Histology, multipolar cells from spinal cord (sheep) x10, (direct/above view)
Histology, multipolar cells from spinal cord (sheep) x10, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Histology, nerve cells isolated x40, (direct/above view)
Histology, nerve cells isolated x40, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Histology, liver monkey ts (inject blood sect) x40, (direct/above view)
Histology, liver monkey ts (inject blood sect) x40, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Histology, cilliate epi cells (from fallopian tubes) x100, (direct/above view)
Histology, cilliate epi cells (from fallopian tubes) x100, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Histology, cilliate epi cells (from fallopian tubes) x40, (direct/above view)
Histology, cilliate epi cells (from fallopian tubes) x40, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Rat anatomy, Either male or female, Pointer to right blood vessels lying on muscle bed of throat, (s
Rat anatomy, Either male or female, Pointer to right blood vessels lying on muscle bed of throat, (side/lateral view)
Rat anatomy, Either male or female, Trachea, thyroid & blood vessels of throat insitu 1, (direct/abo
Rat anatomy, Either male or female, Trachea, thyroid & blood vessels of throat insitu 1, (direct/above view)
Rat anatomy, Either male or female, Pointer to right blood vessels lying on muscle bed of throat 1,
Rat anatomy, Either male or female, Pointer to right blood vessels lying on muscle bed of throat 1, (direct/above view)
Rat anatomy, Either male or female, Trachea, thyroid & blood vessels of throat insitu 1, (direct/abo
Rat anatomy, Either male or female, Trachea, thyroid & blood vessels of throat insitu 1, (direct/above view)
Rat anatomy, Either male or female, Using tissues to mop blood seeping into dissected area (!), (sid
Rat anatomy, Either male or female, Using tissues to mop blood seeping into dissected area (!), (side/lateral view)
Rat anatomy, Male, Pointer to right spermatic blood vessles of right teste, (side/lateral view)
Rat anatomy, Male, Pointer to right spermatic blood vessles of right teste, (side/lateral view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Rat anatomy, Male, Pointer to right spermatic blood vessles of right teste, (side/lateral view)
Rat anatomy, Male, Pointer to right spermatic blood vessles of right teste, (side/lateral view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Rat anatomy, Male, Pointer to spermatic blood vessels, (side/lateral view)
Rat anatomy, Male, Pointer to spermatic blood vessels, (side/lateral view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Rat anatomy, Male, Pointer to left adrenal blood vessels, (side/lateral view)
Rat anatomy, Male, Pointer to left adrenal blood vessels, (side/lateral view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Rat anatomy, Male, Lifting fat surrounded major blood vessels in dorsal line 2, (direct/above view)
Rat anatomy, Male, Lifting fat surrounded major blood vessels in dorsal line 2, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Rat anatomy, Female, Raised mesentery + mesenteric blood vessels 1, (direct/above view)
Rat anatomy, Female, Raised mesentery + mesenteric blood vessels 1, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Rat anatomy, Female, Raised mesentery + mesenteric blood vessels 1, (direct/above view)
Rat anatomy, Female, Raised mesentery + mesenteric blood vessels 1, (direct/above view). Rat dissection stills taken from FARID (Functional Anatomy of the Rat [Interactive Dissection]). This resource was authored by Megan Quentin-Baxter and David Dewhurst, with Graham Irving and Stephen Mera at Leeds Metropolitan University.
Introduction to Glycolysis
Living cells can process certain sugar molecules, rearranging their atoms and this process can supply energy to the cell to power growth and other functions. This process is called glycolysis. Glycolysis evolved billions of years ago when there was no oxygen in the earth's atmosphere and it was therefore impossible for cells to gain energy from the oxidation of sugar molecules using oxygen. Later when oxygen was produced as a byproduct of photosynthesis cells evolved to utilise oxygen to oxidise
Angiogenesis and Metastasis in Cancer
The resource below is a series of Powerpoint slides (and a list of further reading) on the cellular and molecular basis of angiogenesis and metastasis in cancer. It gives a short overview of the basic organisation of blood vessels and how tuours agrow and spread by stimulating new blood vessel growth and metastic transformation, highlighting the signalling pathways involved in these processes. These slides were created by Dr. Momna Hejmadi as part of her course to first and second year undergrad
6.973 Organic Optoelectronics (MIT)
The course examines optical and electronic processes in organic molecules and polymers that govern the behavior of practical organic optoelectronic devices. Electronic structure of a single organic molecule is used as a guide to the electronic behavior of organic aggregate structures. Emphasis is placed on the use of organic thin films in active organic devices including organic LEDs, solar cells, photodetectors, transistors, chemical sensors, memory cells, electrochromic devices, as well as xer
