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Synaptid skin under a microscope; Synaptid (Synapta digitata) Polarized light illumination with X 200 magnification.Synaptid skin under a microscope; Synaptid (Synapta digitata) Polarized light illumination with X 200 magnification.Synaptid skin under a microscope; Synaptid (Synapta digitata) Polarized light illumination with X 200 magnification.© Christian Gautier / BiosphotoJPG - RM

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Synaptid skin under a microscope; Synaptid (Synapta digitata)

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Transversal cut of a spine of sea urchin  ; Lighting in bright background, magnification x 40. Colors by computer processing.Transversal cut of a spine of sea urchin Transversal cut of a spine of sea urchin  ; Lighting in bright background, magnification x 40. Colors by computer processing.© Christian Gautier / BiosphotoJPG - RM

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Transversal cut of a spine of sea urchin  ; Lighting in bright

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Sponge spicules Chondrilla nucula polarized light Sponge spicules Chondrilla nucula polarized light Sponge spicules Chondrilla nucula polarized light © Christian Gautier / BiosphotoJPG - RM

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Sponge spicules Chondrilla nucula polarized light 

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Microscopic view of moss branch Tortula papillosa Microscopic view of moss branch Tortula papillosa Microscopic view of moss branch Tortula papillosa © Christian Gautier / BiosphotoJPG - RM

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Microscopic view of moss branch Tortula papillosa 

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Spicules of sea cuncumber under microscope ; Lighting in polarized light with blade compensatory gypsum, magnified x 100. Spicules of sea cuncumber under microscopeSpicules of sea cuncumber under microscope ; Lighting in polarized light with blade compensatory gypsum, magnified x 100. © Christian Gautier / BiosphotoJPG - RM

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Spicules of sea cuncumber under microscope ; Lighting in

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Royal Farlowella (Sturisomatichthys aureus) eggs after 130 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 130 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 130 h of incubation© Aqua Press / BiosphotoJPG - RMNon exclusive sale

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Royal Farlowella (Sturisomatichthys aureus) eggs after 130 h of

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Royal Farlowella (Sturisomatichthys aureus) eggs after 84 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 84 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 84 h of incubation© Aqua Press / BiosphotoJPG - RMNon exclusive sale

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Royal Farlowella (Sturisomatichthys aureus) eggs after 84 h of

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Royal Farlowella (Sturisomatichthys aureus) eggs after 60 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 60 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 60 h of incubation© Aqua Press / BiosphotoJPG - RMNon exclusive sale

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Royal Farlowella (Sturisomatichthys aureus) eggs after 60 h of

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Royal Farlowella (Sturisomatichthys aureus) eggs after 60 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 60 h of incubationRoyal Farlowella (Sturisomatichthys aureus) eggs after 60 h of incubation© Aqua Press / BiosphotoJPG - RMNon exclusive sale

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Royal Farlowella (Sturisomatichthys aureus) eggs after 60 h of

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Tara Oceans Expeditions - May 2011. Chaetognaths and copepods. Living plancton, photographed on board Tara; Photo (M): Christoph Gerigk/CNRS/TaraexpeditionsTara Oceans Expeditions - May 2011. Chaetognaths and copepods. Living plancton, photographed on board Tara; Photo (M): Christoph Gerigk/CNRS/TaraexpeditionsTara Oceans Expeditions - May 2011. Chaetognaths and copepods. Living plancton, photographed on board Tara; Photo (M): Christoph Gerigk/CNRS/Taraexpeditions© Christoph Gerigk / BiosphotoJPG - RM

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Tara Oceans Expeditions - May 2011. Chaetognaths and copepods.

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Zebrafish, Danio rerio, fry on aquarium. Since the 1930s, zebra fish have been a model organism for studying human diseases. The fertilized eggs, embryos, and fry are transparent, allowing scientists to easily observe and study topics such as tumor growth, brain tissue development, and blood vessel growth. PortugalZebrafish, Danio rerio, fry on aquarium. Since the 1930s, zebra fish have been a model organism for studying human diseases. The fertilized eggs, embryos, and fry are transparent, allowing scientists to easily observe and study topics such as tumor growth, brain tissue development, and blood vessel growth. PortugalZebrafish, Danio rerio, fry on aquarium. Since the 1930s, zebra fish have been a model organism for studying human diseases. The fertilized eggs, embryos, and fry are transparent, allowing scientists to easily observe and study topics such as tumor growth, brain tissue development, and blood vessel growth. Portugal© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Zebrafish, Danio rerio, fry on aquarium. Since the 1930s, zebra

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Microinjection of Zebrafish (Danio rerio) embryos to analyse gene function. Embryo being micro-injected into the yolk with RNA (ribonucleic acid) mixed with a red dye. One of the advantages of studying zebrafish is the ease with which specific gene products can be added to or eliminated from the embryo by microinjection. Morpholinos, which are synthetic oligonucleotides with antisense complementarity to target RNAs, can be added to the embryo to reduce the expression of a particular gene product. USAMicroinjection of Zebrafish (Danio rerio) embryos to analyse gene function. Embryo being micro-injected into the yolk with RNA (ribonucleic acid) mixed with a red dye. One of the advantages of studying zebrafish is the ease with which specific gene products can be added to or eliminated from the embryo by microinjection. Morpholinos, which are synthetic oligonucleotides with antisense complementarity to target RNAs, can be added to the embryo to reduce the expression of a particular gene product. USAMicroinjection of Zebrafish (Danio rerio) embryos to analyse gene function. Embryo being micro-injected into the yolk with RNA (ribonucleic acid) mixed with a red dye. One of the advantages of studying zebrafish is the ease with which specific gene products can be added to or eliminated from the embryo by microinjection. Morpholinos, which are synthetic oligonucleotides with antisense complementarity to target RNAs, can be added to the embryo to reduce the expression of a particular gene product. USA© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Microinjection of Zebrafish (Danio rerio) embryos to analyse gene

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Marine fish larvae eat microplastics. Small pieces of plastic, termed “micro plastic” in the oceans derive mainly from degradation of big plastics such as beach littering, but also from sources of direct emission from example beauty scrubbers and synthetic sand-blasting. These micro plastics are ingested by marine animals –mistaking them for plankton – or via prey. When ingested, the particles affect the animals due to their physical properties and their chemical properties (the plastic polymer itself and additives) and persistent organic pollutants (POPs) gathered on their surface. The latter because micro plastics have a large hydrophobic surface, which accumulate POPs to a great extent, on micro plastics than in the surrounding water.Marine fish larvae eat microplastics. Small pieces of plastic, termed “micro plastic” in the oceans derive mainly from degradation of big plastics such as beach littering, but also from sources of direct emission from example beauty scrubbers and synthetic sand-blasting. These micro plastics are ingested by marine animals –mistaking them for plankton – or via prey. When ingested, the particles affect the animals due to their physical properties and their chemical properties (the plastic polymer itself and additives) and persistent organic pollutants (POPs) gathered on their surface. The latter because micro plastics have a large hydrophobic surface, which accumulate POPs to a great extent, on micro plastics than in the surrounding water.Marine fish larvae eat microplastics. Small pieces of plastic, termed “micro plastic” in the oceans derive mainly from degradation of big plastics such as beach littering, but also from sources of direct emission from example beauty scrubbers and synthetic sand-blasting. These micro plastics are ingested by marine animals –mistaking them for plankton – or via prey. When ingested, the particles affect the animals due to their physical properties and their chemical properties (the plastic polymer itself and additives) and persistent organic pollutants (POPs) gathered on their surface. The latter because micro plastics have a large hydrophobic surface, which accumulate POPs to a great extent, on micro plastics than in the surrounding water.© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Marine fish larvae eat microplastics. Small pieces of plastic,

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Marine fish larvae eat microplastics. Small pieces of plastic, termed “micro plastic” in the oceans derive mainly from degradation of big plastics such as beach littering, but also from sources of direct emission from example beauty scrubbers and synthetic sand-blasting. These micro plastics are ingested by marine animals –mistaking them for plankton – or via prey. When ingested, the particles affect the animals due to their physical properties and their chemical properties (the plastic polymer itself and additives) and persistent organic pollutants (POPs) gathered on their surface. The latter because micro plastics have a large hydrophobic surface, which accumulate POPs to a great extent, on micro plastics than in the surrounding water.Marine fish larvae eat microplastics. Small pieces of plastic, termed “micro plastic” in the oceans derive mainly from degradation of big plastics such as beach littering, but also from sources of direct emission from example beauty scrubbers and synthetic sand-blasting. These micro plastics are ingested by marine animals –mistaking them for plankton – or via prey. When ingested, the particles affect the animals due to their physical properties and their chemical properties (the plastic polymer itself and additives) and persistent organic pollutants (POPs) gathered on their surface. The latter because micro plastics have a large hydrophobic surface, which accumulate POPs to a great extent, on micro plastics than in the surrounding water.Marine fish larvae eat microplastics. Small pieces of plastic, termed “micro plastic” in the oceans derive mainly from degradation of big plastics such as beach littering, but also from sources of direct emission from example beauty scrubbers and synthetic sand-blasting. These micro plastics are ingested by marine animals –mistaking them for plankton – or via prey. When ingested, the particles affect the animals due to their physical properties and their chemical properties (the plastic polymer itself and additives) and persistent organic pollutants (POPs) gathered on their surface. The latter because micro plastics have a large hydrophobic surface, which accumulate POPs to a great extent, on micro plastics than in the surrounding water.© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Marine fish larvae eat microplastics. Small pieces of plastic,

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Photomicrograph of a mite (Aculops lycopersici); They are very small (<1.5 mm) and reproduce quickly because their life cycle is one week. Parasite widely tomatoes and other plants of the garden.Photomicrograph of a mite (Aculops lycopersici); They are very small (<1.5 mm) and reproduce quickly because their life cycle is one week. Parasite widely tomatoes and other plants of the garden.Photomicrograph of a mite (Aculops lycopersici); They are very small (<1.5 mm) and reproduce quickly because their life cycle is one week. Parasite widely tomatoes and other plants of the garden.© Jean Lecomte / BiosphotoJPG - RM

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Photomicrograph of a mite (Aculops lycopersici); They are very

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Photomicrograph of tomato mite (Aculops lycopersici), length 120 μmPhotomicrograph of tomato mite (Aculops lycopersici), length 120 μmPhotomicrograph of tomato mite (Aculops lycopersici), length 120 μm© Jean Lecomte / BiosphotoJPG - RM

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Photomicrograph of tomato mite (Aculops lycopersici), length 120

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Tomato mites (Aculops lycopersici) live in the hundreds under a tomato leaf. They are very small (<1.5 mm) and reproduce quickly because their life cycle is one week.Tomato mites (Aculops lycopersici) live in the hundreds under a tomato leaf. They are very small (<1.5 mm) and reproduce quickly because their life cycle is one week.Tomato mites (Aculops lycopersici) live in the hundreds under a tomato leaf. They are very small (<1.5 mm) and reproduce quickly because their life cycle is one week.© Jean Lecomte / BiosphotoJPG - RM

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Tomato mites (Aculops lycopersici) live in the hundreds under a

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Two Red spider mite (Tetranychus urticae)Two Red spider mite (Tetranychus urticae)Two Red spider mite (Tetranychus urticae)© Jean Lecomte / BiosphotoJPG - RM

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Two Red spider mite (Tetranychus urticae)

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Yellow mites (Lorryia formosa) harvested from an olive tree twig of Banyuls sur mer, France. On the right, a red mite (Brevipalpus oleae).Yellow mites (Lorryia formosa) harvested from an olive tree twig of Banyuls sur mer, France. On the right, a red mite (Brevipalpus oleae).Yellow mites (Lorryia formosa) harvested from an olive tree twig of Banyuls sur mer, France. On the right, a red mite (Brevipalpus oleae).© Jean Lecomte / BiosphotoJPG - RM

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Yellow mites (Lorryia formosa) harvested from an olive tree twig

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Photomicrograph of mite (Brevipalpus oleae) caught on olive leaves, size 300 μm, Espolla, SpainPhotomicrograph of mite (Brevipalpus oleae) caught on olive leaves, size 300 μm, Espolla, SpainPhotomicrograph of mite (Brevipalpus oleae) caught on olive leaves, size 300 μm, Espolla, Spain© Jean Lecomte / BiosphotoJPG - RM

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Photomicrograph of mite (Brevipalpus oleae) caught on olive

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Yellow mite (Brachytydeus formosa), caught on olive leaves in Espolla, SpainYellow mite (Brachytydeus formosa), caught on olive leaves in Espolla, SpainYellow mite (Brachytydeus formosa), caught on olive leaves in Espolla, Spain© Jean Lecomte / BiosphotoJPG - RM

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Yellow mite (Brachytydeus formosa), caught on olive leaves in

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Yellow mite (Lorryia formosa) under an olive leaf, Size: 320 μYellow mite (Lorryia formosa) under an olive leaf, Size: 320 μYellow mite (Lorryia formosa) under an olive leaf, Size: 320 μ© Jean Lecomte / BiosphotoJPG - RM

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Yellow mite (Lorryia formosa) under an olive leaf, Size: 320 μ

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Three colonies of yellow mites (Brachytydeus formosa) under this olive leaf, the most dangerous for olives.Three colonies of yellow mites (Brachytydeus formosa) under this olive leaf, the most dangerous for olives.Three colonies of yellow mites (Brachytydeus formosa) under this olive leaf, the most dangerous for olives.© Jean Lecomte / BiosphotoJPG - RM

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Three colonies of yellow mites (Brachytydeus formosa) under this

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Larva of Olive black scale (Saisettia oleae) just hatched and unhatched eggs.Larva of Olive black scale (Saisettia oleae) just hatched and unhatched eggs.Larva of Olive black scale (Saisettia oleae) just hatched and unhatched eggs.© Jean Lecomte / BiosphotoJPG - RM

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Larva of Olive black scale (Saisettia oleae) just hatched and

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Olive fruit midge (Lasioptera berlesiana), this small insect lays its eggs in the exit holes of the olive flies, whose larvae maggots devour the larvae in their gallery. He can not pierce the cuticle of the olives.Olive fruit midge (Lasioptera berlesiana), this small insect lays its eggs in the exit holes of the olive flies, whose larvae maggots devour the larvae in their gallery. He can not pierce the cuticle of the olives.Olive fruit midge (Lasioptera berlesiana), this small insect lays its eggs in the exit holes of the olive flies, whose larvae maggots devour the larvae in their gallery. He can not pierce the cuticle of the olives.© Jean Lecomte / BiosphotoJPG - RM

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Olive fruit midge (Lasioptera berlesiana), this small insect lays

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Olive mite (Brevipalpus oleae) harvested on an olive tree in Banyuls sur mer, France - Length = 360 μmOlive mite (Brevipalpus oleae) harvested on an olive tree in Banyuls sur mer, France - Length = 360 μmOlive mite (Brevipalpus oleae) harvested on an olive tree in Banyuls sur mer, France - Length = 360 μm© Jean Lecomte / BiosphotoJPG - RM

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Olive mite (Brevipalpus oleae) harvested on an olive tree in

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Mobile larvae of the Oleander Scale (Aspidiotus nerii). They secrete a carapace that protects them. size of 0, 2 mm.Mobile larvae of the Oleander Scale (Aspidiotus nerii). They secrete a carapace that protects them. size of 0, 2 mm.Mobile larvae of the Oleander Scale (Aspidiotus nerii). They secrete a carapace that protects them. size of 0, 2 mm.© Jean Lecomte / BiosphotoJPG - RM

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Mobile larvae of the Oleander Scale (Aspidiotus nerii). They

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Twospotted Spider Mite (Tetranychus urticae) captured on an olive twig harvested from an olive grove in Espolla, SpainTwospotted Spider Mite (Tetranychus urticae) captured on an olive twig harvested from an olive grove in Espolla, SpainTwospotted Spider Mite (Tetranychus urticae) captured on an olive twig harvested from an olive grove in Espolla, Spain© Jean Lecomte / BiosphotoJPG - RM

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Twospotted Spider Mite (Tetranychus urticae) captured on an olive

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Photomicrograph of mite (Brevipalpus oleae) caught on olive leaves, size 300 μm, Espolla, SpainPhotomicrograph of mite (Brevipalpus oleae) caught on olive leaves, size 300 μm, Espolla, SpainPhotomicrograph of mite (Brevipalpus oleae) caught on olive leaves, size 300 μm, Espolla, Spain© Jean Lecomte / BiosphotoJPG - RM

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Photomicrograph of mite (Brevipalpus oleae) caught on olive

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Honey bee (Apis mellifera) - Anterior Leg of a Bee Grows 70 TimesHoney bee (Apis mellifera) - Anterior Leg of a Bee Grows 70 TimesHoney bee (Apis mellifera) - Anterior Leg of a Bee Grows 70 Times© Eric Tourneret / BiosphotoJPG - RMNon exclusive sale
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Honey bee (Apis mellifera) - Anterior Leg of a Bee Grows 70 Times

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Apidologie - Bee's eye magnified X 270: In the electron microscope, the enlarged and coloured eye of a bee (Apis mellifera).Apidologie - Bee's eye magnified X 270: In the electron microscope, the enlarged and coloured eye of a bee (Apis mellifera).Apidologie - Bee's eye magnified X 270: In the electron microscope, the enlarged and coloured eye of a bee (Apis mellifera).© Eric Tourneret / BiosphotoJPG - RMNon exclusive sale
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Apidologie - Bee's eye magnified X 270: In the electron

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Zoid of colonial Ascidia.Zoid of colonial Ascidia.Zoid of colonial Ascidia.© Jean Lecomte / BiosphotoJPG - RM

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Zoid of colonial Ascidia.

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individu planctonique de Oikopleura dioica hors de sa logette (Tuniciers) . Cet Oikopleura est l'un des premiers Chordés du règne animal; il mesure environ deux millimètres de long et nage en agitant son appendice caudal.individu planctonique de Oikopleura dioica hors de sa logette (Tuniciers) . Cet Oikopleura est l'un des premiers Chordés du règne animal; il mesure environ deux millimètres de long et nage en agitant son appendice caudal.individu planctonique de Oikopleura dioica hors de sa logette (Tuniciers) . Cet Oikopleura est l'un des premiers Chordés du règne animal; il mesure environ deux millimètres de long et nage en agitant son appendice caudal.© Jean Lecomte / BiosphotoJPG - RM

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individu planctonique de Oikopleura dioica hors de sa logette

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Red coral encrusting alga (Corallina elongata) that grows on well-lit rocks: this young colony has developed on a glass slide, which allows to see how its cells extend can to to cover all the supports it finds.Red coral encrusting alga (Corallina elongata) that grows on well-lit rocks: this young colony has developed on a glass slide, which allows to see how its cells extend can to to cover all the supports it finds.Red coral encrusting alga (Corallina elongata) that grows on well-lit rocks: this young colony has developed on a glass slide, which allows to see how its cells extend can to to cover all the supports it finds.© Jean Lecomte / BiosphotoJPG - RM

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Red coral encrusting alga (Corallina elongata) that grows on

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Larvacean in its stall (Oikopleura dioica) in swim movement. Note at the bottom, the filter loaded with nutrient particles: phytoplankton algae or microorganisms.Larvacean in its stall (Oikopleura dioica) in swim movement. Note at the bottom, the filter loaded with nutrient particles: phytoplankton algae or microorganisms.Larvacean in its stall (Oikopleura dioica) in swim movement. Note at the bottom, the filter loaded with nutrient particles: phytoplankton algae or microorganisms.© Jean Lecomte / BiosphotoJPG - RM

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Larvacean in its stall (Oikopleura dioica) in swim movement. Note

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Very young planktonic larva of Sea Urchin (Sphaerechinus granularis). Size about 0.6 mmVery young planktonic larva of Sea Urchin (Sphaerechinus granularis). Size about 0.6 mmVery young planktonic larva of Sea Urchin (Sphaerechinus granularis). Size about 0.6 mm© Jean Lecomte / BiosphotoJPG - RM

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Very young planktonic larva of Sea Urchin (Sphaerechinus

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As soon as these parasitic nematode eggs (Anguilicoloides crassus) are released into the sea or fresh water by the parasitic eels, they pierce their shell and swim towards the bottom where they will be eaten by the benthic copepods (Cyclops sp.). Which will be eaten in turn by the eels. Then these nematodes will cross the stomach and will parasitize the swim bladder of the eel. Diameter of an egg, approximately 400μAs soon as these parasitic nematode eggs (Anguilicoloides crassus) are released into the sea or fresh water by the parasitic eels, they pierce their shell and swim towards the bottom where they will be eaten by the benthic copepods (Cyclops sp.). Which will be eaten in turn by the eels. Then these nematodes will cross the stomach and will parasitize the swim bladder of the eel. Diameter of an egg, approximately 400μAs soon as these parasitic nematode eggs (Anguilicoloides crassus) are released into the sea or fresh water by the parasitic eels, they pierce their shell and swim towards the bottom where they will be eaten by the benthic copepods (Cyclops sp.). Which will be eaten in turn by the eels. Then these nematodes will cross the stomach and will parasitize the swim bladder of the eel. Diameter of an egg, approximately 400μ© Jean Lecomte / BiosphotoJPG - RM

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As soon as these parasitic nematode eggs (Anguilicoloides

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Plankton: This female ovigerous copepod carries its eggs on its caudal appendix. Length 1.1 mmPlankton: This female ovigerous copepod carries its eggs on its caudal appendix. Length 1.1 mmPlankton: This female ovigerous copepod carries its eggs on its caudal appendix. Length 1.1 mm© Jean Lecomte / BiosphotoJPG - RM

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Plankton: This female ovigerous copepod carries its eggs on its

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Echinodermal planktonic larva. Width approximately 600 μEchinodermal planktonic larva. Width approximately 600 μEchinodermal planktonic larva. Width approximately 600 μ© Jean Lecomte / BiosphotoJPG - RM

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Echinodermal planktonic larva. Width approximately 600 μ

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Benthic copepod (Cyclops sp.) Parasitized by two parasitic nematodes of eels (Anguilicoloides crassus) These copepods can then be eaten by an eel that will be parasitized by nematodes which will cross its stomach and settle in the swim bladder of the eel.Benthic copepod (Cyclops sp.) Parasitized by two parasitic nematodes of eels (Anguilicoloides crassus) These copepods can then be eaten by an eel that will be parasitized by nematodes which will cross its stomach and settle in the swim bladder of the eel.Benthic copepod (Cyclops sp.) Parasitized by two parasitic nematodes of eels (Anguilicoloides crassus) These copepods can then be eaten by an eel that will be parasitized by nematodes which will cross its stomach and settle in the swim bladder of the eel.© Jean Lecomte / BiosphotoJPG - RM

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Benthic copepod (Cyclops sp.) Parasitized by two parasitic

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Macrophotography of Common Octopus (Octopus vulgaris) with its multiple chromatophores which it can extend or reduce in order to change color rapidly, for the purpose of mimicry or prey attack.Macrophotography of Common Octopus (Octopus vulgaris) with its multiple chromatophores which it can extend or reduce in order to change color rapidly, for the purpose of mimicry or prey attack.Macrophotography of Common Octopus (Octopus vulgaris) with its multiple chromatophores which it can extend or reduce in order to change color rapidly, for the purpose of mimicry or prey attack.© Jean Lecomte / BiosphotoJPG - RM

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Macrophotography of Common Octopus (Octopus vulgaris) with its

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Last planktonic stage of Common Octopus larva (Octopus vulgaris). It is at this stage that this young octopus leaves the planktonic life and descends on the bottom to feed on other prey than the plankton.Last planktonic stage of Common Octopus larva (Octopus vulgaris). It is at this stage that this young octopus leaves the planktonic life and descends on the bottom to feed on other prey than the plankton.Last planktonic stage of Common Octopus larva (Octopus vulgaris). It is at this stage that this young octopus leaves the planktonic life and descends on the bottom to feed on other prey than the plankton.© Jean Lecomte / BiosphotoJPG - RM

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Last planktonic stage of Common Octopus larva (Octopus vulgaris).

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Last planktonic stage of Common Octopus larva (Octopus vulgaris). It is at this stage that this young octopus leaves the planktonic life and descends on the bottom to feed on other prey than the plankton.Last planktonic stage of Common Octopus larva (Octopus vulgaris). It is at this stage that this young octopus leaves the planktonic life and descends on the bottom to feed on other prey than the plankton.Last planktonic stage of Common Octopus larva (Octopus vulgaris). It is at this stage that this young octopus leaves the planktonic life and descends on the bottom to feed on other prey than the plankton.© Jean Lecomte / BiosphotoJPG - RM

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Last planktonic stage of Common Octopus larva (Octopus vulgaris).

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Common Octopus (Octopus vulgaris) Young hatched. Below, we see their corions from where they came out.Common Octopus (Octopus vulgaris) Young hatched. Below, we see their corions from where they came out.Common Octopus (Octopus vulgaris) Young hatched. Below, we see their corions from where they came out.© Jean Lecomte / BiosphotoJPG - RM

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Common Octopus (Octopus vulgaris) Young hatched. Below, we see

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Anguillicola (Anguilicoloides crassous) Parasitic nematodes of the swimming bladder of eels. This parasite was introduced accidentally into Europe in the 1980s from eels imported from Japan. Note that small individuals are little colored while adults are filled with the blood of the eel where they were found; The tallest individuals measure about one centimeter.Anguillicola (Anguilicoloides crassous) Parasitic nematodes of the swimming bladder of eels. This parasite was introduced accidentally into Europe in the 1980s from eels imported from Japan. Note that small individuals are little colored while adults are filled with the blood of the eel where they were found; The tallest individuals measure about one centimeter.Anguillicola (Anguilicoloides crassous) Parasitic nematodes of the swimming bladder of eels. This parasite was introduced accidentally into Europe in the 1980s from eels imported from Japan. Note that small individuals are little colored while adults are filled with the blood of the eel where they were found; The tallest individuals measure about one centimeter.© Jean Lecomte / BiosphotoJPG - RM

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Anguillicola (Anguilicoloides crassous) Parasitic nematodes of

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Anguillicola (Anguilicoloides crassous) Parasitic nematodes of the swimming bladder of eels. This parasite was introduced accidentally into Europe in the 1980s from eels imported from Japan. Note that small individuals are little colored while adults are filled with the blood of the eel where they were found; The tallest individuals measure about one centimeter.Anguillicola (Anguilicoloides crassous) Parasitic nematodes of the swimming bladder of eels. This parasite was introduced accidentally into Europe in the 1980s from eels imported from Japan. Note that small individuals are little colored while adults are filled with the blood of the eel where they were found; The tallest individuals measure about one centimeter.Anguillicola (Anguilicoloides crassous) Parasitic nematodes of the swimming bladder of eels. This parasite was introduced accidentally into Europe in the 1980s from eels imported from Japan. Note that small individuals are little colored while adults are filled with the blood of the eel where they were found; The tallest individuals measure about one centimeter.© Jean Lecomte / BiosphotoJPG - RM

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Anguillicola (Anguilicoloides crassous) Parasitic nematodes of

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Portugal ; sulphur crystals photomicrography with polarized light. PortugalPortugalPortugal ; sulphur crystals photomicrography with polarized light. Portugal© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Portugal ; sulphur crystals photomicrography with polarized

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Portugal ; Citric acid crystals photomicrography with polarized light. PortugalPortugalPortugal ; Citric acid crystals photomicrography with polarized light. Portugal© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Portugal ; Citric acid crystals photomicrography with polarized

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Portugal ; Benzoic acid crystals photomicrography with polarized light. PortugalPortugalPortugal ; Benzoic acid crystals photomicrography with polarized light. Portugal© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Portugal ; Benzoic acid crystals photomicrography with polarized

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Benzoic acid crystals photomicrography with polarized light. PortugalBenzoic acid crystals photomicrography with polarized light. PortugalBenzoic acid crystals photomicrography with polarized light. Portugal© Paulo de Oliveira / BiosphotoJPG - RMNon exclusive sale
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Benzoic acid crystals photomicrography with polarized light.

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