Peptide: protein formed by a chain of animated acids. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/peptide-protein-formed-by-a-chain-of-animated-acids-image476923677.html
RF2JKWN0D–Peptide: protein formed by a chain of animated acids.
Influenza viruses and proteins that bind to host cells. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/influenza-viruses-and-proteins-that-bind-to-host-cells-image476924249.html
RF2JKWNMW–Influenza viruses and proteins that bind to host cells.
Influenza viruses and proteins that bind to host cells. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/influenza-viruses-and-proteins-that-bind-to-host-cells-image476924240.html
RF2JKWNMG–Influenza viruses and proteins that bind to host cells.
Influenza viruses and proteins that bind to host cells. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/influenza-viruses-and-proteins-that-bind-to-host-cells-image476924251.html
RF2JKWNMY–Influenza viruses and proteins that bind to host cells.
Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/ligand-dependent-ion-channel-attachment-of-a-particular-molecule-causes-the-channel-to-open-image476926586.html
RF2JKWTMA–Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open.
DNA transcription for protein production and translation. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/dna-transcription-for-protein-production-and-translation-image476925838.html
RF2JKWRNJ–DNA transcription for protein production and translation.
Detail representing the synthesis of a protein from messenger RNA. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/detail-representing-the-synthesis-of-a-protein-from-messenger-rna-image476925041.html
RF2JKWPN5–Detail representing the synthesis of a protein from messenger RNA.
Detail representing the synthesis of a protein from messenger RNA. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/detail-representing-the-synthesis-of-a-protein-from-messenger-rna-image476925043.html
RF2JKWPN7–Detail representing the synthesis of a protein from messenger RNA.
Cytokines and inflammatory response Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/cytokines-and-inflammatory-response-image466107158.html
Displacement of the action potential (influx) in the synapse. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/displacement-of-the-action-potential-influx-in-the-synapse-image476925671.html
RF2JKWRFK–Displacement of the action potential (influx) in the synapse.
Supply of glucose to muscle cells via transporters. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/supply-of-glucose-to-muscle-cells-via-transporters-image476925319.html
RF2JKWR33–Supply of glucose to muscle cells via transporters.
Phototransduction: operation of a photoreceptor in night vision. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/phototransduction-operation-of-a-photoreceptor-in-night-vision-image476926568.html
RF2JKWTKM–Phototransduction: operation of a photoreceptor in night vision.
Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/ligand-dependent-ion-channel-attachment-of-a-particular-molecule-causes-the-channel-to-open-image476926610.html
RF2JKWTN6–Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open.
Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/ligand-dependent-ion-channel-attachment-of-a-particular-molecule-causes-the-channel-to-open-image476926565.html
RF2JKWTKH–Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open.
Transmission of nerve impulses and zoom on a synapse. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-and-zoom-on-a-synapse-image476925673.html
RF2JKWRFN–Transmission of nerve impulses and zoom on a synapse.
Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/contracted-myofibril-made-up-of-myofilaments-and-proteins-allowing-muscle-contraction-image476923536.html
RF2JKWMRC–Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction.
Antibody (immunoglobin E) with light and heavy chain binding site. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/antibody-immunoglobin-e-with-light-and-heavy-chain-binding-site-image476924789.html
RF2JKWPC5–Antibody (immunoglobin E) with light and heavy chain binding site.
Supply of glucose to muscle cells via transporters. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/supply-of-glucose-to-muscle-cells-via-transporters-image476925383.html
RF2JKWR5B–Supply of glucose to muscle cells via transporters.
Antibody (immunoglobin E) with light and heavy chain binding site. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/antibody-immunoglobin-e-with-light-and-heavy-chain-binding-site-image476924749.html
RF2JKWPAN–Antibody (immunoglobin E) with light and heavy chain binding site.
Transmission of nerve impulses from neuron A to neuron B with zoom on a synapse. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-from-neuron-a-to-neuron-b-with-zoom-on-a-synapse-image476924918.html
RF2JKWPGP–Transmission of nerve impulses from neuron A to neuron B with zoom on a synapse.
Resting myofibril made up of fine (actin) and thick (myosin) filaments. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/resting-myofibril-made-up-of-fine-actin-and-thick-myosin-filaments-image476924684.html
RF2JKWP8C–Resting myofibril made up of fine (actin) and thick (myosin) filaments.
Muscle fiber showing the myofibrils made up of myofilaments (actin and myosin). Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/muscle-fiber-showing-the-myofibrils-made-up-of-myofilaments-actin-and-myosin-image476924763.html
RF2JKWPB7–Muscle fiber showing the myofibrils made up of myofilaments (actin and myosin).
Sensory receptors: Information reaches the sensory cell through an ion channel. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/sensory-receptors-information-reaches-the-sensory-cell-through-an-ion-channel-image476926541.html
RF2JKWTJN–Sensory receptors: Information reaches the sensory cell through an ion channel.
Viral invasion: Viruses attach themselves to the surface of the host cell. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/viral-invasion-viruses-attach-themselves-to-the-surface-of-the-host-cell-image476924369.html
RF2JKWNW5–Viral invasion: Viruses attach themselves to the surface of the host cell.
From muscle to muscle fiber: tendon, muscle, muscle fiber. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/from-muscle-to-muscle-fiber-tendon-muscle-muscle-fiber-image476923888.html
RF2JKWN80–From muscle to muscle fiber: tendon, muscle, muscle fiber.
Phototransduction: functioning of a photoreceptor in daytime vision. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/phototransduction-functioning-of-a-photoreceptor-in-daytime-vision-image476926600.html
RF2JKWTMT–Phototransduction: functioning of a photoreceptor in daytime vision.
From muscle to muscle fiber: tendon, muscle, muscle fiber. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/from-muscle-to-muscle-fiber-tendon-muscle-muscle-fiber-image476923885.html
RF2JKWN7W–From muscle to muscle fiber: tendon, muscle, muscle fiber.
Phototransduction: operation of a photoreceptor in night vision. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/phototransduction-operation-of-a-photoreceptor-in-night-vision-image476926607.html
RF2JKWTN3–Phototransduction: operation of a photoreceptor in night vision.
Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/tactile-receptor-associated-with-a-hair-follicle-the-movement-of-the-hair-causes-the-opening-of-the-receptor-channel-image476926597.html
RF2JKWTMN–Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel.
Supply of glucose to muscle cells via transporters. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/supply-of-glucose-to-muscle-cells-via-transporters-image476925678.html
RF2JKWRFX–Supply of glucose to muscle cells via transporters.
Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/contracted-myofibril-made-up-of-myofilaments-and-proteins-allowing-muscle-contraction-image476923526.html
RF2JKWMR2–Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction.
Neuron: transmission of pain in the spinal cord. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/neuron-transmission-of-pain-in-the-spinal-cord-image476924481.html
RF2JKWP15–Neuron: transmission of pain in the spinal cord.
Transmission of nerve impulses in a synapse between two neurons. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-in-a-synapse-between-two-neurons-image476924345.html
RF2JKWNT9–Transmission of nerve impulses in a synapse between two neurons.
Muscle bundle made up of several largely vascularized muscle fibers. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/muscle-bundle-made-up-of-several-largely-vascularized-muscle-fibers-image476924710.html
RF2JKWP9A–Muscle bundle made up of several largely vascularized muscle fibers.
Transmission of nerve impulses from neuron A to neuron B with zoom on a synapse. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-from-neuron-a-to-neuron-b-with-zoom-on-a-synapse-image476924886.html
RF2JKWPFJ–Transmission of nerve impulses from neuron A to neuron B with zoom on a synapse.
Asthma: sensitization phase during the first contact with the allergen. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/asthma-sensitization-phase-during-the-first-contact-with-the-allergen-image476926205.html
RF2JKWT6N–Asthma: sensitization phase during the first contact with the allergen.
Resting myofibril made up of fine (actin) and thick (myosin) filaments. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/resting-myofibril-made-up-of-fine-actin-and-thick-myosin-filaments-image476924745.html
RF2JKWPAH–Resting myofibril made up of fine (actin) and thick (myosin) filaments.
PLT (Long Term Potentiation) after one week, step 2: the synapse is stimulated with greater efficiency. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/plt-long-term-potentiation-after-one-week-step-2-the-synapse-is-stimulated-with-greater-efficiency-image476925654.html
RF2JKWRF2–PLT (Long Term Potentiation) after one week, step 2: the synapse is stimulated with greater efficiency.
Antibody (immunoglobin E) with light and heavy chain binding site. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/antibody-immunoglobin-e-with-light-and-heavy-chain-binding-site-image476924728.html
RF2JKWPA0–Antibody (immunoglobin E) with light and heavy chain binding site.
Transmission of nerve impulses from a synapse of a neuron A to a dendritic button. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-from-a-synapse-of-a-neuron-a-to-a-dendritic-button-image476925910.html
RF2JKWRT6–Transmission of nerve impulses from a synapse of a neuron A to a dendritic button.
Pain path and its inhibition in the spinal cord. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/pain-path-and-its-inhibition-in-the-spinal-cord-image476924857.html
RF2JKWPEH–Pain path and its inhibition in the spinal cord.
Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/contracted-myofibril-made-up-of-myofilaments-and-proteins-allowing-muscle-contraction-image476923539.html
RF2JKWMRF–Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction.
Influenza viruses and proteins that bind to host cells. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/influenza-viruses-and-proteins-that-bind-to-host-cells-image476924261.html
RF2JKWNN9–Influenza viruses and proteins that bind to host cells.
Antibody (immunoglobin E) with light and heavy chain binding site. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/antibody-immunoglobin-e-with-light-and-heavy-chain-binding-site-image476924729.html
RF2JKWPA1–Antibody (immunoglobin E) with light and heavy chain binding site.
Transmission of nerve impulses from a synapse of a neuron A to a dendritic button. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-from-a-synapse-of-a-neuron-a-to-a-dendritic-button-image476925848.html
RF2JKWRP0–Transmission of nerve impulses from a synapse of a neuron A to a dendritic button.
Transmission of nerve impulses in a synapse between two neurons. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-in-a-synapse-between-two-neurons-image476924313.html
RF2JKWNR5–Transmission of nerve impulses in a synapse between two neurons.
Transmission of nerve impulses from a synapse of neuron A to neuron B. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-from-a-synapse-of-neuron-a-to-neuron-b-image476925750.html
RF2JKWRJE–Transmission of nerve impulses from a synapse of neuron A to neuron B.
Striated muscle structure with bundles, muscle fibers, myofibers and microfilaments. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/striated-muscle-structure-with-bundles-muscle-fibers-myofibers-and-microfilaments-image476925381.html
RF2JKWR59–Striated muscle structure with bundles, muscle fibers, myofibers and microfilaments.
Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/tactile-receptor-associated-with-a-hair-follicle-the-movement-of-the-hair-causes-the-opening-of-the-receptor-channel-image476926602.html
RF2JKWTMX–Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel.
Movement of the action potential (impulse) in the axon of the neuron and from one neuron to another. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/movement-of-the-action-potential-impulse-in-the-axon-of-the-neuron-and-from-one-neuron-to-another-image476924920.html
RF2JKWPGT–Movement of the action potential (impulse) in the axon of the neuron and from one neuron to another.
Influenza viruses and proteins that bind to host cells. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/influenza-viruses-and-proteins-that-bind-to-host-cells-image476924258.html
RF2JKWNN6–Influenza viruses and proteins that bind to host cells.
Nerve impulse: central nervous system neural network with zoom on Ranvier's node. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/nerve-impulse-central-nervous-system-neural-network-with-zoom-on-ranviers-node-image476925506.html
RF2JKWR9P–Nerve impulse: central nervous system neural network with zoom on Ranvier's node.
Transmission of nerve impulses in a synapse between two neurons. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-in-a-synapse-between-two-neurons-image476924370.html
RF2JKWNW6–Transmission of nerve impulses in a synapse between two neurons.
Influenza viruses and proteins that bind to host cells. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/influenza-viruses-and-proteins-that-bind-to-host-cells-image476924245.html
RF2JKWNMN–Influenza viruses and proteins that bind to host cells.
Displacement of the action potential (influx) in the synapse. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/displacement-of-the-action-potential-influx-in-the-synapse-image476925699.html
RF2JKWRGK–Displacement of the action potential (influx) in the synapse.
PLT (Long Term Potentiation) after one week, step 2: the synapse is stimulated with greater efficiency. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/plt-long-term-potentiation-after-one-week-step-2-the-synapse-is-stimulated-with-greater-efficiency-image476925650.html
RF2JKWREX–PLT (Long Term Potentiation) after one week, step 2: the synapse is stimulated with greater efficiency.
Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/contracted-myofibril-made-up-of-myofilaments-and-proteins-allowing-muscle-contraction-image476923532.html
RF2JKWMR8–Contracted myofibril, made up of myofilaments and proteins, allowing muscle contraction.
Phototransduction: functioning of a photoreceptor in daytime vision. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/phototransduction-functioning-of-a-photoreceptor-in-daytime-vision-image476926547.html
RF2JKWTJY–Phototransduction: functioning of a photoreceptor in daytime vision.
Schematic of any virus with DNA strands inside. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/schematic-of-any-virus-with-dna-strands-inside-image476923887.html
RF2JKWN7Y–Schematic of any virus with DNA strands inside.
Sensory receptors: Information reaches the sensory cell through an ion channel. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/sensory-receptors-information-reaches-the-sensory-cell-through-an-ion-channel-image476926580.html
RF2JKWTM4–Sensory receptors: Information reaches the sensory cell through an ion channel.
Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/tactile-receptor-associated-with-a-hair-follicle-the-movement-of-the-hair-causes-the-opening-of-the-receptor-channel-image476926558.html
RF2JKWTKA–Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel.
Viral invasion: Viruses attach themselves to the surface of the host cell. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/viral-invasion-viruses-attach-themselves-to-the-surface-of-the-host-cell-image476924334.html
RF2JKWNRX–Viral invasion: Viruses attach themselves to the surface of the host cell.
Nerve impulse: central nervous system neural network with zoom on Ranvier's node. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/nerve-impulse-central-nervous-system-neural-network-with-zoom-on-ranviers-node-image476925498.html
RF2JKWR9E–Nerve impulse: central nervous system neural network with zoom on Ranvier's node.
Viral invasion: Viruses attach themselves to the surface of the host cell. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/viral-invasion-viruses-attach-themselves-to-the-surface-of-the-host-cell-image476924262.html
RF2JKWNNA–Viral invasion: Viruses attach themselves to the surface of the host cell.
PTL (Long Term Potentiation), step 1: massive release of glutamate by the presynaptic element. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/ptl-long-term-potentiation-step-1-massive-release-of-glutamate-by-the-presynaptic-element-image476925646.html
RF2JKWREP–PTL (Long Term Potentiation), step 1: massive release of glutamate by the presynaptic element.
Schematic of any virus with DNA strands inside. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/schematic-of-any-virus-with-dna-strands-inside-image476923893.html
RF2JKWN85–Schematic of any virus with DNA strands inside.
PTL (Long Term Potentiation), step 1: massive release of glutamate by the presynaptic element. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/ptl-long-term-potentiation-step-1-massive-release-of-glutamate-by-the-presynaptic-element-image476925691.html
RF2JKWRGB–PTL (Long Term Potentiation), step 1: massive release of glutamate by the presynaptic element.
Neuron: transmission of pain in the spinal cord. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/neuron-transmission-of-pain-in-the-spinal-cord-image476924452.html
RF2JKWP04–Neuron: transmission of pain in the spinal cord.
Depolarization: phospholipid membrane with NA + and K + ion channels. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/depolarization-phospholipid-membrane-with-na-and-k-ion-channels-image476926035.html
RF2JKWT0K–Depolarization: phospholipid membrane with NA + and K + ion channels.
Transmission of nerve impulses in a synapse between two neurons. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-in-a-synapse-between-two-neurons-image476924338.html
RF2JKWNT2–Transmission of nerve impulses in a synapse between two neurons.
Transmission of nerve impulses and zoom on a synapse. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transmission-of-nerve-impulses-and-zoom-on-a-synapse-image476925718.html
RF2JKWRHA–Transmission of nerve impulses and zoom on a synapse.
Pain path and its inhibition in the spinal cord. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/pain-path-and-its-inhibition-in-the-spinal-cord-image476924802.html
RF2JKWPCJ–Pain path and its inhibition in the spinal cord.
Muscle fiber showing the myofibrils made up of myofilaments (actin and myosin). Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/muscle-fiber-showing-the-myofibrils-made-up-of-myofilaments-actin-and-myosin-image476924717.html
RF2JKWP9H–Muscle fiber showing the myofibrils made up of myofilaments (actin and myosin).
Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/ligand-dependent-ion-channel-attachment-of-a-particular-molecule-causes-the-channel-to-open-image476926555.html
RF2JKWTK7–Ligand-dependent ion channel: attachment of a particular molecule causes the channel to open.
Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/tactile-receptor-associated-with-a-hair-follicle-the-movement-of-the-hair-causes-the-opening-of-the-receptor-channel-image476926577.html
RF2JKWTM1–Tactile receptor associated with a hair follicle: the movement of the hair causes the opening of the receptor-channel.
Depolarization: phospholipid membrane with NA + and K + ion channels. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/depolarization-phospholipid-membrane-with-na-and-k-ion-channels-image476926080.html
RF2JKWT28–Depolarization: phospholipid membrane with NA + and K + ion channels.
Coronavirus, binding to the host cell, protein S, ACE2 receptor. The coronavirus (in green, red and yellow), here of the SARS-COV2 type, responsible f Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/coronavirus-binding-to-the-host-cell-protein-s-ace2-receptor-the-coronavirus-in-green-red-and-yellow-here-of-the-sars-cov2-type-responsible-f-image355210340.html
RM2BHW6BG–Coronavirus, binding to the host cell, protein S, ACE2 receptor. The coronavirus (in green, red and yellow), here of the SARS-COV2 type, responsible f
PLT (Long-Term Potentiation), step 3: new connections are formed for long-term memory. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/plt-long-term-potentiation-step-3-new-connections-are-formed-for-long-term-memory-image476925721.html
RF2JKWRHD–PLT (Long-Term Potentiation), step 3: new connections are formed for long-term memory.
PLT (Long-Term Potentiation), step 3: new connections are formed for long-term memory. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/plt-long-term-potentiation-step-3-new-connections-are-formed-for-long-term-memory-image476925634.html
RF2JKWREA–PLT (Long-Term Potentiation), step 3: new connections are formed for long-term memory.
Use of glucose by bacteria to produce proteins. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/use-of-glucose-by-bacteria-to-produce-proteins-image476925460.html
RF2JKWR84–Use of glucose by bacteria to produce proteins.
Transcription of DNA into messenger RNA and its translation. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transcription-of-dna-into-messenger-rna-and-its-translation-image476923756.html
RF2JKWN38–Transcription of DNA into messenger RNA and its translation.
Transcription of DNA into messenger RNA and its translation. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transcription-of-dna-into-messenger-rna-and-its-translation-image476923743.html
RF2JKWN2R–Transcription of DNA into messenger RNA and its translation.
Use of glucose by bacteria to produce proteins. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/use-of-glucose-by-bacteria-to-produce-proteins-image476925434.html
RF2JKWR76–Use of glucose by bacteria to produce proteins.
Peptide synthesis in bacteria: synthesis by ribosomal route (left) and other syntheses (right). Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/peptide-synthesis-in-bacteria-synthesis-by-ribosomal-route-left-and-other-syntheses-right-image476925485.html
RF2JKWR91–Peptide synthesis in bacteria: synthesis by ribosomal route (left) and other syntheses (right).
Peptide synthesis: synthesis by ribosomes of amino acids from messenger RNA. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/peptide-synthesis-synthesis-by-ribosomes-of-amino-acids-from-messenger-rna-image476926071.html
RF2JKWT1Y–Peptide synthesis: synthesis by ribosomes of amino acids from messenger RNA.
Transcription (left) and duplication (right) from the DNA of a bacterium. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transcription-left-and-duplication-right-from-the-dna-of-a-bacterium-image476925388.html
RF2JKWR5G–Transcription (left) and duplication (right) from the DNA of a bacterium.
Peptide synthesis: synthesis by ribosomes of amino acids from messenger RNA. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/peptide-synthesis-synthesis-by-ribosomes-of-amino-acids-from-messenger-rna-image476926092.html
RF2JKWT2M–Peptide synthesis: synthesis by ribosomes of amino acids from messenger RNA.
Genes: nucleus of a cell with chromosome, chromatin, DNA helix, genes, ribosome, proteins. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/genes-nucleus-of-a-cell-with-chromosome-chromatin-dna-helix-genes-ribosome-proteins-image476925756.html
RF2JKWRJM–Genes: nucleus of a cell with chromosome, chromatin, DNA helix, genes, ribosome, proteins.
Transcription of DNA into messenger RNA and its translation. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/transcription-of-dna-into-messenger-rna-and-its-translation-image476923724.html
RF2JKWN24–Transcription of DNA into messenger RNA and its translation.
Genes: nucleus of a cell with chromosome, chromatin, DNA helix, genes, ribosome, proteins. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/genes-nucleus-of-a-cell-with-chromosome-chromatin-dna-helix-genes-ribosome-proteins-image476925690.html
RF2JKWRGA–Genes: nucleus of a cell with chromosome, chromatin, DNA helix, genes, ribosome, proteins.
Interfering RNA, step 3: the double-stranded RNA is cut into nucleotide fragments by the Dicer protein. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/interfering-rna-step-3-the-double-stranded-rna-is-cut-into-nucleotide-fragments-by-the-dicer-protein-image476925238.html
RF2JKWR06–Interfering RNA, step 3: the double-stranded RNA is cut into nucleotide fragments by the Dicer protein.
Interfering RNA, step 3: the double-stranded RNA is cut into nucleotide fragments by the Dicer protein. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/interfering-rna-step-3-the-double-stranded-rna-is-cut-into-nucleotide-fragments-by-the-dicer-protein-image476925246.html
RF2JKWR0E–Interfering RNA, step 3: the double-stranded RNA is cut into nucleotide fragments by the Dicer protein.
Interfering RNA, step 4: the RISC complex binds to the Dicer protein and to the double-stranded RNA fragment. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/interfering-rna-step-4-the-risc-complex-binds-to-the-dicer-protein-and-to-the-double-stranded-rna-fragment-image476925244.html
RF2JKWR0C–Interfering RNA, step 4: the RISC complex binds to the Dicer protein and to the double-stranded RNA fragment.
RNA interferen, step 4: the RISC complex binds to the Dicer protein and to the double-stranded RNA fragment. Stock Photohttps://www.alamy.com/licenses-and-pricing/?v=1https://www.alamy.com/rna-interferen-step-4-the-risc-complex-binds-to-the-dicer-protein-and-to-the-double-stranded-rna-fragment-image476925295.html
RF2JKWR27–RNA interferen, step 4: the RISC complex binds to the Dicer protein and to the double-stranded RNA fragment.
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