Qubit Systems Inc. » Swim Tunnels

DT185 Swim Tunnel Respirometer (185L)

admin — Tue, 15 Jun 2010 12:34:12 +0000

Qubit’s swim tunnel respirometers have been developed for measuring the physiology, energetics, behavior, biomechanics and kinematics of swimming fish, through years of research and laboratory use. Applications also include flow visualization studies and public display of swimming animals. The DT185 is a 185L Swim Tunnel Respirometer.

The unique and compact design allows adequate space for movements and at the same time a low volume required for reliable oxygen consumption measurements.

Acrylic materials and square walls makes for excellent observation of animals from above and from the side. A surrounding temperature bath, external motor and built-in heat exchanger, allow accurate control of water temperatures at all times.

Product #	Volume (L)	Test Section (cm)	Fish Size (g)	Water Speed (cm/s)	Footprint (cm)	Power (V)
DT5	5	30.0 x 7.5 x 7.5	20-80	3-110	117 x 40	110 or 230
DT10	10	40.0 x 10 x 10	50-150	3-110	128 x 45	110 or 230
DT32	32	55.0 x 14 x 14	175-500	3-110	147 x 53	110 or 230
DT90	90	70.0 x 20 x 20	450-1500	5-150	188 x 71	110 or 230
DT185	185	87.5 x 25 x 25	750-1500	10-225	227 x 91	3 x 230

Features:

Anti-corrosive materials for minimum maintenance
Tool free assembly for easy cleaning and transportation
Double-lid for easy instrumentation and handling of animals
Adjustable vanes for modifying flow profile in test section
Speed control with analog input and output
Re-usable wooden crate for transportation
Ports for oxygen and temperature probes

Included:

Swim tunnel respirometer
Temperature bath (surrounding buffer tank)
Submersible flush pump
Speed control (frequency converter) with analog input and output
Fittings, tubing, tools
Maintenance kit (bearings, seals, wing nuts, washers)
User manual
Wooden crate on a flat pallet

**Custom-made swim tunnels available upon request**

Side View of Swimming Goldfish

Top View of Swimming Goldfish

Complete Swim Tunnel Setup

Andreas Pettersson, Jana Pickova and Eva Brännäs (2010). Swimming performance at different temperatures and fatty acid composition of Arctic charr (Salvelinus alpinus) fed palm and rapeseed oils. Aquaculture, volume 300, issues 1-4, 27 February 2010, Pages 176-181.

Ben Speers-Roesch, Erik Sandblom, Gigi Y. Lau, Anthony P. Farrell, and Jeffrey G. Richards (2010). Effects of environmental hypoxia on cardiac energy metabolism and performance in tilapia. Am J Physiol Regul Integr Comp Physiol 298:R104-R119.

J. D. Kieffer, L. M. Arsenault, K. Litvak (2009). Behaviour and performance of juvenile shortnose sturgeon Acipenser brevirostrum at different water velocities. Journal of Fish Biology, Volume 74 Issue 3, Pages 674 – 682.

Frank Melzner, Sandra Göbel, Martina Langenbuch, Magdalena A. Gutowska, Hans-O. Pörtner and Magnus Lucassen (2009). Swimming performance in Atlantic Cod (Gadus morhua) following long-term (4–12 months) acclimation to elevated seawater PCO2. Aquatic Toxicology, 92 (1), 30-37.

M. Vagner, C. Lefrançois, R. S. Ferrari, A. Satta and P. Domenici (2008). The effect of acute hypoxia on swimming stamina at optimal swimming speed in flathead grey mullet Mugil cephalus. Journal Marine Biology 155 (2): 183-190.

Emily A. Jones, Arianne S. Jong and David J. Ellerby (2008). The effects of acute temperature change on swimming performance in bluegill sunfish Lepomis macrochirus. Journal of Experimental Biology 211, 1386-1393.

Blank,J.M, Farwell, C.J., Morrissette, J.M., Schallert, R.J. & Block, B.A. (2007). Influence of Swimming Speed on Metabolic Rates of Juvenile Pacific Bluefin Tuna and Yellowfin Tuna. Physiol. Biochem. Zool. 80(2):167–177.

Zachary A. Sutphin, Christopher A. Myrick, and Mandi M. Brandt (2007). Swimming Performance of Sacramento Splittail Injected with Subcutaneous Marking Agents. North American Journal of Fisheries Management 2007; 27: 1378-1382.

Kendall, J.L., Lucey, K.S., Jones, E.A., Wang,J. & Ellerby, D.J. (2007). Mechanical and energetic factors underlying gait transitions in Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 4265-4271.

Jones, E.A., Kaitlyn, S.L. & Ellerby, D.J. (2007). Efficiency of labriform swimming in the Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 3422-3429.

Jason M. Blank, Charles J. Farwell, Jeffery M. Morrissette, Robert J. Schallert and Barbara A. Block (2007). Influence of Swimming Speed on Metabolic Rates of Juvenile Pacific Bluefin Tuna and Yellowfin Tuna. Physiological and Biochemical Zoology 80(2):167-177.

E. Azizi, T. Landberg and R.J. Wassersug (2007). Vertebral function during tadpole locomotion. Zoology 110(4), 290-297.

Eliason, E. J., Higgs, D.A. & Farrell, A.P. (2007). Effect of isoenergetic diets with different protein and lipid content on the growth performance and heat increment of rainbow trout. Aquaculture (in press).

Blank, J.M.; Farwell, C.J.; Schallert, R.J.; Morrissette, J.M.; Block, B.A. (2005). Metabolic Rate of the Pacific Bluefin Tuna, Thunnus orientalis. Hopkins Marine Station, Stanford University, SICB 2005 Meeting.

Svendsen, J. C., Skov, J., Bildsø, M & Steffensen, J. F. (2003). Intra-school positional preference and reduced tail beat frequency in trailing positions in schooling roach under experimental conditions. J. Fish Biol. 62, 834-846.

Taylor, J.F. Steffensen and M.P. Estrada (2003). Effects of growth hormone transgenesis on metabolic rate, exercise performance and hypoxia tolerance in tilapia hybrids. J. Fish Biol. 63: 398-409.

Korsmeyer, K., Steffensen, J. F. & Herskin, J. (2002). Energetics of rigid-body swimming, undulatory swimming, and gait transition in parrotfish (Scarus schlegeli) and triggerfish (Rhinecanthus aculeatus). J. exp. Biol. 205; 1253-1263.

Herskin, J. & Steffensen, J. F. (1998). Reduced tail beat frequency and oxygen consumption due to hydrodynamic interactions of schooling sea bass, Dicentrarchus labrax L. J. Fish Biology. 53; 366-376.

Schurmann, H. & Steffensen, J. F. (1997) Effects of temperature, hypoxia and activity on the metabolism of Atlantic cod, Gadus morhua. J. Fish Biology. 50; 1166-1180.

Bushnell, P. G., Steffensen, J. F. & Schurmann, H. (1993). Exercise metabolism of two species of cod in Arctic waters, Atlantic cod ,Gadus morhua, and uvak ,Gadus ogak. Polar Biology. 14; 14; 43-48.

Steffensen, J. F. (l985). The transition from active to ram ventilation in fishes: energetic consequences and dependence on water oxygen tension. J. exp. Biol. 114; 141-150.

Steffensen, J. F., Johansen, K. and Bushnell, P. G. (l984). An automated swimming respirometer. Comp. Biochem. Physiol. 79A; 473-476.

DT90 Swim Tunnel Respirometer (90L)

MK — Tue, 15 Jun 2010 12:32:38 +0000

The unique and compact design allows adequate space for movements and at the same time a low volume required for reliable oxygen consumption measurements.

Product#	Volume(L)	Test Section(cm)	Fish Size(g)	Water Speed(cm/s)	Footprint(cm)	Power(V)
DT5	5	30.0 x 7.5 x 7.5	20-80	3-110	117 x 40	110 or 230
DT10	10	40.0 x 10 x 10	50-150	3-110	128 x 45	110 or 230
DT32	32	55.0 x 14 x 14	175-500	3-110	147 x 53	110 or 230
DT90	90	70.0 x 20 x 20	450-1500	5-150	188 x 71	110 or 230
DT185	185	87.5 x 25 x 25	750-1500	10-225	227 x 91	3 x 230

Features:

Anti-corrosive materials for minimum maintenance
Tool free assembly for easy cleaning and transportation
Double-lid for easy instrumentation and handling of animals
Adjustable vanes for modifying flow profile in test section
Speed control with analog input and output
Re-usable wooden crate for transportation
Ports for oxygen and temperature probes

Included:

Swim tunnel respirometer
Temperature bath (surrounding buffer tank)
Submersible flush pump
Speed control (frequency converter) with analog input and output
Fittings, tubing, tools
Maintenance kit (bearings, seals, wing nuts, washers)
User manual
Wooden crate on a flat pallet

**Custom-made swim tunnels available upon request**

Side View of Swimming Goldfish

Top View of Swimming Goldfish

Complete Swim Tunnel Setup

Jones, E.A., Kaitlyn, S.L. & Ellerby, D.J. (2007). Efficiency of labriform swimming in the Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 3422-3429.

E. Azizi, T. Landberg and R.J. Wassersug (2007). Vertebral function during tadpole locomotion. Zoology 110(4), 290-297.

Schurmann, H. & Steffensen, J. F. (1997) Effects of temperature, hypoxia and activity on the metabolism of Atlantic cod, Gadus morhua. J. Fish Biology. 50; 1166-1180.

Steffensen, J. F. (l985). The transition from active to ram ventilation in fishes: energetic consequences and dependence on water oxygen tension. J. exp. Biol. 114; 141-150.

Steffensen, J. F., Johansen, K. and Bushnell, P. G. (l984). An automated swimming respirometer. Comp. Biochem. Physiol. 79A; 473-476.

DT32 Swim Tunnel Respirometer (32L)

MK — Tue, 15 Jun 2010 12:30:22 +0000

Qubit’s swim tunnel respirometers have been developed for measuring the physiology, energetics, behavior, bio-mechanics and kinematics of swimming fish, through years of research and laboratory use. Applications also include flow visualization studies and public display of swimming animals. The DT32 is a 32L Swim Tunnel Respirometer.

The unique and compact design allows adequate space for movements and at the same time a low volume required for reliable oxygen consumption measurements.

Product #	Volume (L)	Test Section (cm)	Fish Size (g)	Water Speed (cm/s)	Footprint (cm)	Power (V)
DT5	5	30.0 x 7.5 x 7.5	20-80	3-110	117 x 40	110 or 230
DT10	10	40.0 x 10 x 10	50-150	3-110	128 x 45	110 or 230
DT32	32	55.0 x 14 x 14	175-500	3-110	147 x 53	110 or 230
DT90	90	70.0 x 20 x 20	450-1500	5-150	188 x 71	110 or 230
DT185	185	87.5 x 25 x 25	750-1500	10-225	227 x 91	3 x 230

Features:

Anti-corrosive materials for minimum maintenance
Tool free assembly for easy cleaning and transportation
Double-lid for easy instrumentation and handling of animals
Adjustable vanes for modifying flow profile in test section
Speed control with analog input and output
Re-usable wooden crate for transportation
Ports for oxygen and temperature probes

Included:

Swim tunnel respirometer
Temperature bath (surrounding buffer tank)
Submersible flush pump
Speed control (frequency converter) with analog input and output
Fittings, tubing, tools
Maintenance kit (bearings, seals, wing nuts, washers)
User manual
Wooden crate on a flat pallet

**Special-made swim tunnels are made upon request**

Side View of Swimming Goldfish

Top View of Swimming Goldfish

Complete Swim Tunnel Setup

Jones, E.A., Kaitlyn, S.L. & Ellerby, D.J. (2007). Efficiency of labriform swimming in the Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 3422-3429.

E. Azizi, T. Landberg and R.J. Wassersug (2007). Vertebral function during tadpole locomotion. Zoology 110(4), 290-297.

Schurmann, H. & Steffensen, J. F. (1997) Effects of temperature, hypoxia and activity on the metabolism of Atlantic cod, Gadus morhua. J. Fish Biology. 50; 1166-1180.

Steffensen, J. F. (l985). The transition from active to ram ventilation in fishes: energetic consequences and dependence on water oxygen tension. J. exp. Biol. 114; 141-150.

Steffensen, J. F., Johansen, K. and Bushnell, P. G. (l984). An automated swimming respirometer. Comp. Biochem. Physiol. 79A; 473-476.

DT10 Swim Tunnel Respirometer (10L)

MK — Tue, 15 Jun 2010 12:28:27 +0000

The unique and compact design allows adequate space for movements and at the same time a low volume required for reliable oxygen consumption measurements.

Product #	Volume (L)	Test Section (cm)	Fish Size (g)	Water Speed (cm/s)	Footprint (cm)	Power (V)
DT5	5	30.0 x 7.5 x 7.5	20-80	3-110	117 x 40	110 or 230
DT10	10	40.0 x 10 x 10	50-150	3-110	128 x 45	110 or 230
DT32	32	55.0 x 14 x 14	175-500	3-110	147 x 53	110 or 230
DT90	90	70.0 x 20 x 20	450-1500	5-150	188 x 71	110 or 230
DT185	185	87.5 x 25 x 25	750-1500	10-225	227 x 91	3 x 230

Features:

Anti-corrosive materials for minimum maintenance
Tool free assembly for easy cleaning and transportation
Double-lid for easy instrumentation and handling of animals
Adjustable vanes for modifying flow profile in test section
Speed control with analog input and output
Re-usable wooden crate for transportation
Ports for oxygen and temperature probes

Included:

Swim tunnel respirometer
Temperature bath (surrounding buffer tank)
Submersible flush pump
Speed control (frequency converter) with analog input and output
Fittings, tubing, tools
Maintenance kit (bearings, seals, wing nuts, washers)
User manual
Wooden crate on a flat pallet

**Custom-made swim tunnels available upon request**

Side View of Swimming Goldfish

Top View of Swimming Goldfish

Complete Swim Tunnel Setup

Jones, E.A., Kaitlyn, S.L. & Ellerby, D.J. (2007). Efficiency of labriform swimming in the Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 3422-3429.

E. Azizi, T. Landberg and R.J. Wassersug (2007). Vertebral function during tadpole locomotion. Zoology 110(4), 290-297.

Schurmann, H. & Steffensen, J. F. (1997) Effects of temperature, hypoxia and activity on the metabolism of Atlantic cod, Gadus morhua. J. Fish Biology. 50; 1166-1180.

Steffensen, J. F. (l985). The transition from active to ram ventilation in fishes: energetic consequences and dependence on water oxygen tension. J. exp. Biol. 114; 141-150.

Steffensen, J. F., Johansen, K. and Bushnell, P. G. (l984). An automated swimming respirometer. Comp. Biochem. Physiol. 79A; 473-476.

DT5 Swim Tunnel Respirometer (5L)

MK — Thu, 10 Jun 2010 20:38:35 +0000

The unique and compact design allows adequate space for movements and at the same time a low volume required for reliable oxygen consumption measurements.

Product #	Volume (L)	Test Section (cm)	Fish Size (g)	Water Speed (cm/s)	Footprint (cm)	Power (V)
DT5	5	30.0 x 7.5 x 7.5	20-80	3-110	117 x 40	110 or 230
DT10	10	40.0 x 10 x 10	50-150	3-110	128 x 45	110 or 230
DT32	32	55.0 x 14 x 14	175-500	3-110	147 x 53	110 or 230
DT90	90	70.0 x 20 x 20	450-1500	5-150	188 x 71	110 or 230
DT185	185	87.5 x 25 x 25	750-1500	10-225	227 x 91	3 x 230

Features:

Anti-corrosive materials for minimum maintenance
Tool free assembly for easy cleaning and transportation
Double-lid for easy instrumentation and handling of animals
Adjustable vanes for modifying flow profile in test section
Speed control with analog input and output
Re-usable wooden crate for transportation
Ports for oxygen and temperature probes

Included:

Swim tunnel respirometer
Temperature bath (surrounding buffer tank)
Submersible flush pump
Speed control (frequency converter) with analog input and output
Fittings, tubing, tools
Maintenance kit (bearings, seals, wing nuts, washers)
User manual

**Custom-made swim tunnels are made upon request**

Side View of Swimming Goldfish

Top View of Swimming Goldfish

Complete Swim Tunnel Setup

Jones, E.A., Kaitlyn, S.L. & Ellerby, D.J. (2007). Efficiency of labriform swimming in the Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 3422-3429.

E. Azizi, T. Landberg and R.J. Wassersug (2007). Vertebral function during tadpole locomotion. Zoology 110(4), 290-297.

Schurmann, H. & Steffensen, J. F. (1997) Effects of temperature, hypoxia and activity on the metabolism of Atlantic cod, Gadus morhua. J. Fish Biology. 50; 1166-1180.

Steffensen, J. F. (l985). The transition from active to ram ventilation in fishes: energetic consequences and dependence on water oxygen tension. J. exp. Biol. 114; 141-150.

Steffensen, J. F., Johansen, K. and Bushnell, P. G. (l984). An automated swimming respirometer. Comp. Biochem. Physiol. 79A; 473-476.

DT1-1500 Swim Tunnel Respirometer (Blazka-type, 1500mL)

admin — Thu, 10 Jun 2010 19:28:34 +0000

DT1-1500 is a mini swim tunnel respirometer is designed for oxygen consumption measurements in juvenile/larval fish or aquatic invertebrates (1500 ml)

You can also use the swim tunnel respirometer for exercise physiology, bio-mechanics, kinematics, flow visualization, public display of swimming or swimming behavioral research.

Product #	Volume (mL)	Test Section (mm)	Fish Size (g)	Water Speed (cm/s)	Power (V)
DT1-170	170	ID26.4 x L100	1-4	3-37	230
DT1-170	170	ID26.4 x L100	1-4	3-37	110
DT1-1500	1500	ID55.0 x L200	4-12	3-50	230
DT1-1500	1500	ID55.0 x L200	4-12	3-50	110

Features:

Modified Blazka-type design with ports for oxygen consumption measurements
No heating of water during operation – the swim respirometer comes submerged in a buffer tank
Glass materials for convenient observation and no O2 uptake/release
Tool-free assembly for easy cleaning and handling of animals
Speed control with analog output
Strong DC brush-less motor for high speeds and long-term operation
Optional replacement glass tubes for changing the length of the test section

Included:

Swim tunnel respirometer
Ambient tank (temperature bath)
Submersible flush pump
Motor and speed control instrument with analog output
PVC fittings and tubing
Tools, extra wing nuts and spacers
User manual

Note:

Flow measurement equipment is not included, use dye technique.

For oxygen consumption measurements, use your own equipment or consider our Systems for Automated Respirometry.

References:

Jones, E.A., Kaitlyn, S.L. & Ellerby, D.J. (2007). Efficiency of labriform swimming in the Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 3422-3429.

E. Azizi, T. Landberg and R.J. Wassersug (2007). Vertebral function during tadpole locomotion. Zoology 110(4), 290-297.

Schurmann, H. & Steffensen, J. F. (1997) Effects of temperature, hypoxia and activity on the metabolism of Atlantic cod, Gadus morhua. J. Fish Biology. 50; 1166-1180.

Steffensen, J. F. (l985). The transition from active to ram ventilation in fishes: energetic consequences and dependence on water oxygen tension. J. exp. Biol. 114; 141-150.

Steffensen, J. F., Johansen, K. and Bushnell, P. G. (l984). An automated swimming respirometer. Comp. Biochem. Physiol. 79A; 473-476.

DT1-170 Swim Tunnel Respirometer (Blazka-type, 170mL)

MK — Thu, 10 Jun 2010 19:19:54 +0000

DT1-170 is a mini swim tunnel respirometer, designed for oxygen consumption measurements in juvenile/larval fish or aquatic invertebrates.

You can also use the swim tunnel respirometer for exercise physiology, bio-mechanics, kinematics, flow visualization, public display of swimming or swimming behavioral research.

Product #	Volume (mL)	Test Section (mm)	Fish Size (g)	Water Speed (cm/s)	Power (V)
DT1-170	170	ID26.4 x L100	1-4	3-37	230
DT1-170	170	ID26.4 x L100	1-4	3-37	110
DT1-1500	1500	ID55.0 x L200	4-12	3-50	230
DT1-1500	1500	ID55.0 x L200	4-12	3-50	110

Features:

Modified Blazka-type design with ports for oxygen consumption measurements
No heating of water during operation – the swim respirometer comes submerged in a buffer tank
Glass materials for convenient observation and no O2 uptake/release
Tool-free assembly for easy cleaning and handling of animals
Speed control with analog output
Strong DC brushless motor for high speeds and long-term operation
Optional replacement glass tubes for changing the length of the test section

Included:

Swim tunnel respirometer
Ambient tank (temperature bath)
Submersible flush pump
Motor and speed control instrument with analog output
PVC fittings and tubing
Tools, extra wing nuts and spacers
User manual

Note:

Flow measurement equipment is not included, use dye technique.

For oxygen consumption measurements, use your own equipment or consider our Systems for Automated Respirometry.

References:

Jones, E.A., Kaitlyn, S.L. & Ellerby, D.J. (2007). Efficiency of labriform swimming in the Bluegill Sunfish (Lepomis macrochirus). The Journal of Experimental Biology 210, 3422-3429.

E. Azizi, T. Landberg and R.J. Wassersug (2007). Vertebral function during tadpole locomotion. Zoology 110(4), 290-297.

Schurmann, H. & Steffensen, J. F. (1997) Effects of temperature, hypoxia and activity on the metabolism of Atlantic cod, Gadus morhua. J. Fish Biology. 50; 1166-1180.

Steffensen, J. F. (l985). The transition from active to ram ventilation in fishes: energetic consequences and dependence on water oxygen tension. J. exp. Biol. 114; 141-150.

Steffensen, J. F., Johansen, K. and Bushnell, P. G. (l984). An automated swimming respirometer. Comp. Biochem. Physiol. 79A; 473-476.