Fraud Blocker Skip to main content

Cuticle Collection

EDITORS COMMENTS"Exploring the Intricate World of Cuticles: From Water Lily Leaves to Giant Panda Hair" Delicate and ethereal

Background imageCuticle Collection: Human skin, polarised light micrograph

Human skin, polarised light micrograph
Human skin. Polarised light micrograph of a section through human skin showing hair follicles (black)

Background imageCuticle Collection: Water lily leaf, light micrograph

Water lily leaf, light micrograph
Water lily leaf. Light micrograph of a transverse section through the leaf of a water lily (Nympha sp.) plant. All aquatic plants (hydrophytes) have a similar structure

Background imageCuticle Collection: Logo for beauty salon. Linear art

Logo for beauty salon. Linear art. Pink Nail polish, manicured female hand, beautiful woman face, eyelash extension, makeup, hairdressing. Diadem Logo for beauty salon. Linear art

Background imageCuticle Collection: Damaged human hair shaft SEM

Damaged human hair shaft SEM
Damaged human hair shaft, coloured scanning electron micrograph (SEM)

Background imageCuticle Collection: Human hair shaft with split ends SEM

Human hair shaft with split ends SEM
Human hair shaft with split ends, coloured scanning electron micrograph (SEM)

Background imageCuticle Collection: Leaf and water droplets

Leaf and water droplets
Fresh Dew droplets cling to the water repellant surface of the leaf

Background imageCuticle Collection: Water lily leaf stalk, light micrograph

Water lily leaf stalk, light micrograph
Water lily leaf stalk. Light micrograph of a transverse section through the leaf stalk (petiole) of a water lily (Nymphaea sp.). All aquatic plants (hydrophytes) have a similar structure

Background imageCuticle Collection: Giant panda hair, SEM C019 / 0254

Giant panda hair, SEM C019 / 0254
Giant panda (Ailuropoda melanoleuca) hair, coloured scanning electron micrograph (SEM). Magnification: x600 when printed at 10 centimetres wide

Background imageCuticle Collection: Gastrotrich, SEM C019 / 0231

Gastrotrich, SEM C019 / 0231
Gastrotrich. Coloured scanning electron micrograph (SEM) of a Chaetonotus sp. gastrotrich. Gastrotrichs are microscopic, worm-like animals found in both freshwater and marine habitats

Background imageCuticle Collection: Gastrotrich, SEM C019 / 0232

Gastrotrich, SEM C019 / 0232
Gastrotrich. Coloured scanning electron micrograph (SEM) of a Chaetonotus sp. gastrotrich. Gastrotrichs are microscopic, worm-like animals found in both freshwater and marine habitats

Background imageCuticle Collection: Human hair, SEM C014 / 0307

Human hair, SEM C014 / 0307
Human hair. Coloured scanning electron micrograph (SEM) showing the surface of a human hair. Hairs are made up of dead tissue

Background imageCuticle Collection: Flowers of blue Meconopsis poppy C013 / 5131

Flowers of blue Meconopsis poppy C013 / 5131
Flowers of the blue poppy, Meconopsis Fertile Seed Group. Originally introduced from W China in 1924 as Meconopsis betonicifolia, blue poppies have since interbred extensively in cultivation

Background imageCuticle Collection: Camel hair, SEM

Camel hair, SEM
Camel hair. Coloured scanning electron micrograph (SEM) showing the structure of hairs from a bactrian camel (Camelus bactrianus)

Background imageCuticle Collection: Reindeer hair, SEM

Reindeer hair, SEM
Reindeer hair. Coloured scanning electron micrograph (SEM) showing the structure of hairs from a reindeer (Rangifer tarandus)

Background imageCuticle Collection: Collembola, springtail

Collembola, springtail
Scanning electron microscope image of a springtail head (x 300)

Background imageCuticle Collection: Collembola sp. springtail

Collembola sp. springtail
Scanning electron microscope image of a springtail showing the characteristic pattern on the cuticle surface (x 3.5K)

Background imageCuticle Collection: Human hair

Human hair
Scanning electron microscope (SEM) image showing a human hair with the cuticle reflexed

Background imageCuticle Collection: Spider trichobothrium hair

Spider trichobothrium hair
Scanning electron microscope (SEM) image of the base of a trichobothrium hair (x 1, 000). The hair is an air-movement sensor extending from the pit in the cuticle of a spiders leg

Background imageCuticle Collection: Springtail body surface, SEM

Springtail body surface, SEM
Springtail body surface. Coloured scanning electron micrograph (SEM) of the body surface of a springtail insect (order Collembola). The hairs (setae) and scales are typical of this group

Background imageCuticle Collection: Nematode worms, SEM

Nematode worms, SEM
Nematode worm. Scanning electron micrograph of a juvenile Heterorhabditis bacteriophora nematode worm (centre) shedding its cuticle (outer coat, centre right) as it develops into an adult

Background imageCuticle Collection: Cubic close-packed crystal structure

Cubic close-packed crystal structure
Haemoglobin molecule. Computer artwork showing the structure of a haemoglobin molecule. Haemoglobin is a metalloprotein that transports oxygen around the body in red blood cells

Background imageCuticle Collection: Fox hair, SEM

Fox hair, SEM
Fox hairs. Coloured scanning electron micrograph (SEM) of hairs from a fox (family Canidae)

Background imageCuticle Collection: Dragonfly metamorphosis

Dragonfly metamorphosis. Adult dragonfly on a plant stems after emerging from the nypmh stage. The discarded exoskeleton is beneath it

Background imageCuticle Collection: Flys eye

Flys eye. Coloured scanning electron micrograph (SEM) of a flys (order Diptera) compound eye. The eye is made up of numerous visual units, known as ommatidia

Background imageCuticle Collection: Flys eye, SEM

Flys eye, SEM
Flys eye. Coloured scanning electron micrograph (SEM) of a flys compound eye. Protective bristles cover its surface. The eye is made up of numerous visual units, known as ommatidia

Background imageCuticle Collection: Hair shaft and skin, SEM

Hair shaft and skin, SEM
Hair shaft and skin. Coloured scanning electron micrograph (SEM) of a hair shaft (dark brown, left) growing from the surface of human skin

Background imageCuticle Collection: Artwork of the structure of a human hair

Artwork of the structure of a human hair

Background imageCuticle Collection: Hair, SEM

Hair, SEM
Hair fracture. Coloured scanning electron micrograph (SEM) of a fractured hair (yellow and pink). The surrounding layer of facial skin (brown) has a typically scale-like surface

Background imageCuticle Collection: Palm

Palm. Magnified section of palm, historical artwork. The external ridged surface is the cuticle, with the thin layer of skin below this known as the rete mucosum, or epidermis

Background imageCuticle Collection: Magnified section of scalp

Magnified section of scalp, historical artwork. The external surface is the cuticle, with the layer of skin below this known as the rete mucosum, or epidermis

Background imageCuticle Collection: SEM of hair on scalp

SEM of hair on scalp
Hair. Coloured scanning electron micrograph of hairs protruding from the surface of the scalp. Numerous desquamating cells (pink) are concentrically arranged around the base of the hair shaft

Background imageCuticle Collection: Coloured SEM of laser writing on a human hair

Coloured SEM of laser writing on a human hair
Laser script on human hair. Coloured scanning electron micrograph (SEM) of writing on a human hair performed by a medical laser

Background imageCuticle Collection: Nasturtium stem, SEM

Nasturtium stem, SEM
Nasturtium stem. Coloured scanning electron micrograph (SEM) of a freeze-fractured Nasturtium (Tropaeolum sp.) stem

Background imageCuticle Collection: Water lily stem, SEM

Water lily stem, SEM
Water lily stem. Coloured scanning electron micrograph (SEM) of a freeze-fractured water lily stem showing numerous vascular bundles (grey) and large intercellular air spaces (holes)

Background imageCuticle Collection: Cashmere wool, SEM

Cashmere wool, SEM
Cashmere wool. Coloured scanning electron micrograph (SEM) of hair fibres from the cashmere goat. The cuticle (outer layer) of the hair comprises overlapping scales

Background imageCuticle Collection: Common rush stem, light micrograph

Common rush stem, light micrograph
Common rush stem. Light micrograph of a section through the stem of a common rush (Juncus conglomeratus) plant, showing stellate cells

Background imageCuticle Collection: Sharp rush stem, light micrograph

Sharp rush stem, light micrograph
Sharp rush stem. Light micrograph of a section through the stem of a sharp rush (Juncus acutus) plant. This arid-adapted plant (xerophyte) has scattered vascular bundles

Background imageCuticle Collection: Ammophila arenaria leaf, light micrograph

Ammophila arenaria leaf, light micrograph
Ammophila arenaria leaf. Polarised light micrograph of a section through a marram grass (Ammophila arenaria) leaf, showing the characteristics that help reduce water loss

Background imageCuticle Collection: Hair shaft, light micrograph

Hair shaft, light micrograph
Hair shaft, differential interference contrast light micrograph. The outer layer of a hair shaft (the cuticle) has overlapping scales of keratin

Background imageCuticle Collection: Mint leaf surface, SEM

Mint leaf surface, SEM
Mint leaf surface. Coloured scanning electron micrograph (SEM) of the surface of a mint (Menta sp.) leaf

Background imageCuticle Collection: Human hair, SEM

Human hair, SEM
Human hair, coloured scanning electron micrograph (SEM). Hairs are made up of dead tissue

Background imageCuticle Collection: Oleander leaf, light micrograph

Oleander leaf, light micrograph
Oleander leaf. Light micrograph of a section through the leaf of an oleander (Nerium oleander) tree, showing its sunken stomata (gaps, centre left and right)

Background imageCuticle Collection: Pine tree needle, light micrograph

Pine tree needle, light micrograph
Pine tree needle. Polarised light micrograph of a cross-section through a needle from a Pinus pine tree. This leaf is needle-like in order to reduce water loss (transpiration)

Background imageCuticle Collection: Hair shaft anatomy, artwork

Hair shaft anatomy, artwork
Hair shaft anatomy. Cutaway artwork showing the internal structure and anatomy of a human hair

Background imageCuticle Collection: Insect anatomy, artwork

Insect anatomy, artwork
Insect anatomy. Computer artwork of a cross-section through the body of a typical Insect showing the main structures and organs. For the labelled diagram see image: C008/8724

Background imageCuticle Collection: Newly-emerged dragonflies

Newly-emerged dragonflies. Adult dragonflies (order Odonata) on plant stems after emerging from the nypmh stage. Their discarded nymphal cases (exuviae) can be seen below and between them

Background imageCuticle Collection: Kidney bean stem, light micrograph

Kidney bean stem, light micrograph
Kidney bean stem. Light micrograph of a section through the stem of a kidney bean (Phaseolus vulgaris) plant. The outer layer is the cuticle (brown), with a cortex of parenchyma (yellow) beneath it

Background imageCuticle Collection: Pine needle, light micrograph

Pine needle, light micrograph
Pine needle. Light micrograph of a transverse section through a leaf (needle) of a pine tree (Pinus sp.)

Background imageCuticle Collection: Young pine tree stem, light micrograph

Young pine tree stem, light micrograph
Young pine tree stem. Light micrograph of a transverse section through a two and a half-year-old stem of a pine tree (Pinus sp.)

Background imageCuticle Collection: Dyers greenweed stem, light micrograph

Dyers greenweed stem, light micrograph
Dyers greenweed stem. Polarised light micrograph of a transverse section through the stem of a dyers greenweed (Genista tinctoria) plant

Background imageCuticle Collection: Marsh samphire stem, light micrograph

Marsh samphire stem, light micrograph
Marsh samphire stem. Light micrograph of a transverse section through the stem of a marsh samphire, (Salicornia europaea) plant. This is a succulent, xerophytic, halophyte plant

Background imageCuticle Collection: Pine wood structure, light micrograph

Pine wood structure, light micrograph
Pine wood structure. Polarised light micrograph of a longitudinal radial section through the stem wood (xylem) of the deal pine tree (Pinus mitis)

Background imageCuticle Collection: Eucalyptus leaf, light micrograph

Eucalyptus leaf, light micrograph
Eucalyptus leaf. Light micrograph of a cross-section through the midrib of a eucalyptus (Eucalyptus globulus) leaf

Background imageCuticle Collection: Cedar tree stem, light micrograph

Cedar tree stem, light micrograph
Cedar tree stem. Light micrograph of a transverse section through a stem of a cedar tree (Thujopsis dolobrata)

Background imageCuticle Collection: Sunflower stem, light micrograph

Sunflower stem, light micrograph
Sunflower stem. Light micrograph of a transverse section through the stem of a sunflower (Helianthus annuus) plant, showing a vascular bundle

Background imageCuticle Collection: Eucalyptus stem, light micrograph

Eucalyptus stem, light micrograph
Eucalyptus stem. Light micrograph of a transverse section through a one-year-old stem of a Eucalyptus (Eucalyptus globulus) plant

Background imageCuticle Collection: Mahogany wood structure, light micrograph

Mahogany wood structure, light micrograph
Mahogany wood structure

Background imageCuticle Collection: Beech leaves, light micrograph

Beech leaves, light micrograph
Beech leaves. Light micrograph of a transverse section through two beech leaves (Fagus sylvatica)

Background imageCuticle Collection: Ginger leaf, light micrograph

Ginger leaf, light micrograph
Ginger leaf. Light micrograph of a transverse section through the midrib of a ginger (Zingiber officinale) leaf

Background imageCuticle Collection: Young yew tree stem, light micrograph

Young yew tree stem, light micrograph
Young yew tree stem. Light micrograph of a transverse section through a one-year-old stem of a yew tree (Taxus baccata)

Background imageCuticle Collection: Cat hair, SEM

Cat hair, SEM
Cat hair, coloured scanning electron micrograph (SEM). The outside of the hair, the cuticle, is covered in overlapping scales of dead cells containing the protein keratin

Background imageCuticle Collection: Human hairs, SEM

Human hairs, SEM
Human hairs. Coloured scanning electron micrograph (SEM) of three human hairs next to each other

Background imageCuticle Collection: Leaf midrib, light micrograph

Leaf midrib, light micrograph
Leaf midrib. Light micrograph (LM) of a section through the midrib of a leaf from a monocotyledon plant. The midrib (midvein) is the continuation of a leafs stem along the centre of the leaf

Background imageCuticle Collection: Leaf midrib, SEM

Leaf midrib, SEM
Leaf midrib. Coloured scanning electron micrograph (SEM) of a section through the midrib of a leaf from the Common Box (Buxus sempervirens)

Background imageCuticle Collection: Pincushion hakea leaf, light micrograph

Pincushion hakea leaf, light micrograph
Pincushion hakea leaf. Polarised light micrograph of a transverse section through the leaf of a pincushion hakea (Hakea laurina) plant. This is a drought plant (xerophyte)

Background imageCuticle Collection: Heather leaf stomata, light micrograph

Heather leaf stomata, light micrograph
Heather leaf stomata. Light micrograph of a transverse section through a stomata (centre, circular) in the leaf of a heather (Erica sp.) plant. Heather is a drought plant (xerophyte)

Background imageCuticle Collection: Heather leaf, light micrograph

Heather leaf, light micrograph
Heather leaf. Light micrograph of a transverse section through the leaf of a heather (Erica sp.) plant. Heather is a drought plant (xerophyte)

Background imageCuticle Collection: She-oak stem, light micrograph

She-oak stem, light micrograph
She-oak stem. Light micrograph of a transverse section through the stem of the Australian she-oak (Casuarina equisetifolia). The she-oak is a drought plant (xerophyte)

Background imageCuticle Collection: Pondweed stem, light micrograph

Pondweed stem, light micrograph
Pondweed stem. Light micrograph of a transverse section through the stem of a pondweed (Potamogeton sp.) plant. All aquatic plants (hydrophytes) have a similar stem structure

Background imageCuticle Collection: Water milfoil stem, light micrograph

Water milfoil stem, light micrograph
Water milfoil stem. Light micrograph of a transverse section through the stem of the aquatic whorled water milfoil (Myriophyllum verticillatum) plant

Background imageCuticle Collection: Water milfoil shoot-tip, light micrograph

Water milfoil shoot-tip, light micrograph
Water milfoil shoot tip. Light micrograph of a transverse section through the shoot-tip of the aquatic whorled water milfoil (Myriophyllum verticillatum) plant

Background imageCuticle Collection: Waterweed stem, light micrograph

Waterweed stem, light micrograph
Waterweed stem. Polarised light micrograph of a transverse section through a stem of the aquatic western waterweed (Elodea nuttallii) plant

Background imageCuticle Collection: Mistletoe stem, light micrograph

Mistletoe stem, light micrograph
Mistletoe stem. Polarised light micrograph of a transverse section through the stem of a mistletoe (Viscum album) plant

Background imageCuticle Collection: Mares tail stem, light micrograph

Mares tail stem, light micrograph
Mares tail stem. Polarised light micrograph of a transverse section through a stem of the aquatic mares tail (Hippuris vulgaris) plant. All aquatic plants (hydrophytes) have a similar stem structure

Background imageCuticle Collection: Sweet potato stem, light micrograph

Sweet potato stem, light micrograph
Sweet potato stem. Light micrograph of a transverse section through part of a sweet potato (Ipomoea batatas) stem. At bottom is a large area of pith, consisting of parenchyma cells

Background imageCuticle Collection: Clematis stem, light micrograph

Clematis stem, light micrograph
Clematis stem. Light micrograph of a transverse section through the stem of a clematis (Clematis flammula) plant. At the centre of the stem is a large area of pith, consisting of parenchyma cells

Background imageCuticle Collection: Rosemary leaf, light micrograph

Rosemary leaf, light micrograph
Rosemary leaf. Light micrograph of a transverse section through a rosemary (Romarinus officinalis) leaf

Background imageCuticle Collection: Pincushion leaf, light micrograph

Pincushion leaf, light micrograph
Pin cushion leaf. Polarised light micrograph of a transverse section through a pinchusion (Hakea laurina) leaf

Background imageCuticle Collection: Human finger, longitudinal section

Human finger, longitudinal section
Human finger. Light micrograph of a longitudinal section through a finger of a human infant. This shows the bones inside the finger (here, the 1st and 2nd phalanges)



All products are expertly crafted, using premium materials, tailored to your specifications and promptly shipped


EDITORS COMMENTS

"Exploring the Intricate World of Cuticles: From Water Lily Leaves to Giant Panda Hair" Delicate and ethereal, the water lily leaf showcases its intricate cuticle structure under a light micrograph. Unveiling the evolution of beauty culture, a vintage black and white photo captures the electric manicure machine revolutionizing nail care. Nature's artistry at play: glistening water droplets delicately rest on a leaf's cuticle, creating an enchanting sight. Peering into the microscopic world, a biomedical illustration reveals the complex anatomy of a roundworm's cuticle – nature's armor for survival. Human hair takes center stage as scanning electron microscopy (SEM) unravels its fascinating structural details with astonishing clarity. Not just limited to humans, SEM delves into dog hair too, unraveling its unique composition and texture in mesmerizing detail. A captivating SEM image showcases giant panda hair in all its glory – each strand revealing nature's mastery in providing insulation and protection. Gastrotrichs take their turn under SEM scrutiny, showcasing their intriguing cuticular features that aid them in aquatic habitats. Another glimpse into human hair through SEM highlights its diverse textures and patterns – truly reflecting individuality at its finest. In this captivating journey through various specimens captured by cutting-edge technology like SEM or traditional photography methods like light micrographs, we discover how different organisms possess unique yet equally fascinating cuticles - from delicate leaves to human hairs or even gastrotrichs thriving underwater. The intricacies hidden within these seemingly ordinary structures remind us of nature’s remarkable ability to adapt and protect living beings across species boundaries.

© Copyright Media Storehouse, All Rights Reserved 2003 - 2025
Facebook     Pinterest     100% Payment Secure     Reviews IO