Callinectes sapidus (from the Greek calli- = "beautiful", nectes = "swimmer", and Latin sapidus = "savory"), the Blue Crab, Atlantic Blue Crab, or regionally as the Chesapeake blue crab, is a species of crab native to the waters of the western Atlantic Ocean and the Gulf of Mexico, and introduced internationally.
C. sapidus is of considerable culinary and economic importance in the USA, particularly in Louisiana, North Carolina, the Chesapeake Bay, Delaware, and New Jersey. It is the Maryland state crustacean and the state's largest commercial fishery. 
Callinectes sapidus is a decapod crab of the swimming crab family Portunidae. The genus Callinectes is distinguished from other portunid crabs by the lack of an internal spine on the carpus (the middle segment of the claw), as well as by the T-shape of the male abdomen.  Blue crabs may grow to a carapace width of 23 cm (9.1 in). C. sapidus individuals exhibit sexual dimorphism. Males and females are easily distinguished by the shape of the abdomen (known as the "apron") and by color differences in the chelipeds, or claws. The abdomen is long and slender in males, but wide and rounded in mature females. A popular mnemonic is that the male's apron is shaped like the Washington Monument, while the mature female's resembles the dome of the United States Capitol.  Claw color differences are more subtle than apron shape. The immovable, fixed finger of the claws in males is blue with red tips, while females have orange coloration with purple tips.  A female's abdomen changes as it matures: an immature female has a triangular-shaped abdomen, whereas a mature female's is rounded. 
Other species of Callinectes may be easily confused with C. sapidus because of overlapping ranges and similar morphology. One species is the lesser blue crab (C. similis). It is found further offshore than the common blue crab, and has a smoother granulated carapace. Males of the lesser blue crab also have mottled white coloration on the swimming legs, and females have areas of violet coloration on the internal surfaces of the claws.  C. sapidus can be distinguished from another related species found within its range, C. ornatus, by number of frontal teeth on the carapace. C. sapidus has four, while C. ornatus has six. 
The crab's blue hue stems from a number of pigments in the shell, including alpha- crustacyanin, which interacts with a red pigment, astaxanthin, to form a greenish-blue coloration. When the crab is cooked, the alpha-crustacyanin breaks down, leaving only the astaxanthin, which turns the crab to a bright orange-red color. 
Callinectes sapidus is native to the western edge of the Atlantic Ocean from Cape Cod to Argentina and around the entire coast of the Gulf of Mexico.   It has recently been reported north of Cape Cod in the Gulf of Maine, potentially representing a range expansion due to climate change.  It has been introduced (via ballast water) to Japanese and European waters, and has been observed in the Baltic, North, Mediterranean and Black Seas.  The first record from European waters was made in 1901 at Rochefort, France.  In some parts of its introduced range, C. sapidus has become the subject of crab fishery, including in Greece, where the local population may be decreasing as a result of overfishing. 
The natural predators of C. sapidus include eels, drum, striped bass, spot, trout, some sharks, humans, cownose rays, and whiptail stingrays. C. sapidus is an omnivore, eating both plants and animals. C. sapidus typically consumes thin-shelled bivalves, annelids, small fish, plants and nearly any other item it can find, including carrion, other C. sapidus individuals, and animal waste.  C. sapidus may be able to control populations of the invasive green crab, Carcinus maenas; numbers of the two species are negatively correlated, and C. maenas is not found in the Chesapeake Bay, where C. sapidus is most frequent. 
Callinectes sapidus is subject to a number of diseases and parasites.  They include a number of viruses, bacteria, microsporidians, ciliates, and others.  The nemertean worm Carcinonemertes carcinophila commonly parasitizes C. sapidus, especially females and older crabs, although it has little adverse effect on the crab.  A trematode that parasitizes C. sapidus is itself targeted by the hyperparasite Urosporidium crescens.  The most harmful parasites may be the microsporidian Ameson michaelis, the amoeba Paramoeba perniciosa and the dinoflagellate Hematodinium perezi, which causes "bitter crab disease". 
Eggs of C. sapidus hatch in high salinity waters of inlets, coastal waters, and mouths of rivers and are carried to the ocean by ebb tides.  During seven planktonic (zoeal) stages blue crab larvae float near the surface and feed on microorganisms they encounter. After the eighth zoeal stage, larvae molt into megalopae. This larval form has small claws called chelipeds for grasping prey items.  Megalopae selectively migrate upward in the water column as tides travel landward toward estuaries. Eventually blue crabs arrive in brackish water, where they spend the majority of their life. Chemical cues in estuarine water prompt metamorphosis to the juvenile phase, after which blue crabs appear similar to the adult form. 
Blue crabs grow by shedding their exoskeleton, or molting, to expose a new, larger exoskeleton. After it hardens, the new shell fills with body tissue. Shell hardening occurs most quickly in low salinity water where high osmotic pressure allows the shell to become rigid soon after molting.  Molting reflects only incremental growth, making age estimation difficult.  For blue crabs, the number of molts in a lifetime is fixed at approximately 25. Females typically exhibit 18 molts after the larval stages, while postlarval males molt about 20 times.  Male blue crabs tend to grow broader and have more accentuated lateral spines than females.  Growth and molting are profoundly influenced by temperature and food availability. Higher temperatures and greater food resources decrease the period of time between molts as well as the change in size during molts (molt increment). Salinity and disease also have subtle impacts on molting and growth rate.  Molting occurs more rapidly in low salinity environments. The high osmotic pressure gradient causes water to quickly diffuse into a soft, recently molted blue crab's shell, allowing it to harden more quickly. The effects of diseases and parasites on growth and molting are less well understood, but in many cases have been observed to reduce growth between molts. For example, mature female blue crabs infected with the parasitic rhizocephalan barnacle Loxothylacus texanus appear extremely stunted in growth when compared to uninfected mature females.  Blue crab may reach maturity within one year of hatching in the Gulf of Mexico, while Chesapeake Bay crabs may take up to 18 months to mature.  As a result of different growth rates, commercial and recreational crabbing occur year-round in the Gulf of Mexico, while crabbing seasons are closed for colder parts of the year in northern states.
Mating and spawning are distinct events in blue crab reproduction. Males may mate several times and undergo no major changes in morphology during the process. Female blue crabs mate only once in their lifetimes during their pubertal, or terminal, molt. During this transition, the abdomen changes from a triangular to a semicircular shape. Mating in blue crab is a complex process that requires precise timing of mating at the time of the female's terminal molt. It generally occurs during the warmest months of the year. Prepubertal females migrate to the upper reaches of estuaries where males typically reside as adults. To ensure that a male can mate, he will actively seek a receptive female and guard her for up to 7 days until she molts, at which time insemination occurs. Crabs compete with other individuals before, during, and after insemination, so mate guarding is very important for reproductive success. After mating, a male must continue to guard the female until her shell has hardened.  Inseminated females retain spermatophores for up to one year, which they use for multiple spawnings in high salinity water.  During spawning, a female extrudes fertilized eggs onto her swimmerets and carries them in a large egg mass, or sponge, while they develop. Females migrate to the mouth of the estuary to release the larvae, the timing of which is believed to be influenced by light, tide, and lunar cycles. Blue crabs have high fecundity: females may produce up to 2 million eggs per brood. 
Migration and reproduction patterns differ between crab populations along the East Coast and the Gulf of Mexico. A distinct and large scale migration occurs in Chesapeake Bay, where C. sapidus undergoes a seasonal migration of up to several hundred miles. In the middle and upper parts of the bay, mating peaks in mid to late summer, while in the lower bay there are peaks in mating activity during spring and late summer through early fall. Changes in salinity and temperature may impact time of mating because both factors are important during the molting process.  After mating, the female crab travels to the southern portion of the Chesapeake, using ebb tides to migrate from areas of low salinity to areas of high salinity,  fertilizing her eggs with sperm stored during her single mating months or almost a year before. 
Spawning events in the Gulf of Mexico are less pronounced than in estuaries along the East Coast, like the Chesapeake. In northern waters of the Gulf of Mexico, spawning occurs in the spring, summer, and fall, and females generally spawn twice. During spawning, females migrate to high salinity waters to develop a sponge, and return inland after hatching their larvae. They develop their second sponge inland, and again migrate to the higher-salinity waters to hatch the second sponge. After this, they typically do not reenter the estuary. Blue crabs along the southernmost coast of Texas may spawn year-round. 
Commercial fisheries for C. sapidus exist along much of the Atlantic coast of the United States, and in the Gulf of Mexico. Although the fishery has been historically centered on the Chesapeake Bay, contributions from other localities are increasing in importance.  In the past two decades, the majority of commercial crabs have been landed in four states: Maryland, Virginia, North Carolina, and Louisiana. Weight and value of harvests since 2000 are listed below. 
|2000||31 (12.3)||24 (15.5)||37 (21.8)||34 (28.0)||164|
|2001||35 (16.3)||26 (15.8)||32 (20.2)||32 (26.3)||158|
|2002||30 (15.1)||21 (15.5)||33 (21.5)||31 (28.5)||147|
|2003||35 (16.3)||19 (12.6)||37 (25.0)||34 (28.1)||154|
|2004||39 (19.4)||22 (15.8)||24 (19.6)||30 (25.4)||146|
|2005||40 (21.9)||21 (16.4)||20 (16.0)||27 (23.9)||141|
|2006||31 (17.7)||14 (13.7)||17 (15.3)||33 (32.1)||126|
|2007||42 (19.6)||16 (16.0)||21 (13.6)||35 (28.7)||149|
|2008||50 (21.5)||18 (14.3)||28 (20.3)||32 (25.7)||161|
|2009||52 (22.0)||21 (18.6)||27 (16.8)||37 (30.1)||163|
|2010||79 (33.2)||29 (19.3)||26 (15.4)||30 (15.4)||205|
|2011||60 (25.3)||26 (19.6)||21 (14.9)||37 (21.7)||184|
|2012||60 (24.4)||25 (18.5)||23 (14.9)||39 (22.8)||188|
|2013||50 (17.9)||24 (18.0)||30 (16.5)||51 (28.8)||192|
As early as the 1600s, the blue crab was an important food item for Native Americans and European settlers in the Chesapeake Bay area. Soft and hard blue crabs were not as valuable as fish but gained regional popularity by the 1700s. Throughout their range crabs were also an effective bait type for hook and line fisheries. Rapid perishing limited the distribution and hindered the growth of the fishery. Advances in refrigeration techniques in the late 1800s and early 1900s increased demand for blue crab nationwide. 
The early blue crab fishery along the Atlantic coast was casual and productive because blue crabs were extremely abundant. In the lower Chesapeake Bay, crabs were even considered a nuisance species because they frequently clogged the nets of seine fishermen. Early on, the blue crab fishery of the Atlantic states was well documented. Atlantic states were the first to regulate the fishery, particularly the Chesapeake states. For example, after observing a slight decline in harvest, the fishing commissions of Virginia and Maryland put size limits into place by 1912 and 1917 respectively. Catch-per-unit-effort at the time was determined by packing houses, or crab processing plants. 
The early history of the recreational blue crab fishery in the Gulf of Mexico is not well known.  Commercial crabbing was first reported in the Gulf of Mexico in the 1880s. Early crab fishermen used long-handled dip nets and drop nets among other simple fishing gear types to trap crabs at night. Blue crab spoiled quickly, which limited distribution and hindered the growth of the fishery for several decades.  The first commercial processing plant in Louisiana opened in Morgan City in 1924. Other plants opened soon after, although commercial processing of hard blue crabs was not widespread until World War II. 
Louisiana now has the world's largest blue crab fishery. Commercial harvests in the state account for over half of all landings in the Gulf of Mexico.  The industry was not commercialized for interstate commerce until the 1990s, when supply markedly decreased in Maryland due to problems (see above) in Chesapeake Bay. Since then, Louisiana has steadily increased its harvest. In 2002, Louisiana harvested 22% of the nation's blue crab. That number rose to 26% by 2009 and 28% by 2012. The vast majority of Louisiana crabs are shipped to Maryland, where they are sold as "Chesapeake" or "Maryland" crab. Louisiana's harvest remained high in 2013, with 17,597 metric tons of blue crab valued at $51 million.  In addition to commercial harvesting, recreational crabbing is very popular along Louisiana's coast. 
The Chesapeake Bay has had the largest blue crab harvest for more than a century. Maryland and Virginia are usually the top two Atlantic coast states in annual landings, followed by North Carolina.  In 2013, crab landings were valued at $18.7 million from Maryland waters and $16.1 million from Virginia waters.  Although crab populations are currently declining, blue crab fishing in Maryland and Virginia remains a livelihood for thousands of coastal residents. As of 2001, Maryland and Virginia collectively had 4,816 commercial crab license holders.  Three separate licenses are required for each of the three major jurisdictional areas: Maryland, the Potomac River, and Virginia waters.  While the Bay’s commercial sector lands the majority of hard crab landings and nearly all peeler or soft crab landings, the recreational fishery is also significant.  In 2013, an estimated 3.9 million pounds of blue crab were harvested recreationally. 
Blue crab populations naturally fluctuate with annual changes in environmental conditions. They have been described as having a long-term dynamic equilibrium, which was first noted after irregular landings data in the Chesapeake in 1950.  This tendency may have made it difficult for managers to predict the severe decline of the Chesapeake’s blue crab populations. Once considered an overwhelmingly abundant annoyance, the declining blue crab population is now the subject of anxiety among fishermen and managers. Over the decade between the mid-1990s to 2004, the population fell from 900 million to around 300 million, and harvest weight fell from 52,000 tons (115,000,000 lbs) to 28,000 tons (62,000,000 lbs). Revenue fell further, from $72 million to $61 million. Long term estimates say that the overall Chesapeake population decreased approximately 70% in the last few decades. Even more alarming, the number of females capable of reproducing, known as spawning age females, has plummeted 84% in just a few decades. Survival and addition of juveniles to the harvestable crab population is also low.  Many factors are to blame for low blue crab numbers, including high fishing pressure, environmental degradation, and disease prevalence.  The 2018 reduction in H-2B visas available for seasonal workers is affecting Maryland's 20 crab processors, which typically employ about 500 foreign workers; however, the effect this will have on the crab fishery is not yet clear. 
Many types of gear have been used to catch blue crabs along the Atlantic and Gulf Coasts.  Initially people used very simple techniques and gear, which included hand lines, dip nets, and push nets among a variety of other gear types. The trotline, a long baited twine set in waters 5–15 feet deep, was the first major gear type used commercially to target hard crabs.  Use of commercial trotlines is now mostly limited to the tributaries of the Chesapeake Bay. In the Gulf of Mexico, trotline use drastically declined after invention of the crab pot in 1938. Crab pots are rigid boxlike traps made of hexagonal or square wire mesh. They possess between two and four funnels that extend into the trap, with the smaller end of the funnel inside of the trap. A central compartment made of smaller wire mesh holds bait. Crabs attracted by odorant plumes from the bait, often an oily fish, enter the trap through the funnels and cannot escape. 
Species other than blue crab are often caught incidentally in crab pots, including fish, turtles, conch, and other crab species. In Georgia, hermit crabs (Pagurus spp.), channeled whelk (Busycon canaliculatum), spider crabs (Libinia spp.), and stone crabs (Menippe mercenaria) were the most common species observed as bycatch in commercial crab pots.  Of important concern is the diamondback terrapin, Malaclemys terrapin. The blue crab and diamondback terrapin have overlapping ranges along the East and Gulf coasts of the United States. Because the funnels in a crab pot are flexible, small terrapins may easily enter and become entrapped. Traps are checked every 24 hours or less, frequently resulting in drowning and death of terrapins. Crab pot bycatch may reduce local terrapin populations to less than half. To reduce terrapin entrapment, bycatch reduction devices (BRDs) may be installed on each of the funnels in a crab pot.  BRDs effectively reduce bycatch (and subsequently mortality) of small terrapins without affecting blue crab catch. 
Because of its commercial and environmental value, C. sapidus is the subject of management plans over much of its range.   In 2012, the C. sapidus population in Louisiana was recognized as a certified sustainable fishery by the Marine Stewardship Council.  It was the first and remains the only certified sustainable blue crab fishery worldwide.  For the state to maintain its certification, it must undergo annual monitoring and conduct a full re-evaluation five years after the certification date. 
- Beautiful Swimmers, a Pulitzer Prize-winning book with an extensive discussion of the crabs and their life cycle
- Chesapeake (novel), by James Michener with a story about C. sapidus titled "Jimmy the crab"
- Crab cake
- She-crab soup
- Soft-shell crab
- "Species Fact Sheet: Callinectes sapidus (Rathbun, 1896)". Food and Agriculture Organization. Retrieved November 28, 2010.
- "Maryland State Crustacean". Maryland State Archives. 2005-12-27.
- "Callinectes spiadus". Field Guide to the Indian River Lagoon. Smithsonian Marine Station at Fort Pierce. Archived from the original on 2013-05-29. Retrieved September 12, 2012.
- Williams, A. B. (1974). "The Swimming Crabs of the Genus Callinectes (Decapoda: Portunidae)". Fishery Bulletin. 72 (3): 685–692.
- Millikin, Mark R.; Williams, Austin B. (March 1984). "Synopsis of Biological Data on the Blue Crab Callinectes sapidus Rathburn". NOAA Technical Report NMFS 1: 1–32.
- "Blue crab, Callinectes sapidus". Maryland Fish Facts. Maryland Department of Natural Resources. April 4, 2007. Archived from the original on April 19, 2011. Retrieved February 17, 2011.
- "Callinectes similis Lesser Blue Crab". Smithsonian Marine Station at Fort Pierce. Retrieved 9 March 2015.
- Susan B. Rothschild (2004). "Sandy beaches". Beachcomber's Guide to Gulf Coast Marine Life: Texas, Louisiana, Mississippi, Alabama, and Florida (3rd ed.). Taylor Trade Publications. pp. 21–38. ISBN 978-1-58979-061-2.
- "Blue Crab Frequently Asked Questions". Blue Crab Archives. December 2008.
- "Callinectes sapidus". Smithsonian Marine Station at Fort Pierce. October 11, 2004.
- "Blue crabs". National Geographic. Retrieved July 22, 2011.
- Johnson, David (2015). "Home > Journals > The savory swimmer swims north: a northern range ... Advanced Search The savory swimmer swims north: a northern range extension of the blue crab Callinectes sapidus?". Journal of Crustacean Biology. 35: 105–110. doi: 10.1163/1937240X-00002293.
- "Callinectes sapidus". CIESM: The Mediterranean Marine Research Network. August 2006. Archived from the original on 2006-10-20. Retrieved 2006-11-23.
- A. Brockerhoff; C. McLay (2011). "Human-mediated spread of alien crabs". In Bella S. Galil; Paul F. Clark; James T. Carlton (eds.). In the Wrong Place – Alien Marine Crustaceans: Distribution, Biology and Impacts. Invading Nature. 6. Springer. pp. 27–106. ISBN 978-94-007-0590-6.
- "Blue Crab-About The bay". The Chesapeake Bay Foundation. Archived from the original on 2009-01-16. Retrieved 2009-01-16.
- Catherine E. DeRivera; Gregory M. Ruiz; Anson H. Hines; Paul Jivoff (2005). "Biotic resistance to invasion: Native predator limits abundance and distribution of an P.U.P.U crab" (PDF). Ecology. 86 (12): 3367–3376. doi: 10.1890/05-0479. Archived from the original (PDF) on 2010-06-10.
- Gretchen A. Messick (1998). "Diseases, parasites, and symbionts and blue crabs (Callinectes sapidus) dredged from Chesapeake Bay" (PDF). Journal of Crustacean Biology. 18 (3): 533–548. doi: 10.2307/1549418. JSTOR 1549418.
- Gretchen A. Messick; Carl J. Sindermann (1992). "Synopsis of principal diseases of the blue crab, Callinectes sapidus" (PDF). NOAA Technical Memorandum. National Oceanic and Atmospheric Administration. NMFS-F/NEC-88.
- Kennedy, Victor S.; Cronin, L. Eugene (2007). The Blue Crab Callinectes sapidus. College Park, Md.: Maryland Sea Grant College. pp. 655–698. ISBN 978-0943676678.
- Bourgeois, Marty; Marx, Jeff; Semon, Katie (November 7, 2014). "Louisiana Blue Crab Fishery Management Plan": 1–122. Cite journal requires
- Perry, H.M. (1975). "The blue crab fishery in Mississippi". Gulf Research Reports. 5 (1): 39–57. doi: 10.18785/grr.0501.05.
- James L. Hench; Richard B. Forward; Sarah D. Carr; Daniel Rittschof; Richard A. Luettich (2004). "Testing a selective tidal-stream transport model: observations of female blue crab (Callinectes sapidus) vertical migration during the spawning season". Limnology and Oceanography. 49 (5): 1857–1870. Bibcode: 2004LimOc..49.1857H. CiteSeerX 10.1.1.536.2262. doi: 10.4319/lo.2004.49.5.1857.
- "Migration". SERC: Smithsonian Environmental Research Center. Archived from the original on 2010-07-13. Retrieved 2010-07-30.
- Alice Cascorbi (February 14, 2004). "Seafood Report: Blue Crab, Callinectes sapidus" (PDF). Seafood Watch. Monterey Bay Aquarium. Archived from the original (PDF) on 2013-07-28. Retrieved September 12, 2012.
- "NMFS Landings Query Results for Blue Crab". Retrieved 23 February 2015.[ permanent dead link]
- Perry, H.M.; Adkins, G.; Condrey, R.; Hammerschmidt, P.C.; Heath, S.; Herring, J.R.; Moss, C.; Perkins, G.; Steele, P. (1984). "A profile of the blue crab fishery of the Gulf of Mexico". Gulf States Marine Fisheries Commission. Publication 7.
- Chesapeake Bay Stock Assessment Committee (2014). "Chesapeake Bay Blue Crab Advisory Report": 1–13. Cite journal requires
- Rhodes, A.; Lipton, D.; Shabman, L. (2001). "A Socio-Economic Profile of the Chesapeake Bay Blue Crab Fishery". Bi-State Blue Crab Advisory Committee: 1–27.
- Miller, T.J.; Wilberg, M.J.; Colton, A.R.; Davis, G.R.; Sharov, A.; Lipcius, R.N.; Ralph, G.M.; Johnson, E.G.; Kaufman, A.G. (2011). "Stock Assessment of the Blue Crab in the Chesapeake Bay". Technical Series Report No. TS614-11: 1–214.
- Stagg, C.; Whilden, M. (1997). "The history of Chesapeake Bay's blue crab (Callinectes sapidus): Fisheries and management". Investigaciones Marinas. 25: 93–104. doi: 10.4067/s0717-71781997002500007.
- Zohar, Y.; Hines, A.H.; Zmora, O.; Johnson, E.G.; Lipcius, R.N.; Seitz, R.D. (2008). "The Chesapeake Bay blue crab (Callinectes sapidus): a multidisciplinary approach to responsible stock replenishment". Reviews in Fisheries Science. 16 (1–3): 24. doi: 10.1080/10641260701681623. S2CID 27931558.
- Chesapeake Bay Foundation (December 2008). "Bad Water and the Decline of Blue Crabs in the Chesapeake Bay". Chesapeake Bay Foundation Reports: 1–24.
- Dance, Scott (2018-05-03). "Crab crisis: Md. seafood industry loses 40 percent of workforce in visa lottery". Washington Post. ISSN 0190-8286. Retrieved 2018-05-06.
- Page, J.W.; Curran, M.C.; Geer, P.J. (2013). "Characterization of the bycatch in the commercial blue crab pot fishery in Georgia, November 2003–December 2006". Marine and Coastal Fisheries. 5: 236–245. doi: 10.1080/19425120.2013.818084.
- Roosenburg, Willem (2004). "The Impact of Crab Pot Fisheries on Terrapin (Malaclemys terrapin) Populations: Where Are We and Where Do We Need to Go?". Conservation and Ecology of Turtles of the Mid-Atlantic Region: A Symposium: 23–30.
- Rook, M.A.; Lipcius, R.N.; Bronner, B.M.; Chambers, R.M. (2010). "Bycatch reduction device conserves diamondback terrapin without affecting catch of blue crab". Marine Ecology Progress Series. 409: 171–179. Bibcode: 2010MEPS..409..171R. doi: 10.3354/meps08489.
- Vincent Guillory; Harriet Perry; Steve VanderKooy, eds. (October 2001).
"The Blue Crab Fishery of the Gulf of Mexico, United States: a Regional Management Plan" (PDF). 96.
Gulf States Marine Fisheries Commission. Retrieved July 22, 2011. Cite journal requires
- Benjamin Alexander-Bloch (March 19, 2012). "Louisiana blue crab earns a blue ribbon". The Times-Picayune. Retrieved March 19, 2012.
- "Louisiana Blue Crab Third Party Certification". Audubon Nature Institute G.U.L.F. Retrieved 23 February 2015.
- DeAlteris, Dr. J.; Daume, Dr. S.; Allen, Mr. R. (February 16, 2012). "MSC Final Report Louisiana Blue Crab Fishery": 1–119. Cite journal requires
- Media related to Callinectes sapidus at Wikimedia Commons
- Female Blue Crab Anatomy - Callinectes sapidus - Dana Point Fish Company
- Crab diagram
- Blue crab life cycle
- The Maryland Blue Crab
- Boy crabs boogie to bring females out of hiding – the wild dance of male blue crabs propels a jet of pheromones to attract would-be lovers, New Scientist, 7 April 2008
- Chesapeake watermen fear blue crab not coming back – Associated Press, July 16, 2008
- Blue Crab Info
- Carolina Blue Crab
- Blue Crab - North Carolina Division of Marine Fisheries
- Blue Crab - North Carolina Watermen
- Blue Crab Fact Sheet