Ann Elizabeth Sefton

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Ann Elizabeth Jervie Sefton AO (born 8 July 1936) [1] [2] is an Australian neurologist and educator. As a visual scientist, she developed descriptions of the connections between the eye and visual centres of the brain. [2] As a student at the University of Sydney she was the first woman to be elected President of the Medical Society. [2] In 2000, she was appointed an Officer of the Order of Australia (AO) for her services to medical education. [1] [3] [4] She was appointed Pro-Chancellor of the University of Sydney in 2001 and served as Deputy Chancellor from 2004 to 2008. [2]

Contents

Early life and education

Sefton was born in Sydney, Australia in 1936. [1] She studied medicine at the University of Sydney, graduating with a BSc (Med) in 1957, a MBBS in 1960, a PhD in 1966 and a DSc in 1990. [2] While she was an undergraduate student, she was the first woman to be elected President of the University of Sydney Medical Society and helped establish the Australian Medical Students' Association, later becoming a life member of both. [1] [2] [4] During her BSc and PhD she began her work on visual connections, producing papers on connections between the eye and the visual cortex. [2] [5] [6]

Career and research

From 1965 to 1973, Sefton worked as a lecturer in physiology at the University of Sydney, becoming an Associate Professor in 1985 and Professor in 1992. [1] [2] She also served as Associate Dean of the Faculty of Medicine at the University of Sydney from 1991 to 1999. [1] Her early research developed anatomical arrangements of the visual centres of the brain, [2] [7] [8] with later work concentrating on the development of colour vision in mammals. [2] [9] [10] [11]

Sefton also contributed to medical education at the University of Sydney. She initiated the development of a new type of medical education program, moving away from memorisation and rote-learning, and instead integrating clinical reasoning, critical appraisal and problem solving. [2] This approach was implemented in the Graduate Medical Program at the University of Sydney in 1997. [2] Sefton also joined the Faculty of Dentistry as associate Dean part-time from 1999 to 2001, helping to develop their graduate dental program. [1] [2] Sefton received multiple awards for teaching excellence from the University of Sydney. [1] [2] [4] She was also made an Officer of the Order of Australia in 2000 "for service to medical education, particularly in the area of reform and the development of a graduate medical programme, and to physiology and research in the field of neuroscience through the study of the function and structure of the visual pathways of the brain." [3]

Sefton remains an Emeritus Professor at the University of Sydney. She served on the University of Sydney Senate from 2001 to 2009, becoming Pro-Chancellor in 2001 and serving as Deputy Chancellor from 2004 to 2008. [2] She has also acted as a co-chair of the education committee of the International Union of Physiological Sciences. [2]

Awards and recognition

Related Research Articles

<span class="mw-page-title-main">Optic chiasm</span> Part of the brain where the optic nerves cross

In neuroanatomy, the optic chiasm, or optic chiasma, is the part of the brain where the optic nerves cross. It is located at the bottom of the brain immediately inferior to the hypothalamus. The optic chiasm is found in all vertebrates, although in cyclostomes, it is located within the brain.

<span class="mw-page-title-main">Thalamus</span> Structure within the brain

The thalamus is a large mass of gray matter located in the dorsal part of the diencephalon. Nerve fibers project out of the thalamus to the cerebral cortex in all directions, allowing hub-like exchanges of information. It has several functions, such as the relaying of sensory signals, including motor signals to the cerebral cortex and the regulation of consciousness, sleep, and alertness.

<span class="mw-page-title-main">Optic nerve</span> Second cranial nerve, which connects the eyes to the brain

In neuroanatomy, the optic nerve, also known as the second cranial nerve, cranial nerve II, or simply CN II, is a paired cranial nerve that transmits visual information from the retina to the brain. In humans, the optic nerve is derived from optic stalks during the seventh week of development and is composed of retinal ganglion cell axons and glial cells; it extends from the optic disc to the optic chiasma and continues as the optic tract to the lateral geniculate nucleus, pretectal nuclei, and superior colliculus.

Blindsight is the ability of people who are cortically blind to respond to visual stimuli that they do not consciously see due to lesions in the primary visual cortex, also known as the striate cortex or Brodmann Area 17. The term was coined by Lawrence Weiskrantz and his colleagues in a paper published in a 1974 issue of Brain. A previous paper studying the discriminatory capacity of a cortically blind patient was published in Nature in 1973.

<span class="mw-page-title-main">Visual system</span> Body parts responsible for sight

The visual system comprises the sensory organ and parts of the central nervous system which gives organisms the sense of sight as well as enabling the formation of several non-image photo response functions. It detects and interprets information from the optical spectrum perceptible to that species to "build a representation" of the surrounding environment. The visual system carries out a number of complex tasks, including the reception of light and the formation of monocular neural representations, colour vision, the neural mechanisms underlying stereopsis and assessment of distances to and between objects, the identification of a particular object of interest, motion perception, the analysis and integration of visual information, pattern recognition, accurate motor coordination under visual guidance, and more. The neuropsychological side of visual information processing is known as visual perception, an abnormality of which is called visual impairment, and a complete absence of which is called blindness. Non-image forming visual functions, independent of visual perception, include the pupillary light reflex and circadian photoentrainment.

<span class="mw-page-title-main">Lateral geniculate nucleus</span> Component of the visual system in the brains thalamus

In neuroanatomy, the lateral geniculate nucleus is a structure in the thalamus and a key component of the mammalian visual pathway. It is a small, ovoid, ventral projection of the thalamus where the thalamus connects with the optic nerve. There are two LGNs, one on the left and another on the right side of the thalamus. In humans, both LGNs have six layers of neurons alternating with optic fibers.

<span class="mw-page-title-main">Midbrain</span> Forward-most portion of the brainstem

The midbrain or mesencephalon is the forward-most portion of the brainstem and is associated with vision, hearing, motor control, sleep and wakefulness, arousal (alertness), and temperature regulation. The name comes from the Greek mesos, "middle", and enkephalos, "brain".

<span class="mw-page-title-main">Pulvinar nuclei</span>

The pulvinar nuclei or nuclei of the pulvinar are the nuclei located in the thalamus. As a group they make up the collection called the pulvinar of the thalamus, usually just called the pulvinar.

<span class="mw-page-title-main">Marginal nucleus of spinal cord</span>

The marginal nucleus of spinal cord, or posteromarginal nucleus, Rexed lamina I, is located at the most dorsal aspect of the dorsal horn of the spinal cord. The neurons located here receive input primarily from Lissauer's tract and relay information related to pain and temperature sensation. Pain sensation relayed here cannot be modulated, e.g. pain from burning the skin. The axons of neurons contribute to the lateral spinothalamic tract.

<span class="mw-page-title-main">Inferior colliculus</span> Midbrain structure involved in the auditory pathway.

The inferior colliculus (IC) is the principal midbrain nucleus of the auditory pathway and receives input from several peripheral brainstem nuclei in the auditory pathway, as well as inputs from the auditory cortex. The inferior colliculus has three subdivisions: the central nucleus, a dorsal cortex by which it is surrounded, and an external cortex which is located laterally. Its bimodal neurons are implicated in auditory-somatosensory interaction, receiving projections from somatosensory nuclei. This multisensory integration may underlie a filtering of self-effected sounds from vocalization, chewing, or respiration activities.

<span class="mw-page-title-main">Edinger–Westphal nucleus</span> One of two nuclei of the oculomotor nerve

The Edinger–Westphal nucleus is one of two nuclei of the oculomotor nerve. It is located in the midbrain. It contributes the autonomic parasympathetic component to the oculomotor nerve, providing innervation to the iris sphincter muscle and ciliary muscle to mediate the pupillary light reflex and accommodation, respectively. It is composed of parasympathetic pre-ganglionic cell bodies that synapse in the ciliary ganglion.

<span class="mw-page-title-main">Subiculum</span> Most inferior part of the hippocampal formation

The subiculum is the most inferior component of the hippocampal formation. It lies between the entorhinal cortex and the CA1 subfield of the hippocampus proper.

The zona incerta (ZI) is a horizontally elongated region of gray matter in the subthalamus below the thalamus. Its connections project extensively over the brain from the cerebral cortex down into the spinal cord.

<span class="mw-page-title-main">Superior olivary complex</span> Collection of brainstem nuclei related to hearing

The superior olivary complex (SOC) or superior olive is a collection of brainstem nuclei that functions in multiple aspects of hearing and is an important component of the ascending and descending auditory pathways of the auditory system. The SOC is intimately related to the trapezoid body: most of the cell groups of the SOC are dorsal to this axon bundle while a number of cell groups are embedded in the trapezoid body. Overall, the SOC displays a significant interspecies variation, being largest in bats and rodents and smaller in primates.

The isothalamus is a division used by some researchers in describing the thalamus.

<span class="mw-page-title-main">Gustatory nucleus</span>

The gustatory nucleus is the rostral part of the solitary nucleus located in the medulla. The gustatory nucleus is associated with the sense of taste and has two sections, the rostral and lateral regions. A close association between the gustatory nucleus and visceral information exists for this function in the gustatory system, assisting in homeostasis - via the identification of food that might be possibly poisonous or harmful for the body. There are many gustatory nuclei in the brain stem. Each of these nuclei corresponds to three cranial nerves, the facial nerve (VII), the glossopharyngeal nerve (IX), and the vagus nerve (X) and GABA is the primary inhibitory neurotransmitter involved in its functionality. All visceral afferents in the vagus and glossopharyngeal nerves first arrive in the nucleus of the solitary tract and information from the gustatory system can then be relayed to the thalamus and cortex.

Ponto-geniculo-occipital waves or PGO waves are distinctive wave forms of propagating activity between three key brain regions: the pons, lateral geniculate nucleus, and occipital lobe; specifically, they are phasic field potentials. These waves can be recorded from any of these three structures during and immediately before REM sleep. The waves begin as electrical pulses from the pons, then move to the lateral geniculate nucleus residing in the thalamus, and end in the primary visual cortex of the occipital lobe. The appearances of these waves are most prominent in the period right before REM sleep, albeit they have been recorded during wakefulness as well. They are theorized to be intricately involved with eye movement of both wake and sleep cycles in many different animals.

The parabrachial nuclei, also known as the parabrachial complex, are a group of nuclei in the dorsolateral pons that surrounds the superior cerebellar peduncle as it enters the brainstem from the cerebellum. They are named from the Latin term for the superior cerebellar peduncle, the brachium conjunctivum. In the human brain, the expansion of the superior cerebellar peduncle expands the parabrachial nuclei, which form a thin strip of grey matter over most of the peduncle. The parabrachial nuclei are typically divided along the lines suggested by Baxter and Olszewski in humans, into a medial parabrachial nucleus and lateral parabrachial nucleus. These have in turn been subdivided into a dozen subnuclei: the superior, dorsal, ventral, internal, external and extreme lateral subnuclei; the lateral crescent and subparabrachial nucleus along the ventrolateral margin of the lateral parabrachial complex; and the medial and external medial subnuclei

<span class="mw-page-title-main">Visual pathway lesions</span> Overview about the lesions of visual pathways

The visual pathway consists of structures that carry visual information from the retina to the brain. Lesions in that pathway cause a variety of visual field defects. In the visual system of human eye, the visual information processed by retinal photoreceptor cells travel in the following way:
Retina→Optic nerve→Optic chiasma →Optic tract→Lateral geniculate body→Optic radiation→Primary visual cortex

Alev Erisir is a Turkish-American neuroscientist. She is a Professor of Psychology and the Department Chair at the University of Virginia in Charlottesville. Her primary research areas include synaptic connectivity in the visual and taste systems, neuronal circuit plasticity, and ultrastructural neuroanatomy.

References

  1. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 "Sefton, Ann Elizabeth". Encyclopedia of Australian Science and Innovation. Retrieved 2022-10-21.
  2. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 "Sefton, Ann Elizabeth Jervie - Faculty of Medicine Online Museum and Archive". www.sydney.edu.au. Retrieved 2022-10-21.
  3. 1 2 3 "Award Extract - Australian Honours Search Facility". Australian Honours Search Facility. Retrieved 2022-10-21.
  4. 1 2 3 4 5 6 7 8 9 10 11 "Trove". trove.nla.gov.au. Retrieved 2022-10-21.
  5. Hayhow, W. R.; Sefton, A.; Webb, C. (June 1962). "Primary optic centers of the rat in relation to the terminal distribution of the crossed and uncrossed optic nerve fibers". The Journal of Comparative Neurology. 118 (3): 295–321. doi:10.1002/cne.901180303. ISSN   0021-9967. PMID   13905663. S2CID   33051001.
  6. Sefton, Ann J.; Burke, W. (1965-03-27). "Reverberator Inhibitory Circuits in the Lateral Geniculate Nucleus of the Rat". Nature. 205 (4978): 1325–1326. doi:10.1038/2051325a0. ISSN   1476-4687. S2CID   4184598.
  7. Dreher, Bogdan; Sefton, Ann Jervie (1979-01-01). "Properties of neurons in cat's dorsal lateral geniculate nucleus: A comparison between medial interlaminar and laminated parts of the nucleus". The Journal of Comparative Neurology. 183 (1): 47–64. doi:10.1002/cne.901830105. ISSN   0021-9967. PMID   758334. S2CID   12631018.
  8. Hale, P. T.; Sefton, A. J.; Dreher, B. (1979-05-01). "A correlation of receptive field properties with conduction velocity of cells in the rat's retino-geniculo-cortical pathway". Experimental Brain Research. 35 (3): 425–442. doi:10.1007/BF00236762. ISSN   1432-1106. PMID   456451. S2CID   1584420.
  9. Mackay-Sim, Alan; Sefton, Ann Jervie; Martin, Paul R. (1983-01-01). "Subcortical projections to lateral geniculate and thalamic reticular nuclei in the hooded rat". The Journal of Comparative Neurology. 213 (1): 24–35. doi:10.1002/cne.902130103. ISSN   0021-9967. PMID   6826786. S2CID   7321636.
  10. Sefton, A. J.; Martin, P. R. (1984-08-01). "Relation of the parabigeminal nucleus to the superior colliculus and dorsal lateral geniculate nucleus in the hooded rat". Experimental Brain Research. 56 (1): 144–148. doi:10.1007/BF00237450. ISSN   1432-1106. PMID   6468563. S2CID   7467035.
  11. Martin, Paul R.; Sefton, Ann Jervie; Dreher, Bogdan (1983-11-11). "The retinal location and fate of ganglion cells which project to the ipsilateral superior colliculus in neonatal albino and hooded rats". Neuroscience Letters. 41 (3): 219–226. doi:10.1016/0304-3940(83)90454-8. ISSN   0304-3940. PMID   6320062. S2CID   45801061.
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