an important regulator of stress responses," j. Exp. Bot., volumen. 69, No. 19, páginas. 4555–4568, Ago. 2018, doi: 10.1093/jxb/ery241.
11. R. Ree, S. Varland, y T. Arnesen, “Spotlight on protein N-terminal acetylation," Exp. Mol. Con., volumen. 50, No. 7, páginas. 1–13, Jul. 2018, doi: 10.1038/s12276-018-0116-z.
12. “Amidation – una visión general | Temas de ScienceDirect”. https://www.sciencedirect.com/topics/engineering/amidation.

TODOS LOS ARTÍCULOS E INFORMACIÓN DE PRODUCTOS PROPORCIONADOS EN ESTE SITIO WEB SON SÓLO PARA FINES INFORMATIVOS Y EDUCATIVOS.

Los productos ofrecidos en este sitio web se proporcionan únicamente para estudios in vitro.. Estudios in vitro (latín: en cristal) se realizan fuera del cuerpo. Estos productos no son medicamentos ni fármacos y no han sido aprobados por la FDA para prevenir, tratar o curar cualquier condición médica, dolencia o enfermedad. La introducción corporal de cualquier tipo en personas o animales está estrictamente prohibida por la ley..