Thickness Of Molecular Layer Research Articles

(Invited) Interfacial Coupling between Nanostructures and Molecular Chromophores

The combination of nanostructures with molecular chromophores offers new opportunities to control excited-state photophysics and photochemistry for several potential applications and has fundamental interest for tuning the exciton states that lie at the interface. Semiconductor quantum dots (QDs) are naturally decorated with molecular ligands that can be exchanged for those with tailored properties. We have chosen polyacene ligands with the potential to create and shuttle triplet photoexcited states across the surface of the PbS QDs with tunable rates and efficiencies. Changing the tetracene orientation and packing density with respect to the surface alters the states involved and the rate of energy/charge transfer. The mechanism of this process is unclear, and we present a systematic control of key variables to elucidate the important features of the hybrid system. We find transfer times varying from femtoseconds to nanoseconds, depending on the extent of coupling at the interfaces.Similarly, two-dimensional materials such as transition metal dichalcogenides (TMDCs) can be combined with molecules to provide intimate contact between the two species. The molecular layer can influence the properties of the TMDC, including altering the exciton population and spin-valley relaxation time. Through control of a molecular layer thickness (i.e., vanadyl phthalocyanine) deposited onto monolayer tungsten diselenide (WSe2), we discover that hybrid exciton states undergo ultrafast decoherence if molecular layers are less than 10 nm thick. Thicker layers produce slower spin-valley relaxation, presumably through exciton dissociation that reduces exchange coupling but without hybridization that destroys the initial spin character in the WSe2. We further characterize this effect through temperature dependence and a suite of spectroscopic and structural experiments.

Laminar Architecture and Morphometry of Developing Human Fetal Cerebellum

Abstract Background: One of the organs in the human fetus that starts to differentiate extremely early and keeps doing so throughout the postnatal period is the cerebellum. The goal of this study was to create a nomogram using the chronological events that were occurring and the relationship with progressing gestational age. Granule cells and Purkinje cells play a crucial role in the normal development of the cerebellum. Any disruption at the cellular level can lead to abnormal migration of these cells, potentially resulting in hypoplasia of the cerebellar vermis. Methodology: Tissue specimens from 60 human fetuses were studied for histological changes after being grouped into four from 13th week to 32nd week. Fetuses with any neurological deficit were excluded from the study. Different layers were identified, and the thickness of each layer was noted. Results: The first two groups had three layers, but the composition was different in both. The marginal and mantle layers in the second group disappeared completely. The third group showed presence of five layers, with addition of lamina dissecans, appearing for a transient period. The fourth group had four layers. The thickness of external granular layer and internal granular layer (IGL) increased throughout, except that the IGL made an appearance from the second group only. Lamina dissecans appeared, causing a significant shift between 23 and 27 weeks. The fetus has a four-layered structure near term, with an external granular layer persisting throughout the early postnatal stage of life. Progression of pregnancy was positively connected with the molecular and Purkinje cell layer (PCL) thickness. Conclusion: Progression of pregnancy was positively connected with the molecular and PCL thickness. Age determination and neuropsychiatric disorders of the developing fetus may benefit from such a link.

Atomic imaging and optical properties of InAs/In0.5Ga0.5As0.5Sb0.5 type II superlattice

High-quality III–V quantum structures, advanced epitaxial technologies, and characterization methods are essential to drive the development of infrared optoelectronic materials and devices. As an important component of type II superlattices, InAs/InxGa1−xAsySb1−y would play an important role in the field of high-performance infrared detectors due to their excellent luminescence efficiency and high crystal quality. However, their interfacial characteristics and the associated minority carrier lifetime are still difficult to identify. In this paper, an atomic imaging technique was used to identify the arrangement and distribution of elements of the InAs/In0.5Ga0.5As0.5Sb0.5 superlattice. Our results confirm the epitaxy mechanism that the quaternary alloy consists of two kinds of ternary alloy in one monolayer. Moreover, by separating the cation and anion columns in the elementally resolved atomic images of the InAs/In0.5Ga0.5As0.5Sb0.5 superlattice, we demonstrate that the interfacial atomic intermixing is less than one molecular layer thickness. Therefore, benefiting from excellent interface quality, InAs/In0.5Ga0.5As0.5Sb0.5 superlattice exhibited high radiation recombination efficiency in the long-wave infrared band (∼8.5 μm), and longer minority carrier lifetime (∼810 ns at 90 K).

Theoretical Study of Strong Coupling between Molecular Shells and Chiral Plasmons of Gold Nanoparticles Helices.

Chiral plasmonic nanostructures can produce strong chiral optical responses and have potential applications in photonics. Experimentally, metallic nanoparticle helices have been synthesized to achieve strong chiral responses. Strong coupling effects between the quantum emitters and the plasmon have attracted significant attention in the past decade and have been recently extended to the chiral plasmon of nanostructures. However, the strong coupling between molecules and metallic nanosphere helices has not been reported yet. In this article we study theoretically such an effect and examine the modulation of chiral and coupling effects by illumination light and molecular layer thickness. Our study may guide further experimental studies.

Ameliorative effect of Vitis gracilis leaf decoction against sensory and motoric disorders, oxidative stress, and cerebellar degeneration in diabetic mice

Vitis gracilis (Vitaceae) is a potent medicinal plant, but its effectiveness in counteracting neuronal issues due to diabetes is uncertain. This study aimed to investigate whether the leaf decoction of V. gracilis could manage sensory and motoric disorders, oxidative stress, and cerebellar degeneration caused by diabetes mellitus. Twenty-five adult male mice were divided into five treatment groups: non-diabetic (non-DM), diabetic (alloxan-induced diabetes mellitus; DM), and DM treated with V. gracilis leaf decoction at doses of 25 g/l (DM + 25 g/l VgD), 50 g/l (DM + 50 g/l VgD), or 100 g/l (DM + 100 g/l VgD). The decoction was administered orally for 30 days. The results showed that V. gracilis leaf decoction did not significantly lower blood glucose levels or improve insulin tolerance in diabetic mice (p > 0.05). However, it substantially maintained sensory response and motoric balance and reduced malondialdehyde levels in brain tissue, especially at a 100 g/l dose (p < 0.05). Moreover, higher decoction doses alleviated histopathological alterations in the cerebellum by significantly preserving molecular and granular layer thickness while reducing degenerated Purkinje cells (p < 0.05). In conclusion, despite its inability to manage hyperglycemia, the decoction effectively improved sensory and motoric function, reduced oxidative stress, and mitigated cerebellar histopathological changes. Therefore, V. gracilis could be an alternative treatment for diabetes-related neurological disorders.

Diversity and evolution of cerebellar folding in mammals.

The process of brain folding is thought to play an important role in the development and organisation of the cerebrum and the cerebellum. The study of cerebellar folding is challenging due to the small size and abundance of its folia. In consequence, little is known about its anatomical diversity and evolution. We constituted an open collection of histological data from 56 mammalian species and manually segmented the cerebrum and the cerebellum. We developed methods to measure the geometry of cerebellar folia and to estimate the thickness of the molecular layer. We used phylogenetic comparative methods to study the diversity and evolution of cerebellar folding and its relationship with the anatomy of the cerebrum. Our results show that the evolution of cerebellar and cerebral anatomy follows a stabilising selection process. We observed two groups of phenotypes changing concertedly through evolution: a group of 'diverse' phenotypes - varying over several orders of magnitude together with body size, and a group of 'stable' phenotypes varying over less than 1 order of magnitude across species. Our analyses confirmed the strong correlation between cerebral and cerebellar volumes across species, and showed in addition that large cerebella are disproportionately more folded than smaller ones. Compared with the extreme variations in cerebellar surface area, folial anatomy and molecular layer thickness varied only slightly, showing a much smaller increase in the larger cerebella. We discuss how these findings could provide new insights into the diversity and evolution of cerebellar folding, the mechanisms of cerebellar and cerebral folding, and their potential influence on the organisation of the brain across species.

Molecular layer modulation of two-dimensional organic ferroelectric transistors

Ferroelectric transistors hold great potential in low consumption devices. Due to the high film quality and clean system, two dimensional organic semiconductors are widely employed to fabricate high performance organic electronic devices and explore the modulation mechanism of the molecular packing on device performance. Here, we combine the ferroelectric hafnium oxide HfZrO x and two-dimensional molecular crystal 2,9-didecyldinaphtho[2,3-b:2′,3′-f]thieno[3,2b]thiophene (C10-DNTT) with controllable layers to study the molecular layer modulation of ferroelectric organic thin-film transistors (OTFTs). The contact resistance, driving current and transconductance are directly affected by the additional access resistance across the upper molecular layers at the source/drain contact region. Simultaneously, the capacitance of Schottky junction related to the molecular layer thickness could effectively adjust the gate potential acting on the organic channel, further controlling the devices’ subthreshold swing and transconductance efficiency. This work would promote the development of low voltage and high performance OTFTs.

Tunable Molecular Electrodes for Bistable Polarization Screening.

The polar discontinuity at any ferroelectric surface creates a depolarizing field that must be screened for the polarization to be stable. In capacitors, screening is done by the electrodes, while in bare ferroelectric surfaces it is typically accomplished by atmospheric adsorbates. Although chemisorbed species can have even better screening efficiency than conventional electrodes, they are subject to unpredictable environmental fluctuations and, moreover, dominant charged species favor one polarity over the opposite. This paper proposes a new screening concept, namely surface functionalization with resonance-hybrid molecules, which combines the predictability and bipolarity of conventional electrodes with the screening efficiency of adsorbates. Thin films of barium titanate (BaTiO3 ) coated with resonant para-aminobenzoic acid (pABA) display increased coercivity for both signs of ferroelectric polarization irrespective of the molecular layer thickness, thanks to the ability of these molecules to swap between different electronic configurations and adapt their surface charge density to the screening needs of the ferroelectric underneath. Because electron delocalization is only in the vertical direction, unlike conventional metals, chemical electrodes allow writing localized domains of different polarity underneath the same electrode. In addition, hybrid capacitors composed of graphene/pABA/ferroelectric have been made with enhanced coercivity compared to pure graphene-electodecapacitors.

Hierarchical Nanoarchitectonics of Ultrathin 2D Organic Nanosheets for Aqueous Processed Electroluminescent Devices.

Ultrathin 2D organic nanosheets (2DONs) with high mobility have received tremendous attention due to thickness of few molecular layers. However, ultrathin 2DONs with high luminescence efficiency and flexibility simultaneously are rarely reported. Here, the ultrathin 2DONs (thickness: 19nm) through the modulation of tighter molecular packing (distance: ≈3.31Å) achievable from the incorporation of methoxyl and dipenylamine (DPA) groups into 3D spirofluorenexanthene (SFX) building blocks is successfully prepared. Even with closer molecular stacking, ultrathin 2DONs still enable the suppression of aggregation quenching to exhibit higher quantum yields of blue emission (ΦF = 48%) than that on amorphous film (ΦF = 20%), and show amplified spontaneous emission (ASE) with a mediate threshold (332mWcm-2 ). Further, through drop-casting method, the ultrathin 2DONs are self-organized into large-scale flexible 2DONs films (1.5 × 1.5cm) with the low hardness (H: 0.008Gpa) and low Young's modulus (Er : 0.63Gpa). Impressively, the large-scale 2DONs film can realize electroluminescence performances with a maximum luminance (445cdm-2 ) and low turn on voltage (3.7V). These ultrathin 2DONs provide a new avenue for the realization of flexible electrically pumping lasers and intelligent quantum tunneling systems.

WWOX P47T partial loss-of-function mutation induces epilepsy, progressive neuroinflammation, and cerebellar degeneration in mice phenocopying human SCAR12

WWOX gene loss-of-function (LoF) has been associated with neuropathologies resulting in developmental, epileptic, and ataxic phenotypes of varying severity based on the level of WWOX dysfunction. WWOX gene biallelic germline variant p.Pro47Thr (P47T) has been causally associated with a new form of autosomal recessive cerebellar ataxia with epilepsy and intellectual disability (SCAR12, MIM:614322). This mutation affecting the WW1 protein binding domain of WWOX, impairs its interaction with canonical proline-proline-X-tyrosine motifs in partner proteins. We generated a mutant knock-in mouse model of Wwox P47T mutation that phenocopies human SCAR12. WwoxP47T/P47T mice displayed epilepsy, profound social behavior and cognition deficits, and poor motor coordination, and unlike KO models that survive only for 1 month, live beyond 1 year of age. These deficits progressed with age and mice became practically immobile, suggesting severe cerebellar dysfunction. WwoxP47T/P47T mice brains revealed signs of progressive neuroinflammation with elevated astro-microgliosis that increased with age. Cerebellar cortex displayed significantly reduced molecular and granular layer thickness and a strikingly reduced number of Purkinje cells with degenerated dendrites. Transcriptome profiling from various brain regions of WW domain LoF mice highlighted widespread changes in neuronal and glial pathways, enrichment of bioprocesses related to neuroinflammation, and severe cerebellar dysfunction. Our results show significant pathobiological effects and potential mechanisms through which WWOX partial LoF leads to epilepsy, cerebellar neurodegeneration, neuroinflammation, and ataxia. Additionally, the mouse model described here will be a useful tool to understand the role of WWOX in common neurodegenerative conditions in which this gene has been identified as a novel risk factor.

Study of the Micromechanism of the Effect of Fatty Alcohol Poly(oxyethylene) Ether-9 on the Wettability of Jincheng Anthracite

The influence mechanism of the adsorption of fatty alcohol poly(oxyethylene) ether (AEO9) on the wettability of anthracite coal was studied by means of experiments and simulations. First, the contact angle and surface tension were measured. When the AEO9 concentration was 0.5 wt %, the contact angle and surface tension were the smallest, which were 10.28° and 25.39 mN m-1, respectively. X-ray photoelectron spectroscopy (XPS) indicated that the content of C-O functional groups on the anthracite surface increased by 20.76% after adsorption of AEO9. The molecular orbital energy and electrostatic potential of AEO9 and anthracite were calculated by density functional theory (DFT). There are two modes of electron transfer between the two orbitals: highest occupied molecular orbital (HOMO) transfer of AEO9 to lowest unoccupied molecular orbital (LUMO) transfer of anthracite and HOMO transfer of anthracite to LUMO transfer of AEO9. The dynamics simulation results show that the addition of AEO9 increases the migration rate of water molecules, promotes the movement of a large number of water molecules toward the surface of anthracite, and enhances the thickness of the water molecular layer on the surface of anthracite. The analysis of the relative concentration shows that AEO9 is distributed at the anthracite/water interface. AEO9 molecules are intertwined and connected by hydrophobic chains to form a network structure, which covers the anthracite surface horizontally, thus promoting the strength of the anthracite/water interaction.

Carbon-Based Molecular Junctions for Practical Molecular Electronics.

The field of molecular electronics has grown rapidly since its experimental realization in the late 1990s, with thousands of publications on how molecules can act as circuit components and the possibility of extending microelectronic miniaturization. Our research group developed molecular junctions (MJs) using conducting carbon electrodes and covalent bonding, which provide excellent temperature tolerance and operational lifetimes. A carbon-based MJ based on quantum mechanical tunneling for electronic music represents the world's first commercial application of molecular electronics, with >3000 units currently in consumer hands. The all-carbon MJ consisting of aromatic molecules and oligomers between vapor-deposited carbon electrodes exploits covalent, C-C bonding which avoids the electromigration problem of metal contacts. The high bias and temperature stability as well as partial transparency of the all-carbon MJ permit a wide range of experiments to determine charge transport mechanisms and observe photoeffects to both characterize and stimulate operating MJs. As shown in the Conspectus figure, our group has reported a variety of electronic functions, many of which do not have analogs in conventional semiconductors. Much of the described research is oriented toward the rational design of electronic functions, in which electronic characteristics are determined by molecular structure.In addition to the fabrication of molecular electronic devices with sufficient stability and operating life for practical applications, our approach was directed at two principal questions: how do electrons move through molecules that are components of an electronic circuit, and what can we do with molecules that we cannot do with existing semiconductor technology? The central component is the molecular junction consisting of a 1-20+ nm layer of covalently bonded oligomers between two electrodes of conducting, mainly sp2-hybridized carbon. In addition to describing the unique junction structure and fabrication methods, this Account summarizes the valuable insights available from photons used both as probes of device structure and dynamics and as prods to stimulate resonant transport through molecular orbitals.Short-range (<5 nm) transport by tunneling and its properties are discussed separately from the longer-range transport (5-60 nm) which bridges the gap between tunneling and transport in widely studied organic semiconductors. Most molecular electronic studies deal with the <5 nm thickness range, where coherent tunneling is generally accepted as the dominant transport mechanism. However, the rational design of devices in this range by changing molecular structure is frustrated by electronic interactions with the conducting contacts, resulting in weak structural effects on electronic behavior. When the molecular layer thickness exceeds 5 nm, transport characteristics change completely since molecular orbitals become the conduits for transport. Incident photons can stimulate transport, with the observed photocurrent tracking the absorption spectrum of the molecular layer. Low-temperature, activationless transport of photogenerated carriers is possible for up to at least 60 nm, with characteristics completely distinct from coherent tunneling and from the hopping mechanisms proposed for organic semiconductors. The Account closes with examples of phenomena and applications enabled by molecular electronics which may augment conventional microelectronics with chemical functions such as redox charge storage, orbital transport, and energy-selective photodetection.

Natural Clinoptilolite Nanoparticles Coated with Phosphatidylcholine.

A nanocarrier was obtained by coating the natural clinoptilolite particle surface with a phosphatidylcholine layer. The shell effective size does not exceed the thickness of the phospholipid molecular layer, which was confirmed by UV spectrometry and molecular mass spectrometry. The hydrodynamic diameter of the formulated nanocarrier, which was determined by dynamic light scattering, is smaller than the clinoptilolite core size. This effect is assumed to be caused by the phospholipid shell, which reduces the aqueous medium friction. The nanosize of the formulated nanocarrier, the natural clinoptilolite core, and the phospholipid shell together allow a combination of fruitful features that can be used for the fabrication of multifunctional platforms for the delivery of biologically active substances, bioimaging, or as a basis for biosensors.

Endothelial Rbpj Is Required for Cerebellar Morphogenesis and Motor Control in the Early Postnatal Mouse Brain.

Intercellular influences are necessary for coordinated development and function of vascular and neural components in the brain. In the early postnatal period after birth, the mammalian cerebellum undergoes extensive morphogenesis - developing its characteristic lobules, organizing its diverse cell types into defined cellular layers, and establishing neural circuits that support cerebellar function, such as coordinated movement. In parallel, the cerebellar vasculature undergoes extensive postnatal growth and maturation, keeping pace with the expanding neural compartment. Endothelial deletion of Rbpj leads to neurovascular abnormalities in mice, including arteriovenous (AV) shunts that supplant capillaries and instead direct high-pressure/high-flow arterial blood directly to veins. Gross and histopathological cerebellar abnormalities, associated with these Rbpj-mediated brain AV malformations (AVMs), led to our hypothesis that early postnatal morphogenesis and lamination of cerebellum was perturbed in mice harboring endothelial Rbpj deficiency from birth. Here, we show that endothelial Rbpj-mutant mice developed enlarged vascular malformations on the cerebellar surface, by 2-week post-Rbpj deletion. In addition, outgrowth of cerebellar lobules was impaired through decreased cell proliferation, but not increased apoptosis, in the external granule layer. Molecular layer thickness was reduced, and the Purkinje layer was affected, by decreased Purkinje cell number, primary dendrite length, and dendritic arbor density. Endothelial deletion of Rbpj also led to impaired motor behaviors, consistent with abnormal cerebellar morphogenesis and lamination. Thus, our data suggest that Rbpj is required, in early postnatal vascular endothelium, to ensure proper cerebellar outgrowth, morphogenesis, and function in mice.

Single Molecular Layer of Chitin Sub-Nanometric Nanoribbons: One-Pot Self-Exfoliation and Crystalline Assembly into Robust, Sustainable, and Moldable Structural Materials.

Sub‐nanometric materials (SNMs) represent a series of unprecedented size‐/morphology‐related properties applicable in theoretical research and diverse cutting‐edge applications. However, in‐depth investigation and wide utilization of organic SNMs are frequently hindered, owing to the complex synthesis procedures, insufficient colloidal stability, poor processability, and high cost. In this work, a low‐cost, energy‐efficient, convenient, effective, and scalable method is demonstrated for directly exfoliating chitin SNMs from their natural sources through a one‐pot “tandem molecular intercalation” process. The resultant solution‐like sample, which exhibits ribbon‐like feature and contains more than 85% of the single molecular layer (thickness <0.6 nm), is capable of being solution‐processed to different types of materials. Thanks to the sub‐nanometric size and rich surface functional groups, chitin SNMs reveal versatile intriguing properties that rarely observe in their nano‐counterparts (nanofibrils), e.g., crystallization‐like assembly in the colloidal state and alcoplasticity/self‐adhesiveness in the bulk aggregate state. The finding in this work not only opens a new avenue for the high value‐added utilization of chitin, but also provides a new platform for both the theoretical study and practical applications of organic SNMs.

Evaluating the Effects of Aloe vera Gel on Cerebellum Histomorphometrical Changes in Diabetic Male Rats

Background: Diabetes mellitus can lead to histomorphometrical changes in the brain. Recent studies have shown that Aloe vera gel has antioxidant and neuroprotective effects, which is independent of glucose-lowering effects. Objectives: The present study aimed to investigate the effects of A. vera gel on histomorphometrical changes of cerebellum following streptozotocin (STZ)-induced diabetic male rats. Methods: A total of 25 male Wistar rats were randomly allocated into five groups as follows: (1) the control group received normal saline; (2) A. vera gel group; (3) diabetic group; (4) treatment group diabetic rats, which received A. vera; and (5) diabetic rats which received insulin. A single dose of STZ [60 mg/kg; intraperitoneal (IP)] was used for the induction of diabetes in rats. All the treatments were administered daily for eight weeks. Subsequently, histomorphometrical changes were evaluated in the cerebellum of the rats. Results: The results showed that the number of granular and purkinje cells reduced in the cerebellum granulosa region, while the number of glial cells increased in the molecular region of the cerebellum in diabetic rats compared to the control group (P &lt; 0.05). These changes were improved in treated rats by insulin or A. vera. Also, the thickness of molecular, purkinje, granular, and white matter layers at the apex of lobules and depth of sulcus in the diabetic group had a significant reduction compared to other groups (P &lt; 0.001). Conclusions: Our results confirmed that improvement of the cerebellar tissue changes in diabetic rats following the use of A. vera gel is comparable to insulin. However, more investigations are required to determine the protective effects of A. vera gel against diabetes-induced cerebellum histomorphometrical changes.

Apoptosis is involved in paraoxon-induced histological changes in rat cerebellum

Acute toxicity of organophosphorus compounds is primarily caused by inhibition of acetylcholinesterase (AChE) at cholinergic synapses. The current study was designed to investigate the effects of paraoxon on histological changes as well as the role of mitochondrion-dependent apoptosis in causing this damage in the rat cerebellum. Adult male Wistar rats were intraperitoneally injected with paraoxon at 0.3, 0.7, or 1 mg/kg. Control animals were injected with corn oil as a vehicle. At 14 or 28 days after intoxication, histological changes and alterations in the expression of apoptosis-related proteins, including Bax, Bcl-2, and caspase-3, were investigated in the cerebellum using cresyl violet staining and western blotting, respectively. Findings showed the decreased thickness of both molecular and granular layers and reduction in the number of Purkinje cells in animals treated with a higher convulsive dose of paraoxon (1 mg/kg). In addition, exposure of rats to 1 mg/kg of paraoxon activated apoptosis pathway confirmed by an increase in Bax and caspase-3 and a decrease in Bcl-2 protein levels. According to our results, cerebellar histological changes and alterations in the expression of apoptosis-related proteins occur following exposure to a high convulsive dose of paraoxon and persist for a long time.

Documented Lipid Per oxidative Intoxication of Cerebellar Molecular Cell Layer

Background: Cerebellar cortexconsists of three layers. The outer molecular, middlePurkinje cell layer, inner granule cell layer. Lithium the alkali metal hasdeleterious effects on nervous tissue and this study proved the injurious effects of lithium on molecular cell layer of cerebellum. Aim: To observe and report the damaging histological and morphological change of the decrement in the thickness of cerebellar molecular layer by Lithium. Methods: This study was designed to observe the microscopic changes of thickness of molecular layer in rat cerebellum. For this experimental study 12 animals were used, they were divided into two groups, each comprising of 6 animals. Results: Group-A received normal lab diet and water ad libitum while group B received injectable lithium carbonate 20 mg/kg/ for 4 weeksrespectively. Micrometry was done and changes of the thickness of molecular cell layer were recorded and documented. Conclusion: The pernicious effects of Lithium Carbonate on molecular cerebellar cortex were visualized and evaluated .Highly significantly decreased changes of thickness of molecular cell layer were documented in rat cerebellum. Keywords: Lipidperoxidation,Molecular cell layeratrophy, decomposition

Ameliorarting Action of Methylcaobalamin on Degenerated Cerebellar Molecular Cell Layer

Background: Cerebellum the hindbrain is located in the posterior cranial fossa.The cerebellar cortex consists, of a gray matter and a white matter and the gray matter comprises of outer molecular layer, middle purkinje cell layer and inner most is the granule cell layer. The antimaniac drug lithium caused distortion to the outer molecular cell layer which was repaired and the damage was lessened by injecting the albino rats with Methylcobalamin. Aim: To observe and document the data of the restored thickness of molecular cell layer after Methylcobalamin administration. Methods: Eighteen albino rats were selected and were treated with lithium and Methylcobalamin for a period of 4 weeks. Results: The results showed regeneration and improved thickness of molecular cell layer stressing the need for educating our masses in dietary use of vitamin b12 and the consultants to prescribe Methylcobalamin in neuronal injuries. Conclusion: My study proved that the use of vitamin b12 is mandatory in strengthening and restoring the cerebellar molecular gray matter. Keywords: Cerebellar molecular cell layer,Degeneration, Regeneration

Neuroprotective Metabolites of Hericium erinaceus Promote Neuro-Healthy Aging.

Frailty is a geriatric syndrome associated with both locomotor and cognitive decline, typically linked to chronic systemic inflammation, i.e., inflammaging. In the current study, we investigated the effect of a two-month oral supplementation with standardized extracts of H. erinaceus, containing a known amount of Erinacine A, Hericenone C, Hericenone D, and L-ergothioneine, on locomotor frailty and cerebellum of aged mice. Locomotor performances were monitored comparing healthy aging and frail mice. Cerebellar volume and cytoarchitecture, together with inflammatory and oxidative stress pathways, were assessed focusing on senescent frail animals. H. erinaceus partially recovered the aged-related decline of locomotor performances. Histopathological analyses paralleled by immunocytochemical evaluation of specific molecules strengthened the neuroprotective role of H. erinaceus able to ameliorate cerebellar alterations, i.e., milder volume reduction, slighter molecular layer thickness decrease and minor percentage of shrunken Purkinje neurons, also diminishing inflammation and oxidative stress in frail mice while increasing a key longevity regulator and a neuroprotective molecule. Thus, our present findings demonstrated the efficacy of a non-pharmacological approach, based on the dietary supplementation using H. erinaceus extract, which represent a promising adjuvant therapy to be associated with conventional geriatric treatments.