Neuron in a sentence

(1) The dendron is a part of a neuron.

(2) The cyton is the main body of a neuron.

(3) Dendrites are the branches of a neuron.

(4) Axones are part of the neuron's structure.

(5) The axone is the longest part of a neuron.

(6) The word axon refers to a part of a neuron.

(7) The cell body is the main part of a neuron.

(8) The afferent neuron is a type of nerve cell.

(9) The efferent neuron is a type of nerve cell.

(10) The cyton contains the nucleus of the neuron.

Neuron sentence

(11) The efferent neuron controls muscle movement.

(12) The afferent neuron is part of the reflex arc.

(13) The perikaryon is the central part of a neuron.

(14) The afferent neuron is activated by a stimulus.

(15) The dendrite is a crucial component of a neuron.

(16) The cell body contains the nucleus of the neuron.

(17) The neurite extended from the neuron's cell body.

(18) The neuron depolarizes when it receives a signal.

(19) The efferent neuron sends signals to the muscles.

(20) The perikaryon contains the nucleus of the neuron.

Neuron make sentence

(21) The efferent neuron is involved in reflex actions.

(22) A sensory neuron is responsible for detecting pain.

(23) The efferent neuron is also known as a motor neuron.

(24) The postsynaptic neuron can have multiple dendrites.

(25) Motor neuron diseases can be hereditary or acquired.

(26) Motor neuron diseases can affect people of all ages.

(27) The efferent neuron is affected by certain diseases.

(28) The afferent neuron sends signals to the spinal cord.

(29) The afferent neuron is activated by light in the eye.

(30) The neuron is a building block for the nervous system.

Sentence of neuron

(31) The afferent neuron is involved in the sense of taste.

(32) The afferent neuron is involved in the sense of smell.

(33) The axonic neuron is a specialized type of nerve cell.

(34) The sensory neuron detects changes in light intensity.

(35) The afferent neuron is responsible for detecting pain.

(36) The efferent neuron is also known as the motor neuron.

(37) The efferent neuron is activated by neurotransmitters.

(38) The motoneuron is classified as a type of motor neuron.

(39) The depolarisation of a neuron is a reversible process.

(40) The depolarized motor neuron triggered muscle movement.

Neuron meaningful sentence

(41) The sensory neuron is involved in the sense of balance.

(42) The sensory neuron is sensitive to changes in humidity.

(43) Babinski's sign is a sign of upper motor neuron lesion.

(44) The action-potential travels down the axon of a neuron.

(45) The action potential depolarizes the neuron's membrane.

(46) The afferent neuron is essential for the sense of touch.

(47) The neuron is the functional unit of the nervous system.

(48) The sensory neuron is activated by pressure on the skin.

(49) The sensory neuron helps us perceive different textures.

(50) The damaged neuron showed signs of neurite degeneration.

Neuron sentence examples

(51) Depolarisations can spread along the length of a neuron.

(52) The neuron was depolarised by the influx of sodium ions.

(53) The afferent neuron is involved in the sense of balance.

(54) The efferent neuron carries signals away from the brain.

(55) The efferent neuron is essential for voluntary movement.

(56) The efferent neuron is connected to the effector organs.

(57) The efferent neuron communicates with muscles and glands.

(58) The photoreceptor is a highly specialized type of neuron.

(59) The postsynaptic neuron can have multiple axon terminals.

(60) Depolarizations can propagate along the axon of a neuron.

Sentence with neuron

(61) The sensory neuron is part of the somatic nervous system.

(62) The time constant of a neuron determines its firing rate.

(63) The sensory neuron helps us perceive the world around us.

(64) The sensory neuron sends signals about pain to the brain.

(65) The sensory neuron is essential for the sense of hearing.

(66) The afferent neuron is activated by pressure on the skin.

(67) The efferent neuron is part of the somatic nervous system.

(68) The efferent neuron transmits signals to skeletal muscles.

(69) The depolarisation of a neuron is an all-or-nothing event.

(70) Motor neuron disorders can cause muscle cramps and spasms.

Use neuron in a sentence

(71) The exact cause of motor neuron diseases is still unknown.

(72) The axonic neuron is a key player in neural communication.

(73) The sensory neuron responds to stimuli in the environment.

(74) The sensory neuron is sensitive to changes in temperature.

(75) The sensory neuron sends signals about touch to the brain.

(76) The afferent neuron is part of the somatic nervous system.

(77) The perikaryon is also known as the cell body of a neuron.

(78) The afferent neuron is activated by chemicals in the body.

(79) The neuron needs to hyperpolarize before it can fire again.

(80) The postsynaptic neuron can undergo long-term potentiation.

Sentence using neuron

(81) The depolarisation of a neuron is an electrochemical event.

(82) Motor neuron diseases can lead to respiratory difficulties.

(83) The afferent neuron is involved in the perception of sound.

(84) The word axonic refers to a type of neuron without an axon.

(85) Damage to a sensory neuron can result in loss of sensation.

(86) The motor end plate receives signals from the motor neuron.

(87) In just a few yoctoseconds, a neuron can fire in the brain.

(88) The time constant of the neuron determines its firing rate.

(89) The Babinski reflex is a sign of upper motor neuron damage.

(90) The neuron fired antidromically, causing a reflex response.

Neuron example sentence

(91) The efferent neuron is responsible for autonomic functions.

(92) The efferent neuron is crucial for maintaining homeostasis.

(93) The efferent neuron is responsible for glandular secretion.

(94) The efferent neuron is part of the autonomic nervous system.

(95) Action potentials are propagated along the axon of a neuron.

(96) The unipotent neuron could only transmit electrical signals.

(97) The treatment options for motor neuron diseases are limited.

(98) The sensory neuron is part of the peripheral nervous system.

(99) Purkinje cells are a type of neuron found in the cerebellum.

(100) The Babinski sign is a sign of an upper motor neuron lesion.

Sentence with word neuron

(101) The basic building block of a perceptron is a single neuron.

(102) The efferent neuron is involved in the process of digestion.

(103) The efferent neuron is part of the peripheral nervous system.

(104) The neuron is the basic building block of the nervous system.

(105) The electrical impulse was responsible for the neuron firing.

(106) The afferent neuron is part of the peripheral nervous system.

(107) The afferent neuron plays a vital role in the sense of touch.

(108) The axonic neuron is characterized by its absence of an axon.

(109) The efferent neuron is a key component of the nervous system.

(110) The cell body is responsible for the metabolism of the neuron.

Sentence of neuron

(111) The postsynaptic neuron can transmit signals to other neurons.

(112) The postsynaptic neuron can have different types of receptors.

(113) The endplate is where the motor neuron meets the muscle fiber.

(114) The perceptron is a mathematical model of a biological neuron.

(115) The progression of motor neuron diseases can be unpredictable.

(116) Damage to the afferent neuron can result in loss of sensation.

(117) The hyperpolarizing current reduced the neuron's excitability.

(118) The sensory neuron plays a crucial role in the sense of taste.

(119) The sensory neuron is involved in the sense of proprioception.

(120) The postsynaptic density is a specialized region of the neuron.

Neuron used in a sentence

(121) The depolarized neuron fired an action potential down the axon.

(122) Motor neuron disorders can lead to muscle wasting and weakness.

(123) The afferent neuron is crucial for the sense of proprioception.

(124) The afferent neuron is involved in the sense of proprioception.

(125) The afferent neuron helps in the perception of light and color.

(126) The depolarization of the neuron triggered an action potential.

(127) The cell structure of a neuron allows for electrical signaling.

(128) The sensory neuron relays information about touch to the brain.

(129) Neurotransmitters bind to receptors on the postsynaptic neuron.

(130) The subthreshold voltage was not enough to activate the neuron.

Neuron sentence in English

(131) The activation of GABA receptors will hyperpolarize the neuron.

(132) The depolarization of the neuron is followed by repolarization.

(133) The efferent neuron is involved in the regulation of breathing.

(134) The efferent neuron is activated by the central nervous system.

(135) The efferent neuron is sensitive to changes in the environment.

(136) The efferent neuron is involved in the fight-or-flight response.

(137) The perceptron model is based on the concept of a single neuron.

(138) The depolarized neuron transmitted the pain signal to the brain.

(139) The depolarized motor neuron initiated the movement of the limb.

(140) The depolarized neuron fired an electrical signal down the axon.

(141) The Purkinje cells are a type of neuron found in the cerebellum.

(142) The afferent neuron detects changes in the external environment.

(143) The sensory neuron transmits signals from the skin to the brain.

(144) The sensory neuron transmits signals from the nose to the brain.

(145) The sensory neuron is specialized in detecting changes in smell.

(146) The sensory neuron is activated by chemicals in the environment.

(147) The axoplasmic content can vary depending on the type of neuron.

(148) The efferent neuron is involved in the fight or flight response.

(149) The efferent neuron is affected by certain medications and drugs.

(150) The postsynaptic neuron can have different types of ion channels.

(151) The depolarized state of the neuron allowed for increased firing.

(152) The afferent neuron allows us to perceive the texture of objects.

(153) Perceptrons are based on the biological model of a single neuron.

(154) The sensory neuron is responsible for detecting changes in sound.

(155) The sensory neuron is responsible for detecting changes in taste.

(156) The end-plate of the neuron was responsible for synaptic pruning.

(157) The visual cell is a specialized type of neuron found in the eye.

(158) Depolarization is a key step in the action potential of a neuron.

(159) The depolarization of a neuron can be inhibited by certain drugs.

(160) An efferent neuron is responsible for transmitting motor signals.

(161) The efferent neuron plays a crucial role in coordinating movement.

(162) The efferent neuron is affected by certain neurological disorders.

(163) Damage to the perikaryon can affect the functioning of the neuron.

(164) The dendrite's length can vary depending on the neuron's location.

(165) Motor neuron diseases can result in muscle stiffness and rigidity.

(166) The afferent neuron helps in the coordination of muscle movements.

(167) The afferent neuron carries signals related to the sense of smell.

(168) The axonic neuron is an important component of the nervous system.

(169) The axonic neuron is an essential component of the nervous system.

(170) The sensory neuron is connected to other neurons through synapses.

(171) The thickness of axolemmas varies depending on the type of neuron.

(172) The sensory neuron transmits signals from the tongue to the brain.

(173) The time it takes for a neuron to fire is measured in nanoseconds.

(174) The afferent neuron is the first step in the process of sensation.

(175) The afferent neuron is activated by a stimulus in the environment.

(176) The depolarization of a neuron can be measured using an electrode.

(177) The efferent neuron is responsible for transmitting motor commands.

(178) The efferent neuron allows us to consciously control our movements.

(179) Motor neuron damage can result in loss of coordination and balance.

(180) The afferent neuron plays a crucial role in the perception of pain.

(181) The afferent neuron allows us to feel pain and temperature changes.

(182) The afferent neuron allows us to detect changes in the environment.

(183) The afferent neuron helps in the coordination of fine motor skills.

(184) The afferent neuron allows us to perceive the intensity of stimuli.

(185) The sensory neuron sends information to the central nervous system.

(186) The hyperpolarized state of the neuron prevents spontaneous firing.

(187) A nerve cell, also known as a neuron, transmits electrical signals.

(188) The afferent neuron is the first step in the process of perception.

(189) The activation of potassium channels will hyperpolarize the neuron.

(190) Amacrine cells are a type of neuron found in the retina of the eye.

(191) The afferent neuron pathway is activated when we touch a hot stove.

(192) The dendrites of a neuron can be affected by drugs and medications.

(193) The efferent neuron is responsible for the body's response to pain.

(194) The efferent neuron is essential for the body's response to stimuli.

(195) The postsynaptic neuron can have different types of synaptic clefts.

(196) The unipotent neuron fired action potentials in response to stimuli.

(197) The axonic neuron is an intriguing area of research in neuroscience.

(198) The axonic neuron is an important focus of study in neurophysiology.

(199) A sensory neuron is responsible for detecting touch and temperature.

(200) The sensory neuron sends information about temperature to the brain.

(201) The sensory neuron is responsible for detecting changes in pressure.

(202) The sensory neuron is connected to the motor neuron in a reflex arc.

(203) The sensory neuron is specialized in detecting changes in vibration.

(204) The end-plate of the neuron was responsible for synaptic plasticity.

(205) The end-plate of the neuron was involved in the formation of memory.

(206) The afferent neuron is activated by light, sound, and other stimuli.

(207) The psychology professor discussed the shaft-like shape of a neuron.

(208) The afferent neuron pathway is activated when we see a bright light.

(209) The dendrite's size and shape can vary depending on the neuron type.

(210) The depolarization of a neuron's membrane is an all-or-nothing event.

(211) The postsynaptic neuron receives signals from the presynaptic neuron.

(212) The cyton is responsible for maintaining the neuron's overall health.

(213) The depolarized motor neuron triggered the contraction of the muscle.

(214) The symptoms of motor neuron diseases can vary from person to person.

(215) Motor neuron disorders can be managed through medication and therapy.

(216) Motor neuron disorders can affect the muscles in the limbs and trunk.

(217) Motor neuron disorders can cause muscle twitching and fasciculations.

(218) The afferent neuron helps in the coordination of voluntary movements.

(219) The axonic neuron is an important topic in the field of neurobiology.

(220) The sensory neuron is connected to the brain through the spinal cord.

(221) The hyperpolarized condition of the neuron prevents excessive firing.

(222) The hyperpolarizing current decreased the excitability of the neuron.

(223) The perikaryon is the site of many metabolic processes in the neuron.

(224) The afferent neuron pathway is activated when we smell a strong odor.

(225) The efferent neuron is involved in the process of voluntary movement.

(226) The efferent neuron is activated by the release of neurotransmitters.

(227) The efferent neuron is responsible for the body's response to stress.

(228) The efferent neuron is involved in the control of voluntary movements.

(229) The efferent neuron carries signals from the brain to the spinal cord.

(230) The efferent neuron is responsible for initiating muscle contractions.

(231) The efferent neuron is connected to the brain through the spinal cord.

(232) The efferent neuron is involved in the regulation of body temperature.

(233) The axoplasmic cytoskeleton provides structural support to the neuron.

(234) The depolarization of a neuron's membrane is an electrochemical event.

(235) The branching structure of the neuron allowed for complex connections.

(236) The postsynaptic neuron can have specialized structures called spines.

(237) The postsynaptic neuron can have different types of synaptic vesicles.

(238) The postsynaptic neuron can have different types of synaptic proteins.

(239) Electrotonic signals can be propagated bidirectionally along a neuron.

(240) The afferent neuron relays information about temperature to the brain.

(241) The afferent neuron helps in the perception of pressure and vibration.

(242) The end-plate region is where the motor neuron meets the muscle fiber.

(243) The sensory neuron transmits signals from the skin to the spinal cord.

(244) The end-plate of the neuron contained receptors for neurotransmitters.

(245) The loss of motoneurons can lead to motor neuron diseases such as ALS.

(246) The afferent neuron is connected to the brain through the spinal cord.

(247) The potassium ions will hyperpolarize the neuron's membrane potential.

(248) The refractory period of the neuron is necessary for proper signaling.

(249) The efferent neuron is involved in the process of learning and memory.

(250) The cell body is responsible for the overall functioning of the neuron.

(251) The ramose structure of the neuron allowed for efficient communication.

(252) Motor neuron disorders can cause difficulty in speaking and swallowing.

(253) The sensory neuron is connected to other neurons in the nervous system.

(254) The behavior of a neuron firing can be modeled as a stochastic process.

(255) The neurite extended towards the neighboring neuron, forming a synapse.

(256) The end-plate of the muscle fiber was where the motor neuron connected.

(257) The axolemma is a barrier between the inside and outside of the neuron.

(258) The axoplasm is the cytoplasmic material found in the axon of a neuron.

(259) The axoplasmic cytoskeleton provides structural support for the neuron.

(260) The depolarizing current caused the neuron to fire an action potential.

(261) The professor explained how electrical signals propagate down a neuron.

(262) The professor explained how electrical signals propagate over a neuron.

(263) The dendrites of a neuron can be damaged by certain toxins or diseases.

(264) The efferent neuron is involved in the regulation of the immune system.

(265) The postsynaptic membrane potential determines the firing of the neuron.

(266) Motor neuron diseases affect the nerves responsible for muscle movement.

(267) The axonic neuron is structurally different from other types of neurons.

(268) The axonic neuron is a fascinating subject of study for neuroscientists.

(269) The hyperpolarizing stimulus caused the neuron to become more polarized.

(270) The hyperpolarizing stimulus caused the neuron to become more inhibited.

(271) The hyperpolarizing current reduced the neuron's sensitivity to stimuli.

(272) The refractory period of a neuron is important for proper communication.

(273) The neuron was depolarized, causing an action potential to be generated.

(274) The outmost sheath of the neuron is responsible for protecting the axon.

(275) The afferent neuron pathway is responsible for our ability to feel pain.

(276) The afferent neuron pathway is involved in our sense of taste and smell.

(277) The afferent neuron is responsible for detecting changes in temperature.

(278) The efferent neuron carries signals away from the central nervous system.

(279) The efferent neuron is essential for the body's coordination and balance.

(280) The shape and size of dendrites can vary depending on the type of neuron.

(281) The depolarization of a neuron's membrane is a rapid and transient event.

(282) The cell body can vary in size and shape depending on the type of neuron.

(283) The postsynaptic neuron can have both excitatory and inhibitory synapses.

(284) The postsynaptic neuron can have different types of synaptic connections.

(285) The depolarisation of a neuron triggers the release of neurotransmitters.

(286) The endplate region is where the motor neuron releases neurotransmitters.

(287) The resting potential of a neuron can be altered by drugs or medications.

(288) Motor neuron diseases can affect the ability to perform daily activities.

(289) The length of axoplasms can vary greatly depending on the type of neuron.

(290) Hyperpolarizing the neuron's membrane potential lowered its excitability.

(291) The depolarization of the neuron enabled the transmission of information.

(292) The depolarization of the neuron facilitated the transmission of signals.

(293) The axoplasm transports nutrients and other substances within the neuron.

(294) The perikaryon is the central part of a neuron that contains the nucleus.

(295) The opening of potassium channels can lead to hyperpolarizing the neuron.

(296) The depolarization of a neuron's membrane is a rapid and reversible event.

(297) Synaptic integration occurs when multiple inputs are combined in a neuron.

(298) Gamma motor neurons are a type of motor neuron involved in muscle control.

(299) The resting potential of a neuron can be affected by diseases or injuries.

(300) The perikaryon is responsible for the synthesis of proteins in the neuron.

(301) The perikaryon can vary in size and shape depending on the type of neuron.

(302) The presynaptic neuron releases neurotransmitters into the synaptic cleft.

(303) The depolarized neuron transmitted the electrical signal to the next cell.

(304) The refractory period of the neuron is the time between action potentials.

(305) The presynaptic neuron can modulate the strength of synaptic transmission.

(306) The afferent neuron pathway is crucial for our ability to detect movement.

(307) The afferent neuron pathway is involved in our sense of touch and texture.

(308) Dendrites are the first point of contact for incoming signals in a neuron.

(309) After an action potential is fired, the neuron enters a refractory period.

(310) The depolarization of a neuron allows for the release of neurotransmitters.

(311) The interneuron receives input from one neuron and transmits it to another.

(312) The dendroidal structure of the neuron allowed for efficient communication.

(313) The perikaryon is essential for the survival and functioning of the neuron.

(314) The endplate region is where the motor neuron and muscle fiber communicate.

(315) The depolarizes state of the neuron allows for the transmission of signals.

(316) Resting potential plays a role in determining the excitability of a neuron.

(317) Motor neuron diseases can have a significant impact on a person's mobility.

(318) The prognosis for motor neuron diseases varies depending on the individual.

(319) The atomical structure of the neuron was studied using confocal microscopy.

(320) The afferent neuron carries sensory information from the body to the brain.

(321) The axonic neuron is a topic of interest in the study of brain development.

(322) The dendriform structure of the neuron allowed for efficient communication.

(323) The hyperpolarized condition of the neuron is necessary for repolarization.

(324) The sensory neuron detects changes in light and sends signals to the brain.

(325) The refractory period of the neuron is important for proper brain function.

(326) The refractory period of the neuron is important for proper nerve function.

(327) The inhibitory neurotransmitter will hyperpolarize the postsynaptic neuron.

(328) After the antidromic stimulation, the neuron exhibited a burst of activity.

(329) When depolarization occurs, the inside of the neuron becomes more positive.

(330) The efferent neuron is responsible for the body's fight or flight response.

(331) Dysfunction of the efferent neuron can lead to muscle weakness or paralysis.

(332) The efferent neuron is responsible for transmitting signals to sweat glands.

(333) The postsynaptic neuron can have different types of postsynaptic potentials.

(334) The depolarizing voltage caused the neuron to transmit an electrical signal.

(335) The sensory neuron is connected to the motor neuron through the spinal cord.

(336) The sensory neuron is activated when a stimulus exceeds a certain threshold.

(337) Hyperpolarizing the neuron's membrane potential increased its resting state.

(338) The axoplasmic flow is regulated by the balance of forces within the neuron.

(339) The behavior of a neuron firing can be described using a stochastic process.

(340) Neurotransmitters can be reabsorbed by the presynaptic neuron after release.

(341) The size and shape of synaptosomes can vary depending on the type of neuron.

(342) The dendrites of a neuron can receive signals from thousands of other cells.

(343) The depolarization of a neuron can lead to the release of neurotransmitters.

(344) Axoplasmic streaming allows for the movement of organelles within the neuron.

(345) The depolarization of a neuron's membrane is followed by a refractory period.

(346) The function of a neuron is to transmit information from one cell to another.

(347) The postsynaptic neuron integrates signals from multiple presynaptic neurons.

(348) The electrotonic properties of a neuron can be influenced by synaptic inputs.

(349) The axonic neuron has unique properties that set it apart from other neurons.

(350) The sensory neuron is one of the basic building blocks of the nervous system.

(351) The sensory neuron is responsible for transmitting pain signals to the brain.

(352) The hyperpolarizing current decreased the neuron's responsiveness to stimuli.

(353) The end-plate of the neuron was responsible for initiating action potentials.

(354) Motor neuron disease is a condition that affects the function of motoneurons.

(355) An action-potential is a brief electrical signal that travels along a neuron.

(356) An afferent neuron carries sensory information to the central nervous system.

(357) The dendrites of a neuron can be affected by genetic mutations and disorders.

(358) The efferent neuron is responsible for transmitting signals to smooth muscles.

(359) The cell body is responsible for maintaining the overall health of the neuron.

(360) The internodal segments of the neuron were stained to visualize its structure.

(361) The endplate region is where the motor neuron and muscle fiber form a synapse.

(362) The hyperpolarizing stimulus caused the neuron to become more negative inside.

(363) Hyperpolarizing the neuron's membrane potential decreased its ability to fire.

(364) The repolarization phase is responsible for resetting the neuron after firing.

(365) The shape of depolarisations can provide information about the type of neuron.

(366) The synaptic protein was ubiquitinated by the neuron to regulate its turnover.

(367) The dendrites of a neuron can change shape and size in response to experience.

(368) The afferent neuron carries sensory information to the central nervous system.

(369) The efferent neuron is responsible for controlling the contraction of muscles.

(370) The efferent neuron is responsible for the body's response to light and sound.

(371) The efferent neuron is involved in the control of involuntary bodily functions.

(372) The axoplasmic reticulum plays a role in calcium homeostasis within the neuron.

(373) The action potential is initiated by a depolarization of the neuron's membrane.

(374) The refractory period of the neuron prevented it from firing again immediately.

(375) The postsynaptic neuron can have different types of neurotransmitter receptors.

(376) The cell body is responsible for the overall metabolic functions of the neuron.

(377) Researchers used a microelectrode to measure electrical activity in the neuron.

(378) Motor neuron diseases can progress at different rates in different individuals.

(379) Motor neuron disorders can be diagnosed through various tests and examinations.

(380) The afferent neuron is responsible for transmitting signals related to hearing.

(381) The afferent neuron carries signals related to balance and spatial orientation.

(382) Neuraxon is a term often used in neuroscience to refer to the axon of a neuron.

(383) The hyperpolarized state of the neuron allows for precise control of signaling.

(384) The protoplasmic activity of the neuron was studied to understand its function.

(385) The binding of an inhibitory ligand will hyperpolarize the postsynaptic neuron.

(386) Presynaptically, the neuron releases neurotransmitters into the synaptic cleft.

(387) The number of synaptic vesicles in a neuron can vary depending on its function.

(388) The refractory period allows for proper repolarization of the neuron's membrane.

(389) The postsynaptic neuron can have different types of synaptic adhesion molecules.

(390) The postsynaptic neuron can have different types of synaptic signaling pathways.

(391) The dendrite's complexity increases the neuron's ability to process information.

(392) Motor neuron disorders can affect both voluntary and involuntary muscle control.

(393) The early symptoms of motor neuron diseases can be subtle and easily overlooked.

(394) The axonic neuron is a subject of ongoing research in the field of neuroscience.

(395) The hyperpolarized condition of the neuron contributes to the refractory period.

(396) The depolarization of the neuron enabled the transmission of electrical signals.

(397) The end-plate of the neuron was sensitive to changes in neurotransmitter levels.

(398) The action-potential is a rapid depolarization and repolarization of the neuron.

(399) The protoplasmic structure of the neuron was studied to understand its function.

(400) The afferent neuron pathway is crucial for our sense of touch, taste, and smell.

(401) The efferent neuron is responsible for the body's response to hunger and thirst.

(402) The efferent neuron is responsible for the body's response to drugs and alcohol.

(403) Damage to the efferent neuron can disrupt the transmission of signals to muscles.

(404) The efferent neuron transmits information from the brain to the rest of the body.

(405) The depolarisation of a neuron allows for the propagation of an action potential.

(406) The septate structure of the neuron allows for efficient transmission of signals.

(407) Motor neuron diseases can be challenging to diagnose due to their complex nature.

(408) The afferent neuron carries signals related to muscle tension and joint position.

(409) The sensory neuron is capable of detecting even the slightest touch or vibration.

(410) The sensory neuron is responsible for our ability to detect pain and temperature.

(411) The eigenfrequency of the neuron's membrane potential determines its firing rate.

(412) The hyperpolarizing stimulus caused the neuron to become more negative in charge.

(413) The organic structure of a neuron enables the transmission of electrical signals.

(414) The behavior of a single neuron can have microcosmic effects on the entire brain.

(415) Hyperpolarizing the membrane potential can reduce the excitability of the neuron.

(416) The afferent neuron pathway is involved in our sense of balance and coordination.

(417) If the neuron depolarizes too much, it can lead to excitotoxicity and cell death.

(418) The efferent neuron is one of the two main types of neurons in the nervous system.

(419) The depolarization of a neuron's membrane is a key event in synaptic transmission.

(420) The resting potential of a neuron can be modulated by various signaling molecules.

(421) The postsynaptic neuron can have different types of neurotransmitter transporters.

(422) The postsynaptic neuron can have different types of synaptic scaffolding proteins.

(423) The endplate of the neuron is responsible for transmitting signals to other cells.

(424) The resting potential of a neuron can be affected by changes in temperature or pH.

(425) The electrotonic properties of a neuron can be affected by changes in temperature.

(426) Motor neuron diseases can have a significant impact on a person's quality of life.

(427) The axonic neuron is a specialized type of nerve cell found in the nervous system.

(428) The bistability of the neuron's membrane potential determines its firing behavior.

(429) The electrograph captured the precise timing of electrical impulses in the neuron.

(430) The dendrites of a neuron can be affected by aging and neurodegenerative diseases.

(431) The depolarization of a neuron can be caused by the binding of a neurotransmitter.

(432) The depolarization of a neuron can be influenced by the activity of other neurons.

(433) The depolarization of the neuron is essential for the transmission of information.

(434) The efferent neuron is responsible for the body's response to temperature changes.

(435) The presynaptically located axon terminal sends signals to the postsynaptic neuron.

(436) The postsynaptic neuron can have different types of synaptic plasticity mechanisms.

(437) The dendroid structure of the neuron allowed for efficient transmission of signals.

(438) The electrotonic potential of a neuron can be measured using specialized equipment.

(439) Hyperpolarizing the neuron's membrane potential increased its resistance to firing.

(440) Hyperpolarizing the neuron's membrane potential increased its threshold for firing.

(441) Action potentials are generated in the axon of a neuron and travel down its length.

(442) The efferent neuron is involved in the regulation of heart rate and blood pressure.

(443) The axonal growth cone guides the extension of the neuron's axon during development.

(444) Axoplasmic continuity allows for the rapid transmission of signals along the neuron.

(445) The cerebellar granule cells are the most abundant type of neuron in the cerebellum.

(446) Dendrites are the branch-like structures that extend from the cell body of a neuron.

(447) The time constant of a neuron determines the speed at which it can transmit signals.

(448) Electrical impulses generated by action potentials travel down the axon of a neuron.

(449) The hyperpolarizing effect of the neurotransmitter prevented the neuron from firing.

(450) Hyperpolarizing the neuron's membrane potential inhibited its ability to depolarize.

(451) The end-plate region is where the motor neuron and muscle fiber establish a synapse.

(452) The action-potential is a result of the movement of ions across the neuron membrane.

(453) The depolarized state of the neuron made it more likely to fire an action potential.

(454) The hyperpolarized state of a neuron can be induced by inhibitory neurotransmitters.

(455) The dendrites of a neuron can be affected by stress and other environmental factors.

(456) The depolarization of the neuron is caused by the influx of positively charged ions.

(457) The efferent neuron helps regulate bodily functions such as heart rate and digestion.

(458) The efferent neuron is crucial for the body's ability to respond to external stimuli.

(459) Action potentials are generated by the movement of ions across the neuron's membrane.

(460) The axon hillock is the region where the axon originates from the neuron's cell body.

(461) The speed at which neurons transmit signals can vary depending on the type of neuron.

(462) The perikaryon plays a crucial role in the transmission of signals within the neuron.

(463) The cell body is crucial for the transmission of electrical signals along the neuron.

(464) The dendrites of a neuron are responsible for receiving information from other cells.

(465) The dendrites of a neuron are covered in receptors that can detect neurotransmitters.

(466) The depolarization of a neuron can lead to the opening of voltage-gated ion channels.

(467) Axones are responsible for transmitting electrical signals from one neuron to another.

(468) The perikaryon is responsible for maintaining the electrical properties of the neuron.

(469) Resting potential is a state of readiness for a neuron to respond to incoming signals.

(470) The afferent neuron is responsible for transmitting signals related to proprioception.

(471) The arborescent structure of the neuron allowed for efficient transmission of signals.

(472) Re-uptake pumps actively transport neurotransmitters back into the presynaptic neuron.

(473) The axoplasmic transport system is responsible for moving materials within the neuron.

(474) The depolarized state of the neuron was necessary for the transmission of information.

(475) The hyperpolarized state of a neuron makes it less likely to fire an action potential.

(476) The afferent neuron pathway is responsible for our ability to detect changes in light.

(477) If the neuron depolarizes too frequently, it can lead to a state of hyperexcitability.

(478) The resting potential of a neuron can be altered by certain drugs or neurotransmitters.

(479) The depolarisation of a neuron is necessary for the integration of sensory information.

(480) Understanding the eigenmodes of a neuron can provide insights into its firing patterns.

(481) The electrotonic properties of a neuron can be affected by changes in extracellular pH.

(482) The physical structure of the neuron allowed for electrical impulses to be transmitted.

(483) The hyperpolarizing effect of the drug caused the neuron to become less likely to fire.

(484) The afferent neuron is responsible for transmitting signals from the body to the brain.

(485) The dendritical morphology of a neuron can vary depending on its location and function.

(486) The depolarization of the neuron is a key step in the process of synaptic transmission.

(487) The depolarization of the neuron is followed by the propagation of an action potential.

(488) The axonal membrane is responsible for transmitting electrical signals along the neuron.

(489) Axoplasmic continuity allows for the propagation of electrical signals along the neuron.

(490) The resting potential of a neuron is a result of the activity of ion pumps and channels.

(491) The electrotonic properties of a neuron can be altered by changes in membrane potential.

(492) The ramous structure of the neuron allowed for efficient communication within the brain.

(493) The hyperpolarizing stimulus caused the neuron to become more inhibited in its activity.

(494) The axoplasmic streaming allows for the distribution of molecules throughout the neuron.

(495) The axoplasmic streaming is essential for the removal of waste products from the neuron.

(496) Neurotransmission allows for the transmission of information from one neuron to another.

(497) If active transport is blocked, the neuron may not be able to transmit signals properly.

(498) The efferent neuron is one of the two types of neurons in the peripheral nervous system.

(499) The dendriform structure of the neuron allowed for efficient communication in the brain.

(500) The dendrites of a neuron are covered in tiny spines that help to increase surface area.

(501) The depolarization of the neuron is necessary for the initiation of an action potential.

(502) The axoplasmic matrix provides a medium for the diffusion of molecules within the neuron.

(503) The refractory period is a key factor in determining the maximum firing rate of a neuron.

(504) Resting potential is an important factor in determining the firing threshold of a neuron.

(505) The resting potential of a neuron can be influenced by the activity of neurotransmitters.

(506) The presence of a positive Babinski sign is pathognomonic for upper motor neuron disease.

(507) The depolarisation of a neuron is a rapid and transient change in its membrane potential.

(508) The endplate region is where the motor neuron and muscle fiber come into close proximity.

(509) The resting potential of a neuron can be influenced by the activity of neighboring cells.

(510) The electrotonic properties of a neuron can be modulated by changes in synaptic strength.

(511) The axoplasmic transport of mitochondria is important for providing energy to the neuron.

(512) If the neuron depolarizes too slowly, it may not be able to generate an action potential.

(513) The depolarization of a neuron's membrane is a fundamental step in information processing.

(514) The action potential is a rapid change in electrical potential across a neuron's membrane.

(515) The electrotonic properties of a neuron can be altered by changes in membrane capacitance.

(516) The afferent neuron is responsible for transmitting signals to the central nervous system.

(517) The afferent neuron is responsible for transmitting signals related to the sense of taste.

(518) Hyperpolarizing the cell made it less likely for the neuron to reach the firing threshold.

(519) The end-plate region is where the motor neuron and muscle fiber come into close proximity.

(520) The motor end plate receives signals from the motor neuron, initiating muscle contraction.

(521) The neuraxon is highly specialized and can vary in length depending on the type of neuron.

(522) The ganglionic synapse is where nerve impulses are transmitted from one neuron to another.

(523) The dendritical spines on the neuron's surface play a crucial role in synaptic plasticity.

(524) Hyperpolarizing the neuron can be achieved through the activation of certain ion channels.

(525) Depolarization is a rapid and reversible change in the electrical potential of the neuron.

(526) The depolarization of the neuron is a result of the opening of voltage-gated ion channels.

(527) Neurilemmoma is derived from the Greek words neuron meaning nerve and lemma meaning sheath.

(528) The depolarization of a neuron's membrane is necessary for the transmission of information.

(529) The arborized structure of the neuron allowed for efficient communication within the brain.

(530) The electrotonic properties of a neuron can be modulated by changes in membrane resistance.

(531) The dendritic structure of a neuron allows for efficient communication between brain cells.

(532) The hyperpolarizing current inhibited the neuron's ability to generate an action potential.

(533) Action potentials can propagate along the axon of a neuron without loss of signal strength.

(534) The bistable nature of a neuron's membrane potential is crucial for information processing.

(535) The presence of a positive Babinski reflex is pathognomonic for upper motor neuron disease.

(536) The depolarized state of the neuron was caused by the opening of ligand-gated ion channels.

(537) The biology class learned about the nervous system by studying the circuit around a neuron.

(538) When the neuron depolarizes, it sends an electrical signal to the next neuron in the chain.

(539) The plasm of a neuron cell allows for the transmission of information in the nervous system.

(540) The resting potential of a neuron can be influenced by the activity of other nearby neurons.

(541) The presynaptically released neurotransmitters bind to receptors on the postsynaptic neuron.

(542) The electrotonic properties of a neuron can be modulated by changes in membrane conductance.

(543) The presynaptic terminal is responsible for transmitting signals to the postsynaptic neuron.

(544) The depolarization of the neuron is a critical step in the process of synaptic transmission.

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

(546) The efferent neuron is crucial for the body's ability to move and respond to its environment.

(547) The plantar reflex can be used to differentiate between upper and lower motor neuron lesions.

(548) The refractory period is influenced by the activity of ion channels in the neuron's membrane.

(549) Hyperpolarizing the cell made it more difficult for the neuron to reach the firing threshold.

(550) The hyperpolarizing effect of the neurotransmitter prevented the neuron from becoming active.

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