Page semi-protected

Testicle

From Wikipedia, the free encyclopedia
  (Redirected from Testis)
Jump to: navigation, search
Testicle
Figure 28 01 03.JPG
Diagram of inner structures of testicles.
Gray1144.png
Diagram of the external features and surrounding structures of the testicles of an adult male
Details
Artery Testicular artery
Vein Testicular vein, Pampiniform plexus
Nerve Spermatic plexus
Lymph Lumbar lymph nodes
Identifiers
Latin testis
Dorlands
/Elsevier
Testicle
TA A09.3.01.001
FMA 7210
Anatomical terminology
Animation of the migration of spermatozoa from their origin as germ cells to their exit from the vas deferens. A.) Blood vessels; B.) Head of epididymis; C.) Efferent ductules; D.) Seminiferous tubules; E.) Parietal lamina of tunica vaginalis; F.) Visceral lamina of tunica vaginalis; G.) Cavity of tunica vaginalis; H.) Tunica albuginea; I.) Lobule of testis; J.) Tail of epididymis; K.) Body of epididymis; L.) Mediastinum; M.) Vas deferens.

The testicle or testis is the male reproductive gland in all animals, including humans. It is homologous to the female ovary. The functions of the testes are to produce both sperm and androgens, primarily testosterone. Testosterone release is controlled by the anterior pituitary luteinizing hormone; whereas sperm production is controlled both by the anterior pituitary follicle-stimulating hormone and gonadal testosterone.

Structure

Appearance

Males have two testicles of similar size contained within the scrotum, which is an extension of the abdominal wall. Scrotal asymmetry is not unusual: one testicle extends further down into the scrotum than the other due to differences in the anatomy of the vascululature.

Measurement

The volume of the testicle can be estimated by palpating it and comparing it to ellipsoids of known sizes. Another method is to use calipers (an orchidometer) or a ruler either on the person or on an ultrasound image to obtain the three measurements of the x, y, and z axes (length, depth and width). These measurements can then be used to calculate the volume, using the formula for the volume of an ellipsoid: 4/3 π × (length/2) × (width/2) × (depth/2).

The dimensions of the average adult testicle are up to 2 inches long, 0.8 inches in breadth, and 1.2 inches in height (5 x 2 x 3 cm). The Tanner scale for the maturity of male genitals assigns a maturity stage to the calculated volume ranging from stage I, a volume of less than 1.5 ml; to stage V, a volume greater than 20 ml. Normal volume is 15 to 25 ml; the average is 18 cm³ per testis (range 12 cm³ to 30 cm³.[1]

There is some evidence to suggest that average human testicle size and weight has been progressively diminishing in recent years among younger cohorts in Western industrialized nations. This may be associated with a decline in sperm counts. The recent changes suggest involvement of environmental or lifestyle factor(s) such as increasing exposure to endocrine disruptors.[2]

Internal structure

Transverse section through the left side of the scrotum and the left testis.

Duct system

The testes are covered by a tough membranous shell called the tunica albuginea. Within the testes are very fine coiled tubes called seminiferous tubules. The tubules are lined with a layer of cells (germ cells) that develop from puberty through old age into sperm cells (also known as spermatozoa or male gametes). The developing sperm travel through the seminiferous tubules to the rete testis located in the mediastinum testis, to the efferent ducts, and then to the epididymis where newly created sperm cells mature (see spermatogenesis). The sperm move into the vas deferens, and are eventually expelled through the urethra and out of the urethral orifice through muscular contractions.

Primary cell types

Within the seminiferous tubules
Between tubules (interstitial cells)

Blood supply and lymphatic drainage

Blood supply and lymphatic drainage of the testes and scrotum are distinct:

Layers

Many anatomical features of the adult testis reflect its developmental origin in the abdomen. The layers of tissue enclosing each testicle are derived from the layers of the anterior abdominal wall. Notably, the cremasteric muscle arises from the internal oblique muscle.

The blood–testis barrier

Large molecules cannot pass from the blood into the lumen of a seminiferous tubule due to the presence of tight junctions between adjacent Sertoli cells. The spermatogonia are in the basal compartment (deep to the level of the tight junctions) and the more mature forms such as primary and secondary spermatocytes and spermatids are in the adluminal compartment.

The function of the blood–testis barrier (red highlight in diagram above) may be to prevent an auto-immune reaction. Mature sperm (and their antigens) arise long after immune tolerance is established in infancy. Therefore, since sperm are antigenically different from self tissue, a male animal can react immunologically to his own sperm. In fact, he is capable of making antibodies against them.

Injection of sperm antigens causes inflammation of the testis (auto-immune orchitis) and reduced fertility. Thus, the blood–testis barrier may reduce the likelihood that sperm proteins will induce an immune response, reducing fertility and so progeny.

Temperature regulation

Spermatogenesis is enhanced at temperatures slightly less than core body temperature.[6] The spermatogenesis is less efficient at lower and higher temperatures than 33 °C.[6] This is presumably why the testes are located outside the body.[6] There are a number of mechanisms to maintain the testes at the optimum temperature.[6]

The cremasteric muscle is part of the spermatic cord. When this muscle contracts, the cord is shortened and the testicle is moved closer up toward the body, which provides slightly more warmth to maintain optimal testicular temperature. When cooling is required, the cremasteric muscle relaxes and the testicle is lowered away from the warm body and is able to cool. Contraction also occurs in response to stress (the testicles rise up toward the body in an effort to protect them in a fight). There are persistent reports that relaxation indicates approach of orgasm.[citation needed] There is a noticeable tendency to also retract during orgasm.[citation needed]

The cremaster muscle can reflexively raise each testicle individually if properly triggered. This phenomenon is known as the cremasteric reflex. The testicles can also be lifted voluntarily using the pubococcygeus muscle, which partially activates related muscles.

Gene and protein expression

The human genome includes approximately 20,000 protein coding genes: 80% of these genes are expressed in adult testes.[7] The testes have the highest fraction of tissue type-specific genes compared to other organs and tissues:[8] about 1000 of them are highly specific for the testes,[9] and about 2,200 show an elevated pattern of expression here. A majority of these genes encode for proteins that are expressed in the seminiferous tubules and have functions related to spermatogenesis.[10][11] Sperm cells express proteins that result in the development of flagella; these same proteins are expressed in the female in cells lining the fallopian tube, and cause the development of cilia. In other words, sperm cell flagella and Fallopian tube cilia are homologous structures. The testis-specific proteins that show the highest level of expression are protamines.

Development

There are two phases in which the testes grow substantially; namely in embryonic and pubertal age.

Embryonic

During mammalian development, the gonads are at first capable of becoming either ovaries or testes.[12] In humans, starting at about week 4 the gonadal rudiments are present within the intermediate mesoderm adjacent to the developing kidneys. At about week 6, sex cords develop within the forming testes. These are made up of early Sertoli cells that surround and nurture the germ cells that migrate into the gonads shortly before sex determination begins. In males, the sex-specific gene SRY that is found on the Y-chromosome initiates sex determination by downstream regulation of sex-determining factors, (such as GATA4, SOX9 and AMH), which leads to development of the male phenotype, including directing development of the early bipotential gonad down the male path of development.

Testes follow the "path of descent" from high in the posterior fetal abdomen to the inguinal ring and beyond to the inguinal canal and into the scrotum. In most cases (97% full-term, 70% preterm), both testes have descended by birth. In most other cases, only one testis fails to descend (cryptorchidism) and that will probably express itself within a year.

Pubertal

The testes grow in response to the start of spermatogenesis. Size depends on lytic function, sperm production (amount of spermatogenesis present in testis), interstitial fluid, and Sertoli cell fluid production. After puberty, the volume of the testes can be increased by over 500% as compared to the pre-pubertal size.[citation needed] Testicles are fully descended before one reaches puberty.

Clinical significance

Protection and injury

  • The testicles are well-known to be very sensitive to impact and injury. The pain involved travels up from each testicle into the abdominal cavity, via the spermatic plexus, which is the primary nerve of each testicle. This will cause pain in the hip and the back. The pain usually goes away in a few minutes.
  • Testicular torsion is a medical emergency. Treatment within 4–6 hours of onset can prevent necrosis of the testis.[13]
  • Testicular rupture is a medical emergency caused by blunt force impact, sharp edge, or piercing impact to one or both testicles, which can lead to necrosis of the testis in as little as 30 minutes.[citation needed]
  • Penetrating injuries to the scrotum may cause castration, or physical separation or destruction of the testes, possibly along with part or all of the penis, which results in total sterility if the testicles are not reattached quickly.
  • Some jockstraps are designed to provide support to the testicles.[14]

Diseases and conditions

Testicular disease
Classification and external resources
ICD-10 E29, N43-N44
ICD-9-CM 257, 603-604
MeSH D013733
  • Bell-clapper deformity is a deformity in which the testicle is not attached to the scrotal walls, and can rotate freely on the spermatic cord within the tunica vaginalis. It is the most common underlying cause of testicular torsion.
  • Orchitis inflammation of the testicles
  • Epididymitis, a painful inflammation of the epididymis or epididymides frequently caused by bacterial infection but sometimes of unknown origin.
  • Anorchia, the absence of one or both testicles.
  • Cryptorchidism or "undescended testicles", when the testicle does not descend into the scrotum of the infant boy.

Testicular enlargement is an unspecific sign of various testicular diseases, and can be defined as a testicular size of more than 5 cm (long axis) x 3 cm (short axis).[17]

Blue balls is a slang term for a temporary fluid congestion in the testicles and prostate region caused by prolonged sexual arousal.

Testicular prostheses are available to mimic the appearance and feel of one or both testicles, when absent as from injury or as treatment in association to gender dysphoria. There have also been some instances of their implantation in dogs.[18]

Effects of exogenous hormones

To some extent, it is possible to change testicular size. Short of direct injury or subjecting them to adverse conditions, e.g., higher temperature than they are normally accustomed to, they can be shrunk by competing against their intrinsic hormonal function through the use of externally administered steroidal hormones. Steroids taken for muscle enhancement (especially anabolic steroids) often have the undesired side effect of testicular shrinkage.

Similarly, stimulation of testicular functions via gonadotropic-like hormones may enlarge their size. Testes may shrink or atrophy during hormone replacement therapy or through chemical castration.

In all cases, the loss in testes volume corresponds with a loss of spermatogenesis.

Society and culture

Testicles of a male calf or other livestock are cooked and eaten in a dish sometimes called Rocky Mountain oysters.[19]

As early as 330 BC, Aristotle prescribed the ligation (tying off) of the left testicle in men wishing to have boys.[20] In the Middle Ages, men who wanted a boy sometimes had their left testicle removed. This was because people believed that the right testicle made "boy" sperm and the left made "girl" sperm.[21]

Etymology

One theory about the etymology of the word testis is based on Roman law. The original Latin word "testis", "witness", was used in the firmly established legal principle "Testis unus, testis nullus" (one witness [equals] no witness), meaning that testimony by any one person in court was to be disregarded unless corroborated by the testimony of at least another. This led to the common practice of producing two witnesses, bribed to testify the same way in cases of lawsuits with ulterior motives. Since such "witnesses" always came in pairs, the meaning was accordingly extended, often in the diminutive (testiculus, testiculi).[citation needed]

Another theory says that testis is influenced by a loan translation, from Greek parastatēs "defender (in law), supporter" that is "two glands side by side".[22]

Other animals

External appearance

In sharks, the testicle on the right side is usually larger, and in many bird and mammal species, the left may be the larger. The primitive jawless fish have only a single testis, located in the midline of the body, although even this forms from the fusion of paired structures in the embryo.[23]

In seasonal breeders, the weight of the testes often increases during the breeding season.[24] The testicles of a dromedary camel are 7–10 cm (2.8–3.9 in) long, 4.5 cm (1.8 in) deep and 5 cm (2.0 in) in width. The right testicle is often smaller than the left.[25] The testicles of a male red fox attain their greatest weight in December–February.[26] Spermatogenesis in male golden jackals occurs 10–12 days before the females enter estrus and, during this time, males' testicles triple in weight.[27]

Location

Internal

The basal condition for mammals is to have internal testes.[28] The testes of the non-boreotherian mammals, such as the monotremes, armadillos, sloths, and elephants, remain within the abdomen.[not in citation given][29] There are also some marsupials with external testes[30] and Boreoeutherian mammals with internal testes, such as the rhinoceros.[31] Cetaceans such as whales and dolphins also have internal testes.[32] As external testes would increase drag in the water they have internal testes which are kept cool by special circulatory systems that cool the arterial blood going to the testes by placing the arteries near veins bringing cooled venous blood from the skin.[33][34] The testes of the non-boreotherian mammals, such as the monotremes, armadillos, sloths, and elephants, remain within the abdomen.[not in citation given][35] There are also some marsupials with external testes[30] and Boreoeutherian mammals with internal testes, such as the rhinoceros.[36] Cetaceans such as whales and dolphins also have internal testes.[37] As external testes would increase drag in the water they have internal testes which are kept cool by special circulatory systems that cool the arterial blood going to the testes by placing the arteries near veins bringing cooled venous blood from the skin.[38][39]

External

Boreoeutherian land mammals, the large group of mammals that includes humans, have externalized testes.[40] Their testes function best at temperatures lower than their core body temperature. Their testes are located outside of the body, suspended by the spermatic cord within the scrotum.

There are several hypotheses why most boreotherian mammals have external testes which operate best at a temperature that is slightly less than the core body temperature, e.g. that it is stuck with enzymes evolved in a colder temperature due to external testes evolving for different reasons, that the lower temperature of the testes simply is more efficient for sperm production.

1) More efficient. The classic hypothesis is that cooler temperature of the testes allows for more efficient fertile spermatogenesis. In other words, there are no possible enzymes operating at normal core body temperature that are as efficient as the ones evolved, at least none appearing in our evolution so far.

The early mammals had lower body temperatures and thus their testes worked efficiently within their body. However it is argued that boreotherian mammals have higher body temperatures than the other mammals and had to develop external testes to keep them cool. It is argued that those mammals with internal testes, such as the monotremes, armadillos, sloths, elephants, and rhinoceroses, have a lower core body temperatures than those mammals with external testes.[citation needed]

However, the question remains why birds despite having very high core body temperatures have internal testes and did not evolve external testes.[41] It was once theorized that birds used their air sacs to cool the testes internally, but later studies revealed that birds' testes are able to function at core body temperature.[41]

Some mammals which have seasonal breeding cycles keep their testes internal until the breeding season at which point their testes descend and increase in size and become external.[42]

2) Irreversible adaptation to sperm competition. It has been suggested that the ancestor of the boreoeutherian mammals was a small mammal that required very large testes (perhaps rather like those of a hamster) for sperm competition and thus had to place its testes outside the body.[43] This led to enzymes involved in spermatogenesis, spermatogenic DNA polymerase beta and recombinase activities evolving a unique temperature optimum, slightly less than core body temperature. When the boreoeutherian mammals then diversified into forms that were larger and/or did not require intense sperm competition they still produced enzymes that operated best at cooler temperatures and had to keep their testes outside the body. This position is made less parsimonious by the fact that the kangaroo, a non-boreoeutherian mammal, has external testicles. The ancestors of kangaroos might, separately from boreotherian mammals, have also been subject to heavy sperm competition and thus developed external testes, however, kangaroo external testes are suggestive of a possible adaptive function for external testes in large animals.

3) Protection from abdominal cavity pressure changes. One argument for the evolution of external testes is that it protects the testes from abdominal cavity pressure changes caused by jumping and galloping.[44]

4) Protection against DNA damage. Mild, transient scrotal heat stress causes DNA damage, reduced fertility and abnormal embryonic development in mice.[45] DNA strand breaks were found in spermatocytes recovered from testicles subjected to 40°C or 42°C for 30 minutes.[45] These findings suggest that the external location of the testicles provides the adaptive benefit of protecting spermatogenic cells from heat-induced DNA damage that could otherwise lead to infertility and germline mutation.

Size

Cross section of rabbit testis, photographed in bright field microscopy at 40× magnification.

Testicular size as a proportion of body weight varies widely. In the mammalian kingdom, there is a tendency for testicular size to correspond with multiple mates (e.g., harems, polygamy). Production of testicular output sperm and spermatic fluid is also larger in polygamous animals, possibly a spermatogenic competition for survival. The testes of the right whale are likely to be the largest of any animal, each weighing around 500 kg (1,100 lb).[46]

Among the Hominidae, gorillas have little female promiscuity and sperm competition and the testes are small compared to body weight (0.03%). Chimpanzees have high promiscuity and large testes compared to body weight (0.3%). Human testicular size falls between these extremes (0.08%).[47]

Testis weight also varies in seasonal breeders like deer and horses.[citation needed] The change is related to changes in testosterone production.[citation needed]

Human testicles are smaller than chimpanzee testicles but larger than gorilla testicles.[48]

Internal structure

Under a tough membranous shell called the tunica albuginea, the testis of amniotes, as well as some teleost fish, contains very fine coiled tubes called seminiferous tubules.

Amphibians and most fish do not possess seminiferous tubules. Instead, the sperm are produced in spherical structures called sperm ampullae. These are seasonal structures, releasing their contents during the breeding season, and then being reabsorbed by the body. Before the next breeding season, new sperm ampullae begin to form and ripen. The ampullae are otherwise essentially identical to the seminiferous tubules in higher vertebrates, including the same range of cell types.[23]

Gallery

See also

Notes

  1. ^ Andrology: Male Reproductive Health and Dysfunction"[1]" By E. Nieschlag, Hermann M. Behre, H. van. Ahlen
  2. ^ Dindyal, S. (2007). "The sperm count has been decreasing steadily for many years in Western industrialised countries: Is there an endocrine basis for this decrease?". The Internet Journal of Urology. 2 (1): 1–21. 
  3. ^ Histology, A Text and Atlas by Michael H. Ross and Wojciech Pawlina, Lippincott Williams & Wilkins, 5th ed, 2006
  4. ^ Skinner M, McLachlan R, Bremner W (1989). "Stimulation of Sertoli cell inhibin secretion by the testicular paracrine factor PModS". Mol Cell Endocrinol. 66 (2): 239–49. doi:10.1016/0303-7207(89)90036-1. PMID 2515083. 
  5. ^ Arch Histol Cytol. 1996 Mar;59(1):1–13
  6. ^ a b c d Mieusset, R; Bujan, L; Mansat, A; Pontonnier, F (1992). "Hyperthermie scrotale et infécondité masculine" (PDF). Progrès en Urologie (in French) (2): 31–36. 
  7. ^ Uhlén, Mathias; Fagerberg, Linn; Hallström, Björn M.; Lindskog, Cecilia; Oksvold, Per; Mardinoglu, Adil; Sivertsson, Åsa; Kampf, Caroline; Sjöstedt, Evelina (2015-01-23). "Tissue-based map of the human proteome". Science. 347 (6220): 1260419. doi:10.1126/science.1260419. ISSN 0036-8075. PMID 25613900. 
  8. ^ Djureinovic, D.; Fagerberg, L.; Hallström, B.; Danielsson, A.; Lindskog, C.; Uhlén, M.; Pontén, F. (2014-06-01). "The human testis-specific proteome defined by transcriptomics and antibody-based profiling". MHR: Basic science of reproductive medicine. 20 (6): 476–488. doi:10.1093/molehr/gau018. ISSN 1360-9947. 
  9. ^ Uhlén, Mathias; Fagerberg, Linn; Hallström, Björn M.; Lindskog, Cecilia; Oksvold, Per; Mardinoglu, Adil; Sivertsson, Åsa; Kampf, Caroline; Sjöstedt, Evelina (2015-01-23). "Tissue-based map of the human proteome". Science. 347 (6220): 1260419. doi:10.1126/science.1260419. ISSN 0036-8075. PMID 25613900. 
  10. ^ "The human proteome in testis - The Human Protein Atlas". www.proteinatlas.org. 
  11. ^ Djureinovic, D.; Fagerberg, L.; Hallström, B.; Danielsson, A.; Lindskog, C.; Uhlén, M.; Pontén, F. (2014-06-01). "The human testis-specific proteome defined by transcriptomics and antibody-based profiling". MHR: Basic science of reproductive medicine. 20 (6): 476–488. doi:10.1093/molehr/gau018. ISSN 1360-9947. 
  12. ^ Online textbook: "Developmental Biology" 6th ed. By Scott F. Gilbert (2000) published by Sinauer Associates, Inc. of Sunderland (MA).
  13. ^ S. Khan, J. Rehman, B. Chughtai, D. Sciullo, E. Mohan & H. Rehman: "Anatomical Approach to Scrotal Emergencies: A New Paradigm for the Diagnosis and Treatment of the Acute Scrotum". The Internet Journal of Urology. (2010) Volume 6: Number 2. ISSN 1528-8390.
  14. ^ Amazon.com: Suspensory Jockstrap for Scrotal/Testicle Support: Health & Personal Care
  15. ^ "Varicocele". Kidshealth.org. Retrieved 2010-10-25. 
  16. ^ Sierens, J. E.; Sneddon, S. F.; Collins, F.; Millar, M. R.; Saunders, P. T. (2005). "Estrogens in Testis Biology". Annals of the New York Academy of Sciences. 1061: 65–76. doi:10.1196/annals.1336.008. PMID 16467258. 
  17. ^ Page 559 in: John Pellerito, Joseph F Polak (2012). Introduction to Vascular Ultrasonography (6 ed.). Elsevier Health Sciences. ISBN 9781455737666. 
  18. ^ Neuticles
  19. ^ Reviving a very delicate delicacy
  20. ^ Hoag, Hannah. I'll take a girl, please... Cherry-picking from the dish of life. Drexel University Publication. Archived August 31, 2011, at the Wayback Machine.
  21. ^ Understanding genetics; Human health and genome Stanford school of medicine, Dr. Barry Starr
  22. ^ The American Heritage Dictionary of the English Language, Fourth Edition
  23. ^ a b Romer, Alfred Sherwood; Parsons, Thomas S. (1977). The Vertebrate Body. Philadelphia, PA: Holt-Saunders International. pp. 385–386. ISBN 0-03-910284-X. 
  24. ^ A.D. Johnson (2 December 2012). Development, Anatomy, and Physiology. Elsevier. ISBN 978-0-323-14323-3. 
  25. ^ Mukasa-Mugerwa, E. The Camel (Camelus dromedarius): A Bibliographical Review. pp. 11–3. 
  26. ^ Heptner & Naumov 1998, p. 537
  27. ^ Heptner & Naumov 1998, pp. 154–155
  28. ^ http://www.ias.ac.in/article/fulltext/jbsc/035/01/0027-0037
  29. ^ Spermatogenesis
  30. ^ a b Hugh Tyndale-Biscoe; Marilyn Renfree (30 January 1987). Reproductive Physiology of Marsupials. Cambridge University Press. ISBN 978-0-521-33792-2. 
  31. ^ Schaffer, N. E., et al. "Ultrasonography of the reproductive anatomy in the Sumatran rhinoceros (Dicerorhinus sumatrensis)." Journal of Zoo and Wildlife Medicine (1994): 337-348.
  32. ^ Rommel, Sentiel A., D. Ann Pabst, and William A. McLellan. "Functional anatomy of the cetacean reproductive system, with comparisons to the domestic dog." Reproductive Biology and Phylogeny of Cetacea. Science Publishers (2016): 127-145.
  33. ^ Rommel, Sentiel A., D. Ann Pabst, and William A. McLellan. "Reproductive Thermoregulation in Marine Mammals: How do male cetaceans and seals keep their testes cool without a scrotum? It turns out to be the same mechanism that keeps the fetus cool in a pregnant female." American scientist 86.5 (1998): 440-448.
  34. ^ Pabst, D. Ann, Sentiel A. Rommel, and WILLIAM A. McLELLAN. "Evolution of thermoregulatory function in cetacean reproductive systems." The Emergence of Whales. Springer US, 1998. 379-397.
  35. ^ Spermatogenesis
  36. ^ Schaffer, N. E., et al. "Ultrasonography of the reproductive anatomy in the Sumatran rhinoceros (Dicerorhinus sumatrensis)." Journal of Zoo and Wildlife Medicine (1994): 337-348.
  37. ^ Rommel, Sentiel A., D. Ann Pabst, and William A. McLellan. "Functional anatomy of the cetacean reproductive system, with comparisons to the domestic dog." Reproductive Biology and Phylogeny of Cetacea. Science Publishers (2016): 127-145.
  38. ^ Rommel, Sentiel A., D. Ann Pabst, and William A. McLellan. "Reproductive Thermoregulation in Marine Mammals: How do male cetaceans and seals keep their testes cool without a scrotum? It turns out to be the same mechanism that keeps the fetus cool in a pregnant female." American scientist 86.5 (1998): 440-448.
  39. ^ Pabst, D. Ann, Sentiel A. Rommel, and WILLIAM A. McLELLAN. "Evolution of thermoregulatory function in cetacean reproductive systems." The Emergence of Whales. Springer US, 1998. 379-397.
  40. ^ D. S. Mills; Jeremy N. Marchant-Forde (2010). The Encyclopedia of Applied Animal Behaviour and Welfare. CABI. pp. 293–. ISBN 978-0-85199-724-7. 
  41. ^ a b BIOLOGY OF REPRODUCTION 56, 1570–1575 (1997)- Determination of Testis Temperature Rhythms and Effects of Constant Light on Testicular Function in the Domestic Fowl (Gallus domesticus) Archived 2015-09-23 at the Wayback Machine.
  42. ^ "Ask a Biologist Q&A / Human sexual physiology – good design?". Askabiologist.org.uk. 2007-09-04. Retrieved 2010-10-25. 
  43. ^ "'The Human Body as an Evolutionary Patchwork' by Alan Walker, Princeton.edu". RichardDawkins.net. 2007-04-10. Retrieved 2010-10-25. 
  44. ^ Newscientist.com – bumpy-lifestyle-led-to-external-testes
  45. ^ a b Paul C, Murray AA, Spears N, Saunders PT (2008). "A single, mild, transient scrotal heat stress causes DNA damage, subfertility and impairs formation of blastocysts in mice". Reproduction. 136 (1): 73–84. doi:10.1530/REP-08-0036. PMID 18390691. 
  46. ^ Crane, J.; Scott, R. (2002). "Eubalaena glacialis". Animal Diversity Web. Retrieved 2009-05-01. 
  47. ^ Shackelford, T. K.; Goetz, A. T. (2007). "Adaptation to Sperm Competition in Humans". Current Directions in Psychological Science. 16: 47. doi:10.1111/j.1467-8721.2007.00473.x. 
  48. ^ Human Origins 101 – Page 138, Holly M. Dunsworth – 2007

External links