Thick trough shell (Spisula solida)

Distribution data supplied by the Ocean Biodiversity Information System (OBIS). To interrogate UK data visit the NBN Atlas.Map Help

Summary

Description

Spisula solida can reach lengths up of 5 cm. It has a triangular outline with rounded corners. Fine concentric lines and grooves are grouped close together on either side of the beaks. The outer shell surface is brownish or yellowish-white. The shell is white on the inside. The three cardinal teeth of the left valve are fused and short, extending only half way to the inner hinge plate rim, whereas the right valve has two short cardinal teeth. The left valve has single, elongate, anterior and posterior lateral teeth and the right valve has paired anterior and posterior lateral teeth.

Recorded distribution in Britain and Ireland

Recorded at scattered locations around the coasts of Britain and Ireland.

Global distribution

Spisula solida is distributed from subarctic Iceland and Norway as far south as Portugal and Morocco but is not found in the Mediterranean.

Habitat

Spisula solida is a burrowing bivalve occasionally found at low water but more usually in the sublittoral. It prefers sandy beds with continually moving water and avoids mud and stagnant water.

Depth range

5-50 m

Identifying features

  • Sub triangular shell.
  • Coarse concentric sculpturing with distinct growth lines.
  • The three cardinal teeth of the left valve are fused and short, extending only half way to the inner hinge plate rim, whereas the right valve has two short cardinal teeth.
  • Lateral teeth are serrated or ridged.
  • The left valve has single, elongate, anterior and posterior lateral teeth and the right valve has paired anterior and posterior lateral teeth.
  • Solid umbones on the midline.

Additional information

Spisula solida may be confused with Spisula elliptica, however the latter is smaller and more delicate. Spisula elliptica is also narrower relative to its length. Spisula solida may also be confused with Mactra stultorum but the cardinal teeth of the latter are smooth rather than ridged. Please note: the biology of Spisula solida is poorly known and information on closely related species has been used where appropriate.

Listed by

- none -

Biology review

Taxonomy

LevelScientific nameCommon name
PhylumMollusca
ClassBivalvia
FamilyMactridae
GenusSpisula
Authority(Linnaeus, 1758)
Recent Synonyms

Biology

ParameterData
Typical abundanceHigh density
Male size range<5 cm
Male size at maturity~2.5 cm
Female size range~2.5 cm
Female size at maturity
Growth formBivalved
Growth rateSee additional information
Body flexibilityNone (less than 10 degrees)
MobilityBurrower
Characteristic feeding methodActive suspension feeder
Diet/food sourcePlanktotroph
Typically feeds onPhytoplankton (i.e. diatoms)
SociabilityNo information
Environmental positionInfaunal
DependencyNo information found.
SupportsNo information found
Is the species harmful?No

Biology information

Abundance and biomass. The abundance of Spisula solida varies with location. For example, the following abundances and biomass were reported:

  • 0-240 ind./m² (0-2046 g/m²) at Røde Klit Sand (Denmark) (Kristensen, 1996);
  • 0-45 ind./m² (0-632 g/m²) at Horns Reef (Denmark) (Kristensen, 1996); whereas
  • 2000 ind./m2in Start Bay (UK) (Ford, 1925).

In Danish waters, the average biomass of Spisula solida was 265 g/m² in the Røde Klit Sand 103 g/m² at Horns Reef (Kristensen, 1996). In Waterford Harbour, (Ireland) the maximum biomass was 600 g/m2 (Fahy et al., 2003).

Growth. The growth of Spisula solida is rapid during its first two years and then slows down (Gaspar et al., 1995; Kristensen, 1996). This rapid increase in size was reported in Waterford Harbour where the number of Spisula solida per kilogramme declined rapidly between the ages of two and three  (769 - 227 ind./kg) (Fahy et al., 2003). Over the following three years, this figure halved again to 101 ind./kg (Fahy et al., 2003). Growth can be influenced by environmental factors, particularly density. For instance, Weinberg & Hesler (1996) compared growth curves of Spisula solidissima in two areas off the New Jersey and Delmarva coasts (U.S.) and the Long Island and South New England coasts (U.S.) following a hypoxic event, which resulted in mortalities in the southernmost in 1976. Both growth and maximum shell length declined in Long Island/South New England, whereas in New Jersey/Dekmarva growth and shell length remained constant and had not been affected by the hypoxia. Weinberg & Hesler (1996) suggested that following the hypoxia, the first clams to recolonize grew more rapidly in the presence of a good food supply and without competitors.

Growth rates. Clear shell sculpture marks occur on Spisula solida, suggesting annual rings, but their interpretation is not straightforward (Fahy et al., 2003). The shell surface of Spisula solida also exhibits some disturbance lines, that are impossible to distinguish from annual growth lines therefore internal bands are used (Gaspar et al., 1995). Taylor et al. (1969,1973; cited in Fahy et al., 2003) described the shells of the superfamily Mactracea. Their shells are composed of two layers of aragonite: a white, opaque, outer layer, consisting of crossed lamellar crystalline structure, which is separated by the pallial myostracum from a grey, somewhat translucent, inner layer. The white outer shell layer and the chondrophore are streaked periodically with dark lines (internal growth lines). This structure confirms the presence of true annuli, which external sculpture alone might not indicate. During winter, wide growth increments are deposited, which is characteristic of rapid shell growth whilst narrow-spaced dark zones are formed in summer (Gaspar et al., 1995). The maximum length of Spisula solida (5 cm) from Irish waters is similar to that of northern European stocks but growth rates appear to vary geographically. Dimensions attained by Irish Spisula solida differ from those reported from other northern European stocks of the species. In the Danish North Sea, individuals between 2 and 3 years reached a length of 3.5 cm. Meixner (1994; cited in Fahy et al., 2003) reported that Spisula solida 3.5 cm in length from the German North Sea similarly averaged 2.5 years old while in Waterford Harbour individuals were 5.27 years at the same length (Fahy et al., 2003).

Habitat preferences

ParameterData
Physiographic preferencesOpen coast, Offshore seabed, Strait or Sound
Biological zone preferencesLower eulittoral, Lower infralittoral, Sublittoral fringe, Upper infralittoral
Substratum / habitat preferencesFine clean sand, Gravel / shingle, Mixed, Pebbles
Tidal strength preferencesModerately strong 1 to 3 knots (0.5-1.5 m/sec.), Strong 3 to 6 knots (1.5-3 m/sec.), Weak < 1 knot (<0.5 m/sec.)
Wave exposure preferencesExposed, Moderately exposed, Sheltered, Very exposed
Salinity preferencesFull (30-40 psu)
Depth range5-50 m
Other preferencesNo text entered
Migration PatternNon-migratory or resident

Habitat Information

Kristensen (1996) reported that Spisula solida showed a preference for grain sizes that ranged between 2-3 mm. The population of Spisula solida in Waterford Harbour, (Ireland) conformed to the grain size preference above. Spisula solida can be found at depths of 50 m (Schlieper et al., 1967). But in the North Sea, Spisula solida is restricted to depths of about 10-15 m (Theede et al., 1969). Whereas, in Portuguese waters, Spisula solida is more common in greater abundances at depths between 5-13 metres (Gaspar et al., 1999).

Life history

Adult characteristics

ParameterData
Reproductive typeGonochoristic (dioecious)
Reproductive frequency Annual protracted
Fecundity (number of eggs)No information
Generation timeInsufficient information
Age at maturity1 year
SeasonFebruary - June
Life span5-10 years

Larval characteristics

ParameterData
Larval/propagule type-
Larval/juvenile development Planktotrophic
Duration of larval stageNo information
Larval dispersal potential See additional information
Larval settlement periodInsufficient information

Life history information

Longevity. The life expectancy of Spisula solida is up to approximately ten years (Fahy, 2003).

Sexual maturity. Spisula solida reaches sexual maturity during its first year, which is a function of age, not of size (Gaspar & Monteiro,1999; Fahy et al., 2003).

Gametogenesis. The sexes of Spisula solida are separate and there are no records of hermaphrodites (Gaspar & Monteiro, 1999). Male and female white clams are distinguishable externally since the colour of the gonad in this species is reddish in the females and yellowish-orange in the males (Gaspar & Monteiro, 1999). Both sexes show synchrony in gametogenic development and spawning. Gaspar & Monteiro (1999) observed that gametogenesis in Spisula solida began when the seawater temperature started to decrease (late September). Gaspar et al. (1999) concluded that the initiation of gametogenesis in Spisula solida was a response to falling temperature and that spawning occurred when the temperature began to rise rather than occurring at a fixed temperature. The maturation of the gonad continued until late January when the water temperature was at its lowest (Gaspar & Monteiro, 1999). In Danish waters specimens of Spisula solida were sexually inactive from July-Sept. The first ripe stage of gonads was reached in December, and all individuals were ripe by January (Gaspar & Monteiro, 1999).

Spawning. Spawning begins in February (Gaspar & Monteiro, 1999). Gaspar & Monteiro (1999) noted that 75% of a studied population were in the spent stage of their gametogenic cycle by June (Gaspar & Monteiro, 1999).

Dispersal. Ford (1925) suggested that Spisula solida can be moved along by water movement (bed load transport) along the sea bottom to another position on the seabed. Therefore, in the course of time considerable mixing could easily bring together individuals of different ages and origins (Ford, 1925).

Recruitment. In Ireland the recruitment of Spisula solida is irregular with one year old clams out numbering all the other year classes (Fahy et al., 2003). The reasons for this are unknown. However, irregular settlement rather than erratic gamete production might be the explanation for the occasional strong representation of a year class in Waterford Harbour clam population (Fahy, 2003).

Sensitivity reviewHow is sensitivity assessed?

Physical pressures

Use / to open/close text displayed

 IntoleranceRecoverabilitySensitivityEvidence / Confidence
Substratum loss [Show more]

Substratum loss

Benchmark. All of the substratum occupied by the species or biotope under consideration is removed. A single event is assumed for sensitivity assessment. Once the activity or event has stopped (or between regular events) suitable substratum remains or is deposited. Species or community recovery assumes that the substratum within the habitat preferences of the original species or community is present. Further details

Evidence

Removal of the substratum would also remove the entire population of Spisula solida and so intolerance has been assessed as high with a high recoverability.

High High Moderate Low
Smothering [Show more]

Smothering

Benchmark. All of the population of a species or an area of a biotope is smothered by sediment to a depth of 5 cm above the substratum for one month. Impermeable materials, such as concrete, oil, or tar, are likely to have a greater effect. Further details.

Evidence

Spisula solida is a fast burrowing bivalve. If Spisula solida were covered by sediments it would be able to reposition itself within the sediment. The location of the Waterford clam bed (Ireland) was examined in 2001. Fishermen compared the areas of the clam bed that provided the heaviest catches in two years. It was concluded that the location of the heaviest catches had moved slightly to the north-west of the harbour as part of the existing bed had silted up. This reduced the numbers of Spisula solida and the size of the clam patch (Fahy et al., 2003). However, intolerance has been assessed as intermediate to reflect the reduction in the size of the clam bed and Spisula numbers. Recoverability is assessed as high.

Intermediate High Low Moderate
Increase in suspended sediment [Show more]

Increase in suspended sediment

Benchmark. An arbitrary short-term, acute change in background suspended sediment concentration e.g., a change of 100 mg/l for one month. The resultant light attenuation effects are addressed under turbidity, and the effects of rapid settling out of suspended sediment are addressed under smothering. Further details

Evidence

Levels of suspended sediment are likely to be most relevant to feeding. An increase in suspended sediment is likely to increase the rate of siltation (see smothering above) and the availability of food as Spisula solida is a suspension feeder. However, if the level of suspended sediment become too high it could cause the feeding structures to become clogged. It is unlikely that mortality would occur, therefore intolerance has been assessed as low with a very high recoverability.

Low Very high Very Low Very low
Decrease in suspended sediment [Show more]

Decrease in suspended sediment

Benchmark. An arbitrary short-term, acute change in background suspended sediment concentration e.g., a change of 100 mg/l for one month. The resultant light attenuation effects are addressed under turbidity, and the effects of rapid settling out of suspended sediment are addressed under smothering. Further details

Evidence

Levels of suspended sediment are likely to be most relevant to feeding. A decrease in suspended sediment is likely to decrease the availability of food for suspension feeding bivalves. Mortality is unlikely to occur within 1 month (see benchmark) and so intolerance is assessed as low. When suspended sediment levels return to normal, so too should food availability and feeding.

Low Immediate Not sensitive
Desiccation [Show more]

Desiccation

  1. A normally subtidal, demersal or pelagic species including intertidal migratory or under-boulder species is continuously exposed to air and sunshine for one hour.
  2. A normally intertidal species or community is exposed to a change in desiccation equivalent to a change in position of one vertical biological zone on the shore, e.g., from upper eulittoral to the mid eulittoral or from sublittoral fringe to lower eulittoral for a period of one year. Further details.

Evidence

Spisula solida can be found occasionally in the intertidal. A change in desiccation at the benchmark level would affect Spisula solida at the upper limit of their distribution and may cause mortalities. Therefore intolerance is assessed as intermediate with a high recoverability.

Intermediate High Low Very low
Increase in emergence regime [Show more]

Increase in emergence regime

Benchmark. A one hour change in the time covered or not covered by the sea for a period of one year. Further details

Evidence

An increase in emergence at the benchmark level, would most likely to reduce the upper limits of Spisula solida and a portion of the population may be lost. Therefore intolerance is assessed as intermediate with high recoverability a recoverability.

Intermediate High Low Very low
Decrease in emergence regime [Show more]

Decrease in emergence regime

Benchmark. A one hour change in the time covered or not covered by the sea for a period of one year. Further details

Evidence

A decrease in emergence at the benchmark level would benefit individuals ofSpisula solida allowing them to colonize further up the shoreline. Therefore, Spisula solida is tolerant* of this factor.

Tolerant* Not relevant Not sensitive*
Increase in water flow rate [Show more]

Increase in water flow rate

A change of two categories in water flow rate (view glossary) for 1 year, for example, from moderately strong (1-3 knots) to very weak (negligible). Further details

Evidence

Spisula solida is found in areas ranging from strong to weak water flow. The increased water flow rate at the benchmark level would change the sediment characteristics in which the species lives. The substrata may be disturbed and the sediment on the seabed may erode. This scouring of sand and gravel causes coarse sediments to become unstable and difficult to burrow. Additionally, an increase in water flow may interfere with feeding and respiration.
Increased water flow may also lead to the dislodgement and abrasion of Spisula solida. However, the worn appearance of Spisula solida shells indicate that they inhabit areas of considerable water movement. A proportion of the population of Spisula solida may also be transported to another position on the seabed (bedload transport). Increased water flow may also prevent the settlement of larvae and juveniles decreasing the recruitment to an area (Hiscock, 1983). Therefore intolerance is assessed as intermediate with a high recoverability.

Intermediate High Low Moderate
Decrease in water flow rate [Show more]

Decrease in water flow rate

A change of two categories in water flow rate (view glossary) for 1 year, for example, from moderately strong (1-3 knots) to very weak (negligible). Further details

Evidence

Spisula solida is found in areas ranging from strong to weak water flow. A decreased water flow rate may lower the dispersion of planktonic larvae and recruitment from other areas would be minimal. A decrease in water flow at the benchmark level would also result in increased deposition of fine suspended sediment (Hiscock, 1983), changing the sediment characteristics of the habitat in which the species lives. This may cause the substratum to become too muddy for Spisula solida which prefers sandy sediments and mixed sediments and avoids muddy sediments. Some mortality is, therefore, expected and an intolerance of intermediate is recorded. Recoverability is assessed as high

Intermediate High Low Low
Increase in temperature [Show more]

Increase in temperature

  1. A short-term, acute change in temperature; e.g., a 5°C change in the temperature range for three consecutive days. This definition includes ‘short-term’ thermal discharges.
  2. A long-term, chronic change in temperature; e.g. a 2°C change in the temperature range for a year. This definition includes ‘long term’ thermal discharges.

For intertidal species or communities, the range of temperatures includes the air temperature regime for that species or community. Further details

Evidence

Schlieper et al. (1967) state that the upper temperature tolerance of Spisula solida is 30°C. Fahy et al. (2003) stated that the optimum condition of Spisula solida occurred at low temperature. However, Spisula solida does occur in areas as far south as Portugal and Morocco and is unlikely to be affected by an increases in temperature experienced in British and Irish waters. Therefore, Spisula solida would probably be tolerant of an increase in temperature at the benchmark level.

Tolerant Not relevant Not sensitive Low
Decrease in temperature [Show more]

Decrease in temperature

  1. A short-term, acute change in temperature; e.g., a 5°C change in the temperature range for three consecutive days. This definition includes ‘short-term’ thermal discharges.
  2. A long-term, chronic change in temperature; e.g. a 2°C change in the temperature range for a year. This definition includes ‘long term’ thermal discharges.

For intertidal species or communities, the range of temperatures includes the air temperature regime for that species or community. Further details

Evidence

Fahy et al. (2003) stated that the optimum condition of Spisula solida occurred at low temperatures. Spisula solida also occurs as far north as sub-arctic Iceland and Norway. Therefore, Spisula solida would probably be tolerant of an increase in temperature at the benchmark level. However, the Spisula solida population of Red Wharf Bay, Anglesey was reported to demonstrate 'exceptionally heavy mortality' as a result of the 1962/63 winter (Crisp, 1964). Futhermore, the clam disappeared from the entire German Bight above the 20 m depth contour line during the 1995/96 winter where water temperatures at the sea bottom dropped to 0°C (M. Ruth, pers. comm.). Therefore, Spisula solida is probably highly intolerant of an acute temperature change, at the benchmark level.

High High Moderate Moderate
Increase in turbidity [Show more]

Increase in turbidity

  1. A short-term, acute change; e.g., two categories of the water clarity scale (see glossary) for one month, such as from medium to extreme turbidity.
  2. A long-term, chronic change; e.g., one category of the water clarity scale (see glossary) for one year, such as from low to medium turbidity. Further details

Evidence

Spisula solida does not require light and therefore the effects of increased turbidity on light attenuation are not directly relevant. An increase in turbidity may affect primary production in the water column and therefore reduce the availability of food. A turbidity increase for a year (see benchmark) would reduce the availability of food that would probably affect growth and fecundity and an intolerance of low is recorded. As soon as light levels return to normal, primary production will increase and hence recoverability is recorded as very high.

Low Very high Very Low Low
Decrease in turbidity [Show more]

Decrease in turbidity

  1. A short-term, acute change; e.g., two categories of the water clarity scale (see glossary) for one month, such as from medium to extreme turbidity.
  2. A long-term, chronic change; e.g., one category of the water clarity scale (see glossary) for one year, such as from low to medium turbidity. Further details

Evidence

Spisula solida does not require light and therefore the effects of increased turbidity on light attenuation are not directly relevant. A decrease in turbidity would increase primary production in the water column and food availability. Therefore it is likely that Spisula solida would be tolerant of a decrease in turbidity.

Tolerant Not relevant Not sensitive Low
Increase in wave exposure [Show more]

Increase in wave exposure

A change of two ranks on the wave exposure scale (view glossary) e.g., from Exposed to Extremely exposed for a period of one year. Further details

Evidence

Spisula solida occurs in wave exposed to wave sheltered areas. This suggests that the species would be tolerant of a certain degree of sediment mobility associated with strong wave action. An increase in wave exposure (at the benchmark level) would place the majority of the population in areas frequently subject to strong wave action and the species may be affected in several ways. Strong wave action may cause damage or withdrawal of the siphons, resulting in loss of feeding opportunities and compromised growth. Furthermore, individuals may be dislodged by scouring from sand and gravel mobilized by increased wave action. Breon (1970; cited in Chícharo et al., 2002) reported that Spisula subtruncata, a species with a depth distribution similar to Spisula solida, exhibited increased burrowing activity when disturbed by wave action. Therefore intolerance is assessed as intermediate with a high recoverability.

Intermediate High Low Moderate
Decrease in wave exposure [Show more]

Decrease in wave exposure

A change of two ranks on the wave exposure scale (view glossary) e.g., from Exposed to Extremely exposed for a period of one year. Further details

Evidence

Spisula solida occurs in wave exposed to wave sheltered areas. Decreased wave exposure at the benchmark level is likely to result in the establishment of more stable muddy sediment habitats. It is likely that this would result in mortality of Spisula solida. Spisula solida may also probably suffer increased competition from species better adapted to life in low energy environments. Intolerance is therefore assessed as intermediate with a high recoverability.

Intermediate High Low Moderate
Noise [Show more]

Noise

  1. Underwater noise levels e.g., the regular passing of a 30-metre trawler at 100 metres or a working cutter-suction transfer dredge at 100 metres for one month during important feeding or breeding periods.
  2. Atmospheric noise levels e.g., the regular passing of a Boeing 737 passenger jet 300 metres overhead for one month during important feeding or breeding periods. Further details

Evidence

No information was found concerning the effects of noise on Spisula solida.

No information Not relevant No information Low
Visual presence [Show more]

Visual presence

Benchmark. The continuous presence for one month of moving objects not naturally found in the marine environment (e.g., boats, machinery, and humans) within the visual envelope of the species or community under consideration. Further details

Evidence

Spisula solida probably has little visual acuity and has been recorded as not sensitive to this factor.

No information Not relevant No information Low
Abrasion & physical disturbance [Show more]

Abrasion & physical disturbance

Benchmark. Force equivalent to a standard scallop dredge landing on or being dragged across the organism. A single event is assumed for assessment. This factor includes mechanical interference, crushing, physical blows against, or rubbing and erosion of the organism or habitat of interest. Where trampling is relevant, the evidence and trampling intensity will be reported in the rationale. Further details.

Evidence

The worn appearance of Spisula solida shells indicate that they inhabit areas of considerable water movement showing some tolerance for the effects of water movement on their robust shells (Ford, 1925).
Fishing for demersal species will disturb the surface layer of sediment and any protruding or shallow burrowing species. In Portugal, Spisula solida is caught at a depth of 7-9 m with a tooth dredge that can penetrate the sediment to a depth of 50 cm. Gaspar et al. (2002) noted that 93% of the uncaught Spisula solida were undamaged after experimental trawls, as they were well protected by their thick shells, and only 1% of the uncaught Spisula solida died (Gaspar et al., 2002).

 


The impacts caused by a fishing dredge significantly increased the number of exposed Spisula solida clams and the abundance of potential predators (Chícharo et al., 2002). The impact of the dredge increased the time needed for Spisula solida to rebury, which rendered them vulnerable to predation for longer periods (Chícharo et al., 2002). Under controlled conditions, it took Spisula solida three minutes to rebury themselves when displaced to the surface. However under trawling/dredging conditions it took Spisula solida nine minutes to rebury back into the sediments (Chícharo et al., 2002). Chícharo et al. (2002) stated that only 6% of Spisula solida not caught by the dredge were damaged and 94% were classified as having none or slight damage. Therefore intolerance has been assessed as intermediate as mortality may occur and recoverability has been assessed as high.

 

Intermediate High Low Low
Displacement [Show more]

Displacement

Benchmark. Removal of the organism from the substratum and displacement from its original position onto a suitable substratum. A single event is assumed for assessment. Further details

Evidence

Spisula solida can burrow back down into the sediment very rapidly in its preferred substrata when it is displaced to the surface, therefore it is probably relatively tolerant of displacement. Spisula solida are subject to considerable water movements that cause displacement, which can carry individuals to another position where they will once again settle (Ford, 1925). This can be seen when different morphologies of Spisula solida occur in the same area. It is unlikely that mortalities will occur as Spisula solida has a thick solid shell and individual Spisula solida are often found with a worn appearance that is consistent with such activity (Ford, 1925).

 


The impacts caused by a fishing dredge significantly increased the number of exposed Spisula solida clams and the abundance of potential predators (Chícharo et al., 2002). The impact of the dredge increased the time needed for Spisula solida to rebury and rendered them vulnerable to predation for longer periods (Chícharo et al., 2002). Under controlled conditions it took Spisula solida three minutes to rebury when displaced however under trawling/dredging conditions it took Spisula solida nine minutes to rebury back into the sediments (Chícharo et al., 2002).

 


However such displacement could result in a loss of recruitment, increased predation and loss of mature individuals which will affect the viability of a population. Therefore intolerance is assessed as intermediate with a high recoverability.

Intermediate High Low Moderate

Chemical pressures

Use [show more] / [show less] to open/close text displayed

 IntoleranceRecoverabilitySensitivityEvidence / Confidence
Synthetic compound contamination [Show more]

Synthetic compound contamination

Sensitivity is assessed against the available evidence for the effects of contaminants on the species (or closely related species at low confidence) or community of interest. For example:

  • evidence of mass mortality of a population of the species or community of interest (either short or long term) in response to a contaminant will be ranked as high sensitivity;
  • evidence of reduced abundance, or extent of a population of the species or community of interest (either short or long term) in response to a contaminant will be ranked as intermediate sensitivity;
  • evidence of sub-lethal effects or reduced reproductive potential of a population of the species or community of interest will be assessed as low sensitivity.

The evidence used is stated in the rationale. Where the assessment can be based on a known activity then this is stated. The tolerance to contaminants of species of interest will be included in the rationale when available; together with relevant supporting material. Further details.

Evidence

Effects of synthetic contamination on bivalves are listed below.

  • The burrowing and avoidance behaviour in the bivalves Tellina tenuis, Abra alba and Macoma balthica becomes impaired when they are exposed to phenol but no deaths occurred. Impairment of burrowing can leave bivalves vulnerable to predation and wave action (Møhlen & Kiørboe, 1983).
  • High levels of tributyl tin (TBT), was implicated in slow growth and shell malformation 'balling' in the oyster Magallana gigas and larval mortality in Mytilus edulis (Beaumont et al., 1989) reducing recruitment levels. When exposed to 1-3 µgTBT/l Cerastoderma edule and Scobicularia plana suffered 100% mortality after two and ten weeks respectively (Beaumont et al., 1989).

There is also evidence that TBT causes recruitment failure in bivalves, either due to reproductive failure or larval mortality (Bryan & Gibbs, 1991). No information could be found on the effects of synthetic chemicals on Spisula solida. However, given the likely effects of TBT on bivalves, an intolerance of intermediate has been suggested, albeit with very low confidence.

Intermediate High Low Very low
Heavy metal contamination [Show more]

Heavy metal contamination

Evidence

Many bivalve species accumulate heavy metals in their tissues, far in excess of environmental levels. Examples of the sub-lethal effects of heavy metals include: siphon retraction, valve closure, inhibition of byssal thread production, disruption of burrowing behaviour, inhibition of respiration, inhibition of filtration rate, inhibition of protein synthesis and suppressed growth (see review by Aberkali & Trueman, 1985). Bryan (1984), suggested that Hg was the most toxic metal to bivalve molluscs in experimental studies while copper (Cu), cadmium (Cd) and zinc (Zn) were the most problematic for bivalves in the field. For example:

  • exposure to 15 parts per billion (ppb) of copper was found to produce deformed embryos in Crassostrea virginicaand 33 ppb proved lethal to their larvae (Bryan, 1984).
  • adults, on the other hand could withstand exposure to such levels, although through the immobilization of copper, they become green and unpalatable (Bryan, 1984);
  • exposure to 100 ppb of cadmium for 15 weeks induced poor conditions and mortalities in adult Crassostrea virginica (Bryan, 1984).

No information specifically concerning the effects of heavy metal contamination on Spisula solida was found. However, the above evidence suggests that they may demonstrate sub-lethal effects, and in some cases, mortalities due to heavy metal contamination. Therefore, an intolerance of intermediate has been suggested, albeit with very low confidence.

Intermediate High Low Very low
Hydrocarbon contamination [Show more]

Hydrocarbon contamination

Evidence

The effects of oil on invertebrate molluscs include:

  • substantially reduced feeding rates and / or food detection ability probably due to ciliary inhibition;
  • an increase in energy expenditure and a decrease in feeding rate, resulting in less energy available for growth and reproduction; and
  • reduced infaunal burrowing rates at sublethal concentrations (Suchanek, 1993).

Spisula solidissima, a relative of Spisula solida, was exposed to oil during the North Cape oil spill on the coast of Rhode island (USA) (McCay et al., 2003). The number of bivalve mortalities was estimated by impact assessment modeling of acute toxicity. Results showed that Solida solidissima comprised of 97% of the total loss of bivalve production from the spill affected area with up to 40% mortality. It is probable that hydrocarbons would have a similar effect on Spisula solida, however no specific information could be found concerning the effects of hydrocarbons on Spisula solida. Therefore, an intolerance of intermediate has been suggested, albeit with low confidence.

Intermediate High NR Low
Radionuclide contamination [Show more]

Radionuclide contamination

Evidence

No information was found on the effects of radionuclides on Spisula solida.

No information Not relevant No information Not relevant
Changes in nutrient levels [Show more]

Changes in nutrient levels

Evidence

Increased nutrients are likely to enhance ephemeral algal and phytoplankton growth, increase organic material deposition and enhance bacterial growth. At low levels, an increase in phytoplankton may increase food availability for Spisula solida. However, increased levels of nutrients (beyond the carrying capacity of the environment) may result in eutrophication, algal blooms and reductions in oxygen concentrations that can cause hypoxia. Rosenberg & Loo (1988) reported mass mortalities of the bivalves Mya arenaria and Cerastoderma edule following a eutrophication event in Sweden, however no direct causal link was established. Spisula sp. were reported to accumulate algal toxins (e.g. saxitoxin and neosaxitoxin) in their tissues, and to retain toxins for long periods of time, ranging from months to over three years (see review by Landsberg, 1996). However, Landsberg (1996) found no evidence of resultant neoplasias (cancers) in Spisula sp. and did not report evidence of mortalities in Spisula sp. induced by algal blooms. However, Mahoney & Steimle (1979) reported mass mortalities of Spisula solidissima off the coast of New Jersey, due to of bottom water oxygen deficiency, as a result of the decay of a bloom of the dinoflagellate Ceratium tripos (see oxygenation below). Therefore, while Spisula sp. May be relatively tolerant of algal toxins, algal blooms may indirectly cause mortality due to hypoxia. Therefore, a dramatic increase in nutrient levels may cause some mortality of Spisula solida, and an intolerance of intermediate has been reported.

Intermediate High Low Low
Increase in salinity [Show more]

Increase in salinity

  1. A short-term, acute change; e.g., a change of two categories from the MNCR salinity scale for one week (view glossary) such as from full to reduced.
  2. A long-term, chronic change; e.g., a change of one category from the MNCR salinity scale for one year (view glossary) such as from reduced to low. Further details.

Evidence

Spisula solida is typically found in full salinity conditions. Spisula solida exhibited the lowest salinity tolerance of excised gill tissues compared to the other species tested. After 24 hours, ciliary activity of 4 to 8 mm² gill pieces was observed in salinities that ranged from 15 to 50 parts per thousand (Theede, 1965; reported in Kinne, 1971b). The whole animal is likely to tolerate changes in salinity for longer, since it can isolate itself from its surroundings by closing its valves. However, at the benchmark level, an acute change for a period of 1 week or a chronic change for a year is likely to result in mortality. Therefore, an intolerance of high has been recorded.

High High Moderate Low
Decrease in salinity [Show more]

Decrease in salinity

  1. A short-term, acute change; e.g., a change of two categories from the MNCR salinity scale for one week (view glossary) such as from full to reduced.
  2. A long-term, chronic change; e.g., a change of one category from the MNCR salinity scale for one year (view glossary) such as from reduced to low. Further details.

Evidence

Spisula solida exhibited the lowest salinity tolerance of excised gill tissues compared to the other species tested. After 24 hours, ciliary activity of 4 to 8 mm² gill pieces was observed in salinities that ranged from 15 to 50 parts per thousand (Kinne, 1971b). The whole animal is likely to tolerate changes in salinity for longer, since it can isolate itself from its surroundings by closing its valves. Spisula solida is typically found at full salinities (Theede et al., 1969) and is likely to be intolerant of a decrease in salinity. Distributionally, Spisula solida extends into the Kattegat (Sweden) but does not enter the brackish waters of the Baltic Sea as the salinity is lower (Theede et al., 1969). At the benchmark level, an acute change for a period of 1 week or a chronic change for a year is likely to result in mortality. Therefore intolerance has been assessed to be high with a high recoverability.

High High Moderate Low
Changes in oxygenation [Show more]

Changes in oxygenation

Benchmark.  Exposure to a dissolved oxygen concentration of 2 mg/l for one week. Further details.

Evidence

Diaz & Rosenberg (1995) list Spisula solida as sensitive to hypoxic events. Spisula solida exhibited the fastest declines in ciliary movement in excised gill tissue, compared to other species tested at oxygen concentrations of 0.21 mg/l (Theede at al., 1969). Excised gill tissues of Spisula solida showed irreversible damage after 4 days under anoxic conditions after which ciliary movement completely stopped. The tolerance of the whole animal is likely to be longer, since it can shut itself off from the surrounding water by closing its valves.
Decay of an immense bloom of the dinoflagellate Ceratium tripos caused severe hypoxia over a 13,000 km² in the New York bight in 1976 (Mahoney & Steimle, 1979). The oxygen levels dropped 2ml/l (2.8 mg/l) over a wide area, and to as low as 0.1 ml/l (0.14 mg/l) in the worst affected areas, with an associated increase in hydrogen sulphide levels. Spisula solidissima was the most affected species and exhibited an estimated 69% mortality (Mahoney & Steimle, 1979).

 

Overall, the above evidence suggests that Spisula solida and related species are relatively intolerant of hypoxic conditions. Therefore, a change in oxygenation at the benchmark level would probably cause the population of Spisula solida to collapse and recoverability would be reliant on outside recruitment. Therefore intolerance is assessed as high with a high recoverability.

High High Moderate High

Biological pressures

Use [show more] / [show less] to open/close text displayed

 IntoleranceRecoverabilitySensitivityEvidence / Confidence
Introduction of microbial pathogens/parasites [Show more]

Introduction of microbial pathogens/parasites

Benchmark. Sensitivity can only be assessed relative to a known, named disease, likely to cause partial loss of a species population or community. Further details.

Evidence

A number of organisms have been found living on and in individual specimens of Spisula solida.

  • The gregarine Nematopis schneideri utilizes Spisula solida as an intermediate host (Lauckner, 1983).
  • The ciliate Thigmorphyra bivalviorum was found on the gills of Spisula solida (Fenchel, 1965). However no information on their effects on Spisula solida could be found.
  • The pea crab Pinnotheres pisum lives inside the shells of living bivalves. Møller Christensen (1962;cited in Lauckner, 1983) found an ovigenous female in Spisula solida. Berner (1952; cited in Cheung, 1967) noted that there was a partial or complete cessation in the production of gametes in those individuals that were infected with Pinnotheres pisum that averaged 1 cm or more in carapace length (CL). Smaller crabs very seldom affect bivalves in the manner above.

Therefore, intolerance is assessed as intermediate to reflect the cessation in the production of gonads, with a high recoverability.

Intermediate High Low Moderate
Introduction of non-native species [Show more]

Introduction of non-native species

Sensitivity assessed against the likely effect of the introduction of alien or non-native species in Britain or Ireland. Further details.

Evidence

There is no information on the effects of non-native species on Spisula solida.

No information Not relevant No information Low
Extraction of this species [Show more]

Extraction of this species

Benchmark. Extraction removes 50% of the species or community from the area under consideration. Sensitivity will be assessed as 'intermediate'. The habitat remains intact or recovers rapidly. Any effects of the extraction process on the habitat itself are addressed under other factors, e.g. displacement, abrasion and physical disturbance, and substratum loss. Further details.

Evidence

Spisula solida is fished commercially. The impacts caused by a fishing dredge significantly increased the number of exposed Spisula solida clams and the abundance of potential predators (Chícharo et al., 2002). The impact of the dredge increased the time needed for Spisula solida individuals to rebury rendering them vulnerable to predation for longer.

 

Since 1992 a fishery for Spisula solida has taken place in Danish waters. Catches and landings were high in some years but totally absent in others during a ten year fishing period between 1992 and 2002 (Jensen et al., 2003). From 1992 to 1995 the fishery continued without any decrease in cpue (M. Ruth, pers. comm.). However, Spisula solida disappeared from the entire German Bight above the 20 m depth contour line during the 1995/96 winter where water temperatures at the sea bottom dropped to 0°C (M. Ruth, pers. comm.). 1995 also saw the fishery ending due to bad weather conditions (M. Ruth, pers. comm.). In April 1996, when the fishery tried to start again, no living Spisula solida were found (M. Ruth, pers. comm.). The suction dredging gear was subsequently modified to access Spisula solida living at greater depths.

Because the clams are fished commercially, at least some of the population will be removed and, therefore, intolerance has been assessed as intermediate. Even if the clams are not caught, the dredging will at the very least leave the clams more susceptible to predation. Recoverability will probably be high.

Intermediate High Low Moderate
Extraction of other species [Show more]

Extraction of other species

Benchmark. A species that is a required host or prey for the species under consideration (and assuming that no alternative host exists) or a keystone species in a biotope is removed. Any effects of the extraction process on the habitat itself are addressed under other factors, e.g. displacement, abrasion and physical disturbance, and substratum loss. Further details.

Evidence

No specific information was found concerning the effects of the extraction of other species on Spisula solida. Any extraction of other species using fishing gear that penetrates the seabed such as scallop dredging is likely to cause forced disturbances (as above) or remove species as bycatch. Therefore intolerance has been assessed as intermediate with a high recoverability.

Intermediate High Low Very low

Additional information

Recoverability. Spisula solida can live up to 10 years. No information was found concerning the fecundity of Spisula solida. However, when Spisula solida occur they occur in high abundances (Fahy, 2003). Growth is rapid during the first 2 years although it takes 2-3 years for Spisula solida to reach sexual maturity. Recruitment of Spisula solida can be irregular (Fahy et al., 2003). Gaspar et al. (1996 cited in Gaspar & Monteiro, 1999) noted that in Portuguese waters, there were large yearly fluctuations in the recruitment of a number of species including Spisula solida. The dispersal potential of Spisula solida is also variable as it is reliant on water movement. Ford (1925) suggested that Spisula solida can be moved along by water movement to the sea bottom to another position on the seabed. Therefore, in the course of time, considerable mixing could easily bring together individuals of different ages and origins (Ford, 1925). Although no information was found on the mortality rates of Spisula solida, mortality is probably greatest during the early post-larval period when Spisula solida are much smaller and more fragile. Therefore with the available information the recoverability of Spisula solida has been assessed as high, although further information is required.

Importance review

Policy/legislation

- no data -

Status

Non-native

ParameterData
Native-
Origin-
Date Arrived-

Importance information

Spisula solida is a potentially important commercial bivalve species, although it is under-exploited in the United Kingdom, compared to continental Europe and the USA.

European Union regulations. A minimum size limited of 2.5 cm for Spisula solida clams was imposed by European Union Council Regulation 850/98, Annex XII (Fahy et al., 2003). However Fahy et al. (2003) suggested that bars on a clam dredge should be a minimum of 11 mm apart, which corresponds to an age of three years.

Fisheries information. Commercial fishing methods screen Spisula catches so that the smaller and younger individuals are not retained by the dredge (Fahy et al., 2003). The largest of certain medium age groups will be retained and probably the oldest groups are representative of the size range within the population (Fahy et al., 2003). Spisula solida is harvested in Waterford Harbour (Ireland). The harvesting of Spisula solida was irregular and sporadic as the principal dealers landed 400 tonnes of Spisula solida in 1996, no landings were traced from 1997 or 1998 and only six tonnes were harvested in 1999 (Fahy et al., 2003). In 2000, 338 tonnes of Spisula solida was landed, however, in the following two years the number of Spisula solida dropped further as the calm bed started to become barren (Fahy et al., 2003). Kristensen (1996) stated that a biomass of less than 200 g/m2 was not considered worth fishing. Kristensen (1996) also suggested that an exploitation rate should range from 10-15%. Fahy et al. (2003) suggested likely that the above exploitation rate of Spisula solida was exceeded whenever surf clam patches were harvested in Ireland.

Food source. Spisula solida is an important component of the diet of many flatfishes.

Bibliography

  1. Aberkali, H.B. & Trueman, E.R., 1985. Effects of environmental stress on marine bivalve molluscs. Advances in Marine Biology, 22, 101-198.

  2. Beaumont, A.R., Newman, P.B., Mills, D.K., Waldock, M.J., Miller, D. & Waite, M.E., 1989. Sandy-substrate microcosm studies on tributyl tin (TBT) toxicity to marine organisms. Scientia Marina, 53, 737-743.

  3. Bryan, G.W. & Gibbs, P.E., 1991. Impact of low concentrations of tributyltin (TBT) on marine organisms: a review. In: Metal ecotoxicology: concepts and applications (ed. M.C. Newman & A.W. McIntosh), pp. 323-361. Boston: Lewis Publishers Inc.

  4. Bryan, G.W., 1984. Pollution due to heavy metals and their compounds. In Marine Ecology: A Comprehensive, Integrated Treatise on Life in the Oceans and Coastal Waters, vol. 5. Ocean Management, part 3, (ed. O. Kinne), pp.1289-1431. New York: John Wiley & Sons.

  5. Cargnelli, L.M., Griesbach, S.J., Packer, D.B. & Weissberger, E., 1999b. Essential fish habitat source document: Atlantic surfclam, Spisula solidissima, life history and habitat characteristics. NOAA Technical Memorandum, NMFS-NE-142.

  6. Cheung, T.C., 1967. Parasites of commercially important marine molluscs: The class Crustacea.

  7. Chícharo, L., Chícharo, M., Gaspar, M., Regala, J. & Alves, F., 2002. Reburial time and indirect mortality of Spisula solida clams caused by dredging. Fisheries Research, 59, 247-257.

  8. Crisp, D.J. (ed.), 1964. The effects of the severe winter of 1962-63 on marine life in Britain. Journal of Animal Ecology, 33, 165-210.

  9. Diaz, R.J. & Rosenberg, R., 1995. Marine benthic hypoxia: a review of its ecological effects and the behavioural responses of benthic macrofauna. Oceanography and Marine Biology: an Annual Review, 33, 245-303.

  10. Fahy, E., 2003. Surf clams, a very limited resource [On-line] www.marine.ie/industry+services/fisheries/in+the+press/ surf+clams+limited+resource++aug+03.pdf, 2004-03-16

  11. Fahy, E., Carroll, J. & O'Toole, M., 2003. A preliminary account of fisheries for the surf clam Spisula solida (L) (Mactracea) in Ireland [On-line] http://www.marine.ie, 2004-03-16

  12. Fenchel, T., 1965. Ciliates from Scandinavian Molluscs. Ophelia, 2, 71 - 174.

  13. Fish, J.D. & Fish, S., 1996. A student's guide to the seashore. Cambridge: Cambridge University Press.

  14. Ford, E,. 1925. On the growth of some lamellibranchs in relation to the food supply of fishes. Journal of the Marine Biological Association of the United Kingdom, 13, 531-559.

  15. Gaspar, M.B. & Monteiro, C.C., 1999. Gametogenesis and spawning in the subtidal white clam Spisula solida, in relation to temperature. Journal of the Marine Biological Association of the United Kingdom, 79, 753-755.

  16. Gaspar, M.B., Leitão, F., Santos, M.N., Sobral, M., Chícharo, L., Chícharo, A. & Monteiro, C., 2002. Influence of mesh size and tooth spacing on the proportion of damaged organisms in the catches of the portuguese clam dredge fishery. ICES Journal of Marine Science, 59,1228-1236.

  17. Gibson, R., Hextall, B. & Rogers, A., 2001. Photographic guide to the sea and seashore life of Britain and north-west Europe. Oxford: Oxford University Press.

  18. Hiscock, K., 1983. Water movement. In Sublittoral ecology. The ecology of shallow sublittoral benthos (ed. R. Earll & D.G. Erwin), pp. 58-96. Oxford: Clarendon Press.

  19. Howson, C.M. & Picton, B.E., 1997. The species directory of the marine fauna and flora of the British Isles and surrounding seas. Belfast: Ulster Museum. [Ulster Museum publication, no. 276.]

  20. Jensen, H., Kristensen, P.S. & Hoffmann, E., 2003. Sandeels and clams (Spisula sp.) in the wind turbine park at Horns Reef [On-line]. http://www.hornsrev.dk/Miljoeforhold/miljoerapporter/Tobis%20og%20spisula%20rapport-%208%20april%2003.pdf, 2004-03-18

  21. JNCC (Joint Nature Conservation Committee), 1999. Marine Environment Resource Mapping And Information Database (MERMAID): Marine Nature Conservation Review Survey Database. [on-line] http://www.jncc.gov.uk/mermaid

  22. Kinne, O., 1971b. Salinity - invertebrates. In Marine Ecology: A Comprehensive, Integrated Treatise on Life in Oceans and Coastal Waters. Vol. 1 Environmental Factors, Part 2, pp. 821-995. London: John Wiley & Sons.

  23. Kristensen, K.P., 1996. Biomass, density and growth of Spisula solida in the Danish parts of the North Sea, south of Horns Reef. International Council for the Exploration of the Seas Council Meeting Papers, C.M.1996/K:27.

  24. Lauckner, G., 1983. Diseases of Mollusca: Bivalvia. In Diseases of marine animals. Vol. II. Introduction, Bivalvia to Scaphopoda (ed. O. Kinne), pp. 477-961. Hamburg: Biologische Anstalt Helgoland.

  25. Loosanoff, V.L. & Davis, H.C., 1963. Rearing of bivalve mollusks. Advances in Marine Biology, 1, 1-136.

  26. Møhlenberg, F. & Kiørboe, T., 1983. Burrowing and avoidance behaviour in marine organisms exposed to pesticide-contaminated sediment. Marine Pollution Bulletin, 14 (2), 57-60.

  27. Mahoney, J.B. & Steimle, F.W. Jr., 1979. A mass mortality of marine animals associated with a bloom of Ceratium tripos in the New York Bight. In: Proceedings of the second International Conference on Toxic Dinoflagellate Blooms, Key Biscayne, Florida, October 31 - November 5, 1978. Toxic Dinoflagellate Blooms (ed. D.L. Taylor & H.H. Seliger), pp. 225-230. New York: Elsevier/North-Holland.

  28. Mc Cay, D.P.F., Peterson, C.H., DeAlteris, J.T. & Cuten, J., 2003. Restoration that targets function as opposed to structure: replacing lost bivalve production and filtration. Marine Ecology Progress Series, 264, 197-212.

  29. Picton, B.E. & Costello, M.J., 1998. BioMar biotope viewer: a guide to marine habitats, fauna and flora of Britain and Ireland. [CD-ROM] Environmental Sciences Unit, Trinity College, Dublin.

  30. Rosenberg, R. & Loo, L., 1988. Marine eutrophication induced oxygen deficiency: effects on soft bottom fauna, western Sweden. Ophelia, 29, 213-225.

  31. Schlieper, C., Flügel, H. & Theede, H., 1967. Experimental investigations of the cellular resistance range of marine temperate and tropical bivalves: Results of the Indian Ocean expedition of the German research association. Physiological Zoology, 40, 345-360.

  32. Snelgrove, P.V.R., Grassle, J.P. & Butman, C.A., 1998. Sediment choice by settling larvae of the bivalve Spisula solidissima (Dillyn), in flowing and still water. Marine Biology, 231, 171-190.

  33. Suchanek, T.H., 1993. Oil impacts on marine invertebrate populations and communities. American Zoologist, 33, 510-523. DOI https://doi.org/10.1093/icb/33.6.510

  34. Tebble, N., 1976. British Bivalve Seashells. A Handbook for Identification, 2nd ed. Edinburgh: British Museum (Natural History), Her Majesty's Stationary Office.

  35. Theede, H., Ponat, A., Hiroki, K. & Schlieper, C., 1969. Studies on the resistance of marine bottom invertebrates to oxygen-deficiency and hydrogen sulphide. Marine Biology, 2, 325-337.

  36. Weinberg, J.R. & Helser, T.E., 1996. Age-structure , recruitment and adult mortality in populations of the Atlantic surfclam, Spisula solidissima, from 1978 to 1997. Marine Biology, 134, 113-125.

Datasets

  1. Centre for Environmental Data and Recording, 2018. Ulster Museum Marine Surveys of Northern Ireland Coastal Waters. Occurrence dataset https://www.nmni.com/CEDaR/CEDaR-Centre-for-Environmental-Data-and-Recording.aspx accessed via NBNAtlas.org on 2018-09-25.

  2. Cofnod – North Wales Environmental Information Service, 2018. Miscellaneous records held on the Cofnod database. Occurrence dataset: https://doi.org/10.15468/hcgqsi accessed via GBIF.org on 2018-09-25.

  3. Conchological Society of Great Britain & Ireland, 2018. Mollusc (marine) data for Great Britain and Ireland - restricted access. Occurrence dataset: https://doi.org/10.15468/4bsawx accessed via GBIF.org on 2018-09-25.

  4. Conchological Society of Great Britain & Ireland, 2023. Mollusc (marine) records for Great Britain and Ireland. Occurrence dataset: https://doi.org/10.15468/aurwcz accessed via GBIF.org on 2024-09-27.

  5. Fenwick, 2018. Aphotomarine. Occurrence dataset http://www.aphotomarine.com/index.html Accessed via NBNAtlas.org on 2018-10-01

  6. Fife Nature Records Centre, 2018. St Andrews BioBlitz 2014. Occurrence dataset: https://doi.org/10.15468/erweal accessed via GBIF.org on 2018-09-27.

  7. Kent Wildlife Trust, 2018. Kent Wildlife Trust Shoresearch Intertidal Survey 2004 onwards. Occurrence dataset: https://www.kentwildlifetrust.org.uk/ accessed via NBNAtlas.org on 2018-10-01.

  8. Merseyside BioBank., 2018. Merseyside BioBank (unverified). Occurrence dataset: https://doi.org/10.15468/iou2ld accessed via GBIF.org on 2018-10-01.

  9. Merseyside BioBank., 2018. Merseyside BioBank Active Naturalists (unverified). Occurrence dataset: https://doi.org/10.15468/smzyqf accessed via GBIF.org on 2018-10-01.

  10. National Trust, 2017. National Trust Species Records. Occurrence dataset: https://doi.org/10.15468/opc6g1 accessed via GBIF.org on 2018-10-01.

  11. NBN (National Biodiversity Network) Atlas. Available from: https://www.nbnatlas.org.

  12. Norfolk Biodiversity Information Service, 2017. NBIS Records to December 2016. Occurrence dataset: https://doi.org/10.15468/jca5lo accessed via GBIF.org on 2018-10-01.

  13. OBIS (Ocean Biodiversity Information System),  2024. Global map of species distribution using gridded data. Available from: Ocean Biogeographic Information System. www.iobis.org. Accessed: 2024-11-22

  14. Outer Hebrides Biological Recording, 2018. Invertebrates (except insects), Outer Hebrides. Occurrence dataset: https://doi.org/10.15468/hpavud accessed via GBIF.org on 2018-10-01.

  15. South East Wales Biodiversity Records Centre, 2018. SEWBReC Molluscs (South East Wales). Occurrence dataset: https://doi.org/10.15468/jos5ga accessed via GBIF.org on 2018-10-02.

Citation

This review can be cited as:

Sabatini, M. 2007. Spisula solida Thick trough shell. In Tyler-Walters H. Marine Life Information Network: Biology and Sensitivity Key Information Reviews, [on-line]. Plymouth: Marine Biological Association of the United Kingdom. [cited 22-11-2024]. Available from: https://www.marlin.ac.uk/species/detail/2030

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Last Updated: 31/05/2007