Neuronal in a sentence

(1) Astrocytes can modulate neuronal activity.

(2) The neurons interlock around the neuronal synapse.

(3) Calmodulin is essential for proper neuronal function.

(4) Actin dynamics are important for neuronal development.

(5) Neuroglia can respond to changes in neuronal activity.

(6) ATP is used by the brain to maintain neuronal activity.

(7) Gray matter is densely packed with neuronal connections.

(8) Dysfunction of macroglia can disrupt neuronal signaling.

(9) Astrocytic signaling can modulate neuronal excitability.

(10) The function of Gaba is to reduce neuronal excitability.

Neuronal sentence

(11) Modulate calcium signaling to control neuronal activity.

(12) Ganglioside can influence neuronal growth and plasticity.

(13) The cyton plays a crucial role in neuronal communication.

(14) The neuropil is densely packed with neuronal connections.

(15) Astrocytic calcium signaling regulates neuronal activity.

(16) The synapses interlock across the neuronal communication.

(17) Grey matter is primarily composed of neuronal cell bodies.

(18) The neuropile is densely packed with neuronal connections.

(19) Neurite sprouting is a common response to neuronal injury.

(20) Phosphorylated proteins are involved in neuronal signaling.

Neuronal make sentence

(21) Synaptosomes are sensitive to changes in neuronal activity.

(22) Damage to axoplasms can lead to impaired neuronal function.

(23) Ankyrin is involved in the maintenance of neuronal polarity.

(24) Examine the effects of eicosanoids on neuronal excitability.

(25) Axonic transport is crucial for maintaining neuronal health.

(26) The cell body plays a crucial role in neuronal communication.

(27) Astrocytes can release molecules that promote neuronal growth.

(28) The axolemma is involved in the process of neuronal migration.

(29) Neuronal firing patterns can be disrupted by genetic mutations.

(30) Neuropeptide signaling is important for neuronal communication.

Sentence of neuronal

(31) Neurotrophic factors are known to regulate neuronal plasticity.

(32) Neurites can undergo sprouting to compensate for neuronal loss.

(33) Microtubular organization is critical for neuronal development.

(34) The cytoskeletal network is essential for neuronal development.

(35) Neuroglia can undergo changes in response to neuronal activity.

(36) Axoplasms are essential for the process of neuronal plasticity.

(37) Damage to neurogliacytes can lead to impaired neuronal function.

(38) Antidromically activated neurons can modulate neuronal activity.

(39) Microglia can release growth factors to support neuronal repair.

(40) The accumulation of amyloid plaque can impair neuronal function.

Neuronal meaningful sentence

(41) Neuronal oscillations play a role in coordinating brain activity.

(42) The cell body is involved in the regulation of neuronal activity.

(43) The dysfunction of glial cells can impair neuronal communication.

(44) The neuropile is composed of densely packed neuronal cell bodies.

(45) The axonal sprouting was observed in response to neuronal injury.

(46) Dysfunction of dynein can lead to defects in neuronal development.

(47) Neuropeptides can have long-lasting effects on neuronal signaling.

(48) Glial cells can release chemicals that modulate neuronal activity.

(49) Phosphatases are involved in the regulation of neuronal signaling.

(50) The cell body plays a role in the regulation of neuronal activity.

Neuronal sentence examples

(51) The neurite exhibited dynamic changes during neuronal development.

(52) The hyperpolarizing effect of the drug dampened neuronal activity.

(53) Myosins are important for the development of neuronal connections.

(54) The microvolt reading provided evidence of neuronal communication.

(55) The axonal growth cone guides the extension of neuronal processes.

(56) Neurite formation is a key step in establishing neuronal circuits.

(57) Axoplasms are essential for the process of neuronal communication.

(58) Axoplasms are involved in the process of neuronal differentiation.

(59) The neuronal architecture of the human brain is incredibly complex.

(60) The monitor glycoprotein is essential for proper neuronal function.

Sentence with neuronal

(61) Gaba receptors play a crucial role in inhibiting neuronal activity.

(62) Astrocytic dysfunction can lead to impaired neuronal communication.

(63) Athrocytes are involved in the regulation of neuronal excitability.

(64) Damage to the neuronal pathways can result in cognitive impairments.

(65) Neuronal firing rates can be modulated by various neurotransmitters.

(66) Neuronal dysfunction can result in a range of psychiatric disorders.

(67) The study investigates the role of isoforms in neuronal development.

(68) The quantal release of GABA inhibits neuronal activity in the brain.

(69) Phosphorylating is involved in the regulation of neuronal signaling.

(70) Antidromically activated neurons can modulate neuronal firing rates.

Use neuronal in a sentence

(71) The synaptic vesicle plays a crucial role in neuronal communication.

(72) The hyperpolarizing effect of the drug suppressed neuronal activity.

(73) Astrocyte signaling is important for coordinating neuronal activity.

(74) Damage to the axoplasmic membrane can disrupt neuronal communication.

(75) Neuronal firing patterns can be disrupted by certain drugs or toxins.

(76) Synaptosomes are involved in the regulation of neuronal excitability.

(77) Downregulation of certain ion channels can affect neuronal signaling.

(78) Neuroglial cells are involved in the modulation of neuronal activity.

(79) Astrocytes can release growth factors that promote neuronal survival.

(80) The integrity of axolemmas is essential for proper neuronal function.

Sentence using neuronal

(81) TRP proteins are involved in the regulation of neuronal excitability.

(82) Gangliosides are involved in the regulation of neuronal excitability.

(83) Neuronal regeneration holds promise for treating spinal cord injuries.

(84) The perikaryon is involved in the regulation of neuronal excitability.

(85) The study of axoplasms has revealed insights into neuronal plasticity.

(86) The sample glycoprotein was found to be expressed in neuronal tissues.

(87) Dephosphorylation is involved in the regulation of neuronal signaling.

(88) The neuromodulator can have long-lasting effects on neuronal activity.

(89) The axonal transport system plays a crucial role in neuronal function.

(90) Gangliosides are important for the maintenance of neuronal plasticity.

Neuronal example sentence

(91) Dysfunction in the neuronal network can lead to neurological disorders.

(92) Hyperpolarize the membrane potential to decrease neuronal excitability.

(93) Phosphoryl groups are involved in the regulation of neuronal signaling.

(94) Neuroglia can release neurotransmitters to influence neuronal activity.

(95) Astrocyte processes form a network that supports neuronal connectivity.

(96) Lamellipodia are important for the development of neuronal connections.

(97) Kephalin is important for the proper functioning of neuronal membranes.

(98) The development of new drugs aims to target specific neuronal receptors.

(99) Neuronal firing patterns can be altered by changes in synaptic strength.

(100) Microglia can release neurotrophic factors to support neuronal survival.

Sentence with word neuronal

(101) Astrocytes can release chemical signals that modulate neuronal activity.

(102) Oligodendrocyte dysfunction can result in altered neuronal excitability.

(103) The dysfunction of macroglia can lead to abnormal neuronal excitability.

(104) The neuroepithelium is involved in the regulation of neuronal migration.

(105) The study aimed to validate glycoprotein's role in neuronal development.

(106) If gangliosides are not adequately protected, neuronal damage may occur.

(107) Astrocytes can release neurotransmitters and modulate neuronal activity.

(108) The cytoskeletal system is crucial for neuronal development and function.

(109) Neuronal excitability can be influenced by changes in ion concentrations.

(110) The study aims to verify the glycoprotein's role in neuronal development.

Sentence of neuronal

(111) The synaptosomal membrane plays a crucial role in neuronal communication.

(112) Glial cells can release chemical signals that modulate neuronal activity.

(113) Neuroglial cells are involved in the regulation of neuronal excitability.

(114) The release of neurotransmitters is a key step in neuronal communication.

(115) The dysfunction of macroglia can lead to impaired neuronal communication.

(116) Neuronal plasticity enables the brain to adapt and change throughout life.

(117) The ligand-receptor interaction is essential for proper neuronal function.

(118) Axoplasms can undergo structural changes in response to neuronal activity.

(119) Oligodendrocytes can undergo myelination in response to neuronal activity.

(120) Shape analysis is used in the study of neuronal connectivity in the brain.

Neuronal used in a sentence

(121) The composition of phospholipids in the brain can affect neuronal function.

(122) The study of neuronal activity has advanced our understanding of the brain.

(123) Microtubules are involved in the formation of neuronal axons and dendrites.

(124) Resting potential is a key parameter in the study of neuronal excitability.

(125) The regulation of microtubule dynamics is crucial for neuronal development.

(126) The role of phosphodiesterase in neuronal signaling is still being studied.

(127) The disruption of neurofibril integrity can result in neuronal dysfunction.

(128) The express glycoprotein is important for neuronal development and function.

(129) The neuronal network in the brain is responsible for processing information.

(130) The presence of neurogliacytes is essential for proper neuronal development.

Neuronal sentence in English

(131) The abnormal aggregation of neurofibrils can disrupt neuronal communication.

(132) The neurofibril is intricately linked to the process of neuronal plasticity.

(133) The integrity of axoplasms is crucial for maintaining neuronal connectivity.

(134) The disruption of axolemmas can result in the loss of neuronal connectivity.

(135) Neuroblasts can be induced to differentiate into specific neuronal subtypes.

(136) Gangliosides are important for the proper functioning of neuronal receptors.

(137) Axoplasmic stasis can impair neuronal function and lead to neurodegeneration.

(138) The firing of neuronal synapses allows for communication between brain cells.

(139) Ganglioside is important for maintaining the integrity of neuronal membranes.

(140) The confocal technique is particularly useful for studying neuronal networks.

(141) Neurotrophic factors are involved in the process of neuronal differentiation.

(142) Neuroglia can release growth factors to promote neuronal survival and growth.

(143) Gangliosides can enhance neuronal connectivity if included in the daily diet.

(144) The axoplasmic transport system is crucial for maintaining neuronal function.

(145) The subcellular localization of ion channels influences neuronal excitability.

(146) The role of sialic acid in neuronal development is still not fully understood.

(147) The role of phosphatase in neuronal development is still not fully understood.

(148) Neuronal activity can be modulated by external stimuli such as light or sound.

(149) Oligodendrocyte dysfunction can lead to disruptions in neuronal communication.

(150) Neurotrophic factors are released by glial cells to support neuronal survival.

(151) Dysfunction of neuroglial cells can lead to disruptions in neuronal signaling.

(152) Neuropharmacology studies the effects of drugs on neuronal signaling pathways.

(153) The neuroepithelium is responsible for the establishment of neuronal polarity.

(154) The intercellular communication pathways are essential for neuronal signaling.

(155) The stromal matrix in the brain provides a framework for neuronal connections.

(156) The cerebral atrophy seen in Alzheimer's disease is a result of neuronal loss.

(157) The addition of uridine to cell cultures can enhance neuronal differentiation.

(158) The axoplasmic matrix provides a supportive environment for neuronal processes.

(159) Neuronal connections are constantly forming and strengthening through learning.

(160) The study of neuronal development is crucial for understanding brain disorders.

(161) Neurogliacytes can release signaling molecules that modulate neuronal activity.

(162) The parasagittal brain sections were analyzed for changes in neuronal activity.

(163) Oligodendrocytes play a role in synaptic plasticity and neuronal communication.

(164) Astrocyte dysfunction can lead to impaired neuronal function and communication.

(165) Gangliosides are involved in the regulation of neuronal survival and apoptosis.

(166) Axoplasms are essential for the maintenance of neuronal structure and function.

(167) Neuronal degeneration is a characteristic feature of neurodegenerative diseases.

(168) The neuronal network in the brain undergoes constant remodeling throughout life.

(169) Astrocytes can buffer changes in extracellular pH to maintain neuronal function.

(170) Ionophores have been used to investigate the role of ions in neuronal signaling.

(171) The cocultured neurons and glial cells supported neuronal survival and function.

(172) The function of annexin in neuronal development is currently being investigated.

(173) Axoplasms are highly dynamic structures that constantly adapt to neuronal needs.

(174) The researchers used intracerebral electrophysiology to study neuronal activity.

(175) The role of neuraminic acid in neuronal development is still being investigated.

(176) Dysfunction of regulate ion channels can lead to abnormal neuronal excitability.

(177) Fluorometry is employed in the field of neuroscience to study neuronal activity.

(178) Lissencephaly is caused by abnormal neuronal migration during brain development.

(179) Neurofibrillogenesis is tightly regulated to ensure proper neuronal development.

(180) Neuroglia are non-neuronal cells that provide support and protection to neurons.

(181) Argyrophil staining is commonly used in research to study neuronal connectivity.

(182) The fluorochrome staining allowed for the visualization of neuronal connections.

(183) Glial cells can release growth factors that promote neuronal survival and growth.

(184) The precise organization of neurofibrils is crucial for proper neuronal function.

(185) Dysfunction of neuroglial cells can lead to disruptions in neuronal connectivity.

(186) Dysfunction in the neurofibril can lead to disruptions in neuronal communication.

(187) The neurofibril is involved in the regulation of neuronal growth and development.

(188) Glia can release neurotransmitters that can directly influence neuronal activity.

(189) Neuroglial cells can release signaling molecules that modulate neuronal activity.

(190) If gangliosides are not properly expressed, neuronal connections may be weakened.

(191) Polyamines have been shown to play a role in neuronal development and plasticity.

(192) The ex vivo approach allowed for the study of neuronal connectivity in the brain.

(193) The neuronal circuitry involved in memory formation is still not fully understood.

(194) The study of neuronal connectivity has shed light on brain connectivity disorders.

(195) The study of neuronal signaling has revolutionized our understanding of the brain.

(196) The hyperpolarized state of the cell is necessary for proper neuronal integration.

(197) The inactivations of certain neurotransmitters can disrupt neuronal communication.

(198) Ouabain has been shown to modulate the activity of ion channels in neuronal cells.

(199) The disruption of neurofibril architecture can lead to impaired neuronal function.

(200) Neuropeptides can have both excitatory and inhibitory effects on neuronal activity.

(201) The axoplasmic content contains various molecules necessary for neuronal signaling.

(202) The neuronal connections in the brain form the basis of our thoughts and behaviors.

(203) The argyrophilic stain allows for the visualization of intricate neuronal networks.

(204) Researchers are investigating the role of the pentamer motif in neuronal signaling.

(205) The hyperpolarized state of the cell allows for precise control of neuronal firing.

(206) As a biophysicist, she investigated the role of ion channels in neuronal signaling.

(207) The undifferentiation of neuronal cells can result in neurodevelopmental disorders.

(208) Gangliosides are involved in the regulation of neuronal growth and differentiation.

(209) Gangliosides are crucial for the proper functioning of neuronal signaling pathways.

(210) Athrocytes are involved in the regulation of neuronal migration during development.

(211) The scientist discovered a new mechanism of anterograde transport in neuronal cells.

(212) The study of neuronal circuits has revealed insights into decision-making processes.

(213) Neurogliacytes can release growth factors that promote neuronal survival and growth.

(214) The transfection of neuronal cells can provide insights into neurological disorders.

(215) Synapsis is a tightly controlled process that ensures proper neuronal communication.

(216) The occurrence of chromatolysis can be indicative of neuronal damage or dysfunction.

(217) The hyperpolarized state of the cell is essential for proper neuronal communication.

(218) Neuropharmacology explores the mechanisms by which drugs modulate neuronal activity.

(219) Axonal transport is essential for the maintenance and repair of neuronal connections.

(220) Neuronal communication is essential for coordinating movement and sensory perception.

(221) Neuronal activity in specific brain regions can be correlated with certain behaviors.

(222) The re-uptake of neurotransmitters is necessary for efficient neuronal communication.

(223) The argyrophilic reaction is an important tool in the study of neuronal connectivity.

(224) Autacoids, including adenosine, can modulate neuronal activity and sleep-wake cycles.

(225) Reelin has also been implicated in the regulation of neuronal survival and apoptosis.

(226) The researchers are investigating the role of phosphorylation in neuronal development.

(227) The lateral ventricle is involved in the modulation of neuronal activity in the brain.

(228) Astrocytes can release growth factors that promote neuronal survival and regeneration.

(229) Astrocytes can release neurotrophic factors that promote neuronal survival and growth.

(230) Fibrous connections are formed through the growth and branching of neuronal processes.

(231) Picrotoxin has been used as a tool to study the effects of aging on neuronal function.

(232) The separate glycoprotein is involved in neuronal development and synaptic plasticity.

(233) Neurofibril staining can help identify specific neuronal populations within the brain.

(234) The binding of adenosine diphosphate to a receptor can modulate neuronal excitability.

(235) The fundamental mechanism of action of anesthetics involves altering neuronal activity.

(236) Glial cells can release growth factors that promote neuronal survival and regeneration.

(237) Microglial cells can release inflammatory mediators that contribute to neuronal damage.

(238) The trimer interaction between undefined neurotransmitters affected neuronal signaling.

(239) Astrocyte calcium signaling can modulate synaptic plasticity and neuronal excitability.

(240) The absence of reelin during brain development can lead to abnormal neuronal migration.

(241) The fluorochrome is widely used in neuroscience research to study neuronal connectivity.

(242) Neurogliacytes can respond to changes in neuronal activity by altering their morphology.

(243) The subcellular trafficking of neurotransmitters is essential for neuronal communication.

(244) Researchers used a microelectrode to study the effects of drugs on neuronal excitability.

(245) Astrocyte dysfunction can contribute to the disruption of neuronal circuits in the brain.

(246) The neuroscience research project investigated the effect of blebs on neuronal signaling.

(247) Depolarization is a highly regulated process that is crucial for proper neuronal function.

(248) The refractory period is crucial for maintaining the temporal order of neuronal signaling.

(249) The action spectrum of a neurotransmitter can indicate its role in neuronal communication.

(250) Tetrazolium-based stains are commonly used in neuroscience to visualize neuronal activity.

(251) Intracytoplasmic trafficking of neurotransmitters is essential for neuronal communication.

(252) The use of optical tweezers in neuroscience has provided insights into neuronal processes.

(253) Anterograde transport of neurotransmitters is essential for proper neuronal communication.

(254) The binding of calcium to the calretinin protein is involved in neuronal calcium signaling.

(255) Glia can respond to changes in neuronal activity and adjust their own activity accordingly.

(256) The RSTED technique has been used to study the structure and function of neuronal synapses.

(257) The function of glycolipid in the nervous system is crucial for proper neuronal development.

(258) The use of channelrhodopsin has allowed for the precise control of neuronal firing patterns.

(259) Microglial cells can release neurotrophic factors that support neuronal survival and growth.

(260) Neuropharmacology research investigates the effects of drugs on neuronal signaling pathways.

(261) Gangliosides, which are highly expressed in the brain, are involved in neuronal development.

(262) Astrocyte-mediated release of growth factors can promote neuronal survival and regeneration.

(263) Astrocyte-mediated release of neurotrophic factors can promote neuronal survival and growth.

(264) Neurovascular coupling is the process by which neuronal activity is matched with blood flow.

(265) The depolarization of the neuron is a key factor in the regulation of neuronal excitability.

(266) The translocation of neurotransmitters across synapses is crucial for neuronal communication.

(267) Dendrites can have different types of metabotropic receptors that modulate neuronal activity.

(268) Neurotrophic factors are crucial for the development and maintenance of neuronal connections.

(269) Multiphoton imaging has been used to study the development of neuronal circuits in the brain.

(270) The deficiency of gangliosides can lead to impaired neuronal function and cognitive deficits.

(271) Intravital microscopy has allowed for the visualization of neuronal activity in live animals.

(272) The refractory period is a protective mechanism that prevents excessive neuronal excitability.

(273) The quantal nature of neurotransmitter release plays a crucial role in neuronal communication.

(274) Microglial cells can interact with the extracellular matrix to modulate neuronal connectivity.

(275) Scientists carry out glycoprotein synthesis to investigate their role in neuronal development.

(276) Cytophotometric techniques have been successfully applied in the study of neuronal development.

(277) The binding of aminobutyric acid to its receptors results in the inhibition of neuronal firing.

(278) Gangliosides are important for neuronal plasticity, and they contribute to learning and memory.

(279) The misfolding of prion proteins disrupts normal cellular processes and leads to neuronal damage.

(280) The length and branching pattern of dendrites can influence the strength of neuronal connections.

(281) Neuropeptides are released in response to neuronal activity and can act as retrograde messengers.

(282) Picrotoxin has been used in experiments to investigate the effects of stress on neuronal activity.

(283) Intracerebral injections of neurotrophic factors showed potential for promoting neuronal survival.

(284) Neurotransmission is a tightly controlled process that maintains the balance of neuronal activity.

(285) Resting potential is a fundamental aspect of neuronal physiology that is still being studied today.

(286) Eicosanoids can interact with neurotransmitters, affecting neuronal activity and neurotransmission.

(287) Dysfunction of neurogliacytes can lead to impaired neuronal communication and synaptic transmission.

(288) The effects of picrotoxin on neuronal excitability can be observed using calcium imaging techniques.

(289) Picrotoxin has been used in studies examining the effects of sleep deprivation on neuronal activity.

(290) The cytoarchitectonic analysis showed variations in neuronal density across different brain regions.

(291) The reabsorption of certain neurotransmitters by the brain is crucial for proper neuronal signaling.

(292) The axoplasmic flow can be disrupted by certain toxins or diseases, leading to neuronal dysfunction.

(293) Epifluorescence microscopy is commonly used in the field of neuroscience to study neuronal activity.

(294) The prion-protein is thought to induce a cascade of events leading to neuronal dysfunction and death.

(295) The effects of picrotoxin on neuronal activity can be observed using electrophysiological techniques.

(296) Scientists have used the array melanogaster to investigate the role of genes in neuronal development.

(297) The ankyrin protein is involved in the regulation of neuronal excitability and synaptic transmission.

(298) Prolyl hydroxylase domain-containing protein 19 is implicated in the regulation of neuronal survival.

(299) The dynamic behavior of tubulin is crucial for processes such as axon growth and neuronal development.

(300) Gangliosides, which are abundant in the nervous system, are crucial for proper neuronal communication.

(301) The study of neurofibrils has contributed to our understanding of neuronal development and plasticity.

(302) The disruption of neurofibril architecture can impair neuronal function and lead to cognitive decline.

(303) The axoplasmic flow can be disrupted by certain diseases or injuries, leading to neuronal dysfunction.

(304) Neurofibril staining techniques have greatly contributed to our understanding of neuronal connectivity.

(305) Aminopeptidase is involved in the processing of neuropeptides, which play a role in neuronal signaling.

(306) Cytoskeletons play a crucial role in neuronal development and the establishment of neuronal connections.

(307) Prolyl hydroxylase domain-containing protein 13 is implicated in the regulation of neuronal development.

(308) Glial cells are non-neuronal cells that provide support and protection to neurons in the nervous system.

(309) Prolyl hydroxylase domain-containing protein 5 is involved in the regulation of neuronal differentiation.

(310) The transport of potassium ions across the neuronal membrane is essential for nerve impulse transmission.

(311) The immunohistochemistry analysis showed a significant decrease in neuronal markers in the diseased brain.

(312) Phalloidin has been used in neurobiology research to investigate the role of actin in neuronal development.

(313) The cytoskeletons are crucial for the proper functioning of neurons and the formation of neuronal networks.

(314) If gangliosides are not properly incorporated into cell membranes, neuronal communication may be disrupted.

(315) Prolyl hydroxylase domain-containing protein 17 is associated with the regulation of neuronal excitability.

(316) The effects of picrotoxin on neuronal network activity can be studied using multi-electrode array recordings.

(317) Gangliosides play a crucial role in maintaining neuronal integrity if they are present in sufficient amounts.

(318) Neuroglial cells are non-neuronal cells that provide support and protection to neurons in the nervous system.

(319) The prion-protein is thought to be involved in the prion diseases' ability to cause neuronal loss and gliosis.

(320) Ankyrin is highly expressed in the brain, where it plays a role in neuronal development and synaptic function.

(321) Despite the high expression of the receptor in the brain, its function in neuronal development remains unclear.

(322) The cytoarchitectonic analysis demonstrated distinct patterns of neuronal connectivity in the prefrontal cortex.

(323) Gangliosides are important for neuronal survival, and their deficiency can lead to neurodevelopmental disorders.

(324) The researchers investigated the role of the yield glycoprotein in neuronal development and synaptic plasticity.

(325) The researcher conducted experiments to investigate the effects of anterograde axonal transport on neuronal survival.

(326) Autocoids can also interact with other signaling molecules, such as neurotransmitters, to regulate neuronal activity.

(327) Gangliosides, which are highly expressed in neuronal membranes, are crucial for synaptic transmission and plasticity.

(328) Gangliosides play a crucial role in maintaining neuronal membrane stability if they are present in appropriate levels.

(329) The visualization of neurofibrils using electron microscopy has revolutionized our understanding of neuronal structure.

(330) Postischemic neurovascular coupling refers to the coordination between neuronal activity and blood flow restoration in the brain.

(331) Active transport is used to transport neurotransmitters across the synaptic cleft, and this process is essential for neuronal communication.

(332) HG, which stands for hyperpolarization-activated cyclic nucleotide-gated channels, plays a crucial role in regulating neuronal excitability.

(333) Diterpenoids have been investigated for their potential as neuroprotective agents, as they can help prevent neuronal damage and degeneration.

The word usage examples above have been gathered from various sources to reflect current and historical usage of the word Neuronal. They do not represent the opinions of TranslateEN.com.