皮內成骨

皮內成骨（英語：osteoderm）是在真皮下中形成鱗片、板或其他結構的骨性沉積物。在許多現存和已滅絕的爬行動物和兩棲動物中都發現了皮內成骨，包括蜥蜴类、鱷類、蛙類、各種恐龍（最著名的是裝甲類的甲龍和劍龍）、植龍目、楯齒龍目、魚龍目以及離片椎目動物。

皮內成骨在哺乳動物中並不常見，但在許多異關節總目動物中被發現，如犰狳、已滅絕的雕齒獸和大地懶等。皮內成骨已在許多不同的動物群系中獨立發展^[1] 。犰狳的皮內成骨被認為在皮下真皮組織中發育^[2]。皮內成骨被視為相似物（analogues）而非同源（homologues），故不能作為單系群的必要標準。然而，這些結構是從所有種類的羊膜動物共有的鱗甲中衍生出來的，這便是是所謂的深同源性（deep homologues）的一個例子^[3]。在許多情況下，皮內成骨可能會起到防禦裝甲的作用。成骨細胞由骨組織組成，並從該生物的胚胎髮育過程中的神經脊細胞衍生而來^[4]。

現代鱷類的皮內成骨具有大量血管^[5] ，既可以用作裝甲，也可以用作熱交換器^[6] ，從而使這些大型爬行動物能夠迅速升高或降低溫度。另一個功能是中和酸中毒，這種酸中毒是由於長時間浸泡在水下而導致血液中二氧化碳的積累所致^[7] 。皮内成骨中的鈣和鎂將釋放鹼性離子到血液中，作為防止體液酸化的緩沖劑^[8]。

參考資料

^ Hill, R.V. Comparative anatomy and histology of xenarthran osteoderms. Journal of Morphology. December 2006, 267 (12): 1441–1460. PMID 17103396. doi:10.1002/jmor.10490.
^ Nasoori, Alireza. Formation, structure, and function of extra‐skeletal bones in mammals. Biological Reviews. 2020 [2020-08-09]. doi:10.1111/brv.12597. （原始内容存档于2020-07-27）.
^ Vickaryous, M.K.; Hall, B.K. Development of the dermal skeleton in Alligator mississippiensis (Archosauria, Crocodylia) with comments on the homology of osteoderms. Journal of Morphology. April 2008, 269 (4): 398–422. PMID 17960802. doi:10.1002/jmor.10575.
^ Vickaryous, Matthew K.; Sire, Jean-Yves. The integumentary skeleton of tetrapods: origin, evolution, and development. Journal of Anatomy. 2009-04-01, 214 (4): 441–464. ISSN 1469-7580. PMC 2736118 . PMID 19422424. doi:10.1111/j.1469-7580.2008.01043.x （英语）.
^ Clarac, F.; Buffrénil, V; Cubo, J; Quilhac, A. Vascularization in Ornamented Osteoderms: Physiological Implications in Ectothermy and Amphibious Lifestyle in the Crocodylomorphs?. Anatomical Record. 2018, 301 (1): 175–183. PMID 29024422. doi:10.1002/ar.23695 （英语）.
^ Clarac, F.; Quilhac, A. The crocodylian skull and osteoderms: A functional exaptation to ectothermy?. Zoology. 2019, 132: 31–40. PMID 30736927. doi:10.1016/j.zool.2018.12.001.
^ Jackson, DC.; Andrade, D.; Abe, AS. Lactate sequestration by osteoderms of the broad-nose caiman, Caiman latirostris, following capture and forced submergence.. Journal of Experimental Biology. 2003, 206 (Pt 20): 3601–3606. PMID 12966051. doi:10.1242/jeb.00611.
^ Antacid armour key to tetrapod survival. ABC Science. 2012-04-24 [6 March 2017]. （原始内容存档于2019-01-18）.

[1] Hill, R.V. Comparative anatomy and histology of xenarthran osteoderms. Journal of Morphology. December 2006, 267 (12): 1441–1460. PMID 17103396. doi:10.1002/jmor.10490.

[2] Nasoori, Alireza. Formation, structure, and function of extra‐skeletal bones in mammals. Biological Reviews. 2020 [2020-08-09]. doi:10.1111/brv.12597. （原始内容存档于2020-07-27）.

[3] Vickaryous, M.K.; Hall, B.K. Development of the dermal skeleton in Alligator mississippiensis (Archosauria, Crocodylia) with comments on the homology of osteoderms. Journal of Morphology. April 2008, 269 (4): 398–422. PMID 17960802. doi:10.1002/jmor.10575.

[4] Vickaryous, Matthew K.; Sire, Jean-Yves. The integumentary skeleton of tetrapods: origin, evolution, and development. Journal of Anatomy. 2009-04-01, 214 (4): 441–464. ISSN 1469-7580. PMC 2736118 . PMID 19422424. doi:10.1111/j.1469-7580.2008.01043.x （英语）.

[5] Clarac, F.; Buffrénil, V; Cubo, J; Quilhac, A. Vascularization in Ornamented Osteoderms: Physiological Implications in Ectothermy and Amphibious Lifestyle in the Crocodylomorphs?. Anatomical Record. 2018, 301 (1): 175–183. PMID 29024422. doi:10.1002/ar.23695 （英语）.

[Cl19-6] Clarac, F.; Quilhac, A. The crocodylian skull and osteoderms: A functional exaptation to ectothermy?. Zoology. 2019, 132: 31–40. PMID 30736927. doi:10.1016/j.zool.2018.12.001.

[Ja03-7] Jackson, DC.; Andrade, D.; Abe, AS. Lactate sequestration by osteoderms of the broad-nose caiman, Caiman latirostris, following capture and forced submergence.. Journal of Experimental Biology. 2003, 206 (Pt 20): 3601–3606. PMID 12966051. doi:10.1242/jeb.00611.

[8] Antacid armour key to tetrapod survival. ABC Science. 2012-04-24 [6 March 2017]. （原始内容存档于2019-01-18）.

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