. "The red gills detached from the tuna head on the left"@en . "\u9B5A\u9C13\u662F\u9B5A\u985E\u7684\u9C13\uFF0C\u4F4D\u65BC\u5176\u54BD\u90E8\u5DE6\u53F3\u3002\u9C13\u4E2D\u6709\u7D50\u69CB\uFF0C\u5176\u4E2D\u542B\u6709\u6BDB\u7D30\u8840\u7BA1\u4EE5\u4EA4\u63DB\u6C27\u6C23\u8207\u4E8C\u6C27\u5316\u78B3\u3002\u5B83\u5011\u901A\u904E\u5C07\u542B\u6709\u6C27\u6C23\u7684\u6C34\u7531\u5634\u5438\u5165\u9C13\u4E2D\u4F86\u7372\u53D6\u4E4B\uFF0C\u4E00\u4E9B\u9B5A\u985E\u6BDB\u7D30\u8840\u7BA1\u4E2D\u8840\u6DB2\u6D41\u5411\u8207\u6C34\u6D41\u76F8\u53CD\uFF0C\u53EF\u4EE5\u9020\u6210\u9006\u6D41\u4EA4\u63DB\uFF0C\u6700\u7D42\u5C07\u542B\u6C27\u91CF\u6E1B\u5C11\u7684\u6C34\u5F9E\u9C13\u4E2D\u6392\u51FA\u3002 \u4E00\u4E9B\u9B5A\u985E\uFF0C\u8AF8\u5982\u9BCA\u9B5A\u548C\u4E03\u9C13\u9C3B\uFF0C\u64C1\u6709\u4E0D\u6B62\u4E00\u5C0D\u9C13\uFF0C\u9019\u8207\u786C\u9AA8\u9B5A\u5927\u76F8\u5F91\u5EAD\u3002\u5E7C\u5E74\u591A\u9C2D\u9B5A\u4E5F\u6709\u591A\u500B\u9C13\uFF0C\u662F\u4E00\u7A2E\u540C\u5169\u6816\u985E\u5E7C\u9AD4\u76F8\u4F3C\u7684\u539F\u59CB\u7D50\u69CB\u3002"@zh . . . . . "Fish gill"@en . . . "Fish gills are organs that allow fish to breathe underwater. Most fish exchange gases like oxygen and carbon dioxide using gills that are protected under gill covers (operculum) on both sides of the pharynx (throat). Gills are tissues that are like short threads, protein structures called filaments. These filaments have many functions including the transfer of ions and water, as well as the exchange of oxygen, carbon dioxide, acids and ammonia. Each filament contains a capillary network that provides a large surface area for exchanging oxygen and carbon dioxide."@en . "23889"^^ . . . "\u9B5A\u9C13"@zh . . . . . . . . . . "right"@en . . . . . . . . . . . . . . . . "Gills .jpg"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "breathing in fish.jpg"@en . . "Tuna Gills in Situ 01.jpg"@en . . . . . "\u9B5A\u9C13\u662F\u9B5A\u985E\u7684\u9C13\uFF0C\u4F4D\u65BC\u5176\u54BD\u90E8\u5DE6\u53F3\u3002\u9C13\u4E2D\u6709\u7D50\u69CB\uFF0C\u5176\u4E2D\u542B\u6709\u6BDB\u7D30\u8840\u7BA1\u4EE5\u4EA4\u63DB\u6C27\u6C23\u8207\u4E8C\u6C27\u5316\u78B3\u3002\u5B83\u5011\u901A\u904E\u5C07\u542B\u6709\u6C27\u6C23\u7684\u6C34\u7531\u5634\u5438\u5165\u9C13\u4E2D\u4F86\u7372\u53D6\u4E4B\uFF0C\u4E00\u4E9B\u9B5A\u985E\u6BDB\u7D30\u8840\u7BA1\u4E2D\u8840\u6DB2\u6D41\u5411\u8207\u6C34\u6D41\u76F8\u53CD\uFF0C\u53EF\u4EE5\u9020\u6210\u9006\u6D41\u4EA4\u63DB\uFF0C\u6700\u7D42\u5C07\u542B\u6C27\u91CF\u6E1B\u5C11\u7684\u6C34\u5F9E\u9C13\u4E2D\u6392\u51FA\u3002 \u4E00\u4E9B\u9B5A\u985E\uFF0C\u8AF8\u5982\u9BCA\u9B5A\u548C\u4E03\u9C13\u9C3B\uFF0C\u64C1\u6709\u4E0D\u6B62\u4E00\u5C0D\u9C13\uFF0C\u9019\u8207\u786C\u9AA8\u9B5A\u5927\u76F8\u5F91\u5EAD\u3002\u5E7C\u5E74\u591A\u9C2D\u9B5A\u4E5F\u6709\u591A\u500B\u9C13\uFF0C\u662F\u4E00\u7A2E\u540C\u5169\u6816\u985E\u5E7C\u9AD4\u76F8\u4F3C\u7684\u539F\u59CB\u7D50\u69CB\u3002"@zh . . . . . . . . . . "The fish draws oxygen-rich water in through the mouth . It then pumps it over gills so oxygen enters the bloodstream, and allows oxygen-depleted water to exit through the gill slits"@en . . . . . "280"^^ . . . . . . . . . . "Tuna gills inside the head. The head is oriented snout-down with the view looking towards the mouth."@en . . . . . . . . . "1118257616"^^ . . "Fish gills are organs that allow fish to breathe underwater. Most fish exchange gases like oxygen and carbon dioxide using gills that are protected under gill covers (operculum) on both sides of the pharynx (throat). Gills are tissues that are like short threads, protein structures called filaments. These filaments have many functions including the transfer of ions and water, as well as the exchange of oxygen, carbon dioxide, acids and ammonia. Each filament contains a capillary network that provides a large surface area for exchanging oxygen and carbon dioxide. Fish exchange gases by pulling oxygen-rich water through their mouths and pumping it over their gills. Within the gill filaments, capillary blood flows in the opposite direction to the water, causing counter-current exchange. The gills push the oxygen-poor water out through openings in the sides of the pharynx. Some fish, like sharks and lampreys, possess multiple gill openings. However, bony fish have a single gill opening on each side. This opening is hidden beneath a protective bony cover called the operculum. Juvenile bichirs have external gills, a very primitive feature that they share with larval amphibians. Previously, the evolution of gills was thought to have occurred through two diverging lines: gills formed from the endoderm, as seen in jawless fish species, or those form by the ectoderm, as seen in jawed fish. However, recent studies on gill formation of the little skate (Leucoraja erinacea) has shown potential evidence supporting the claim that gills from all current fish species have in fact evolved from a common ancestor."@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "horizontal"@en . . "190"^^ . . . . . . . . . . . . . . . . . "vertical"@en . . . . . . . . . . . . . "Tuna Gills in Situ cut.jpg"@en . . "37926134"^^ . . .