MRI Compatible Syringe Pump

MRI Compatible Syringe Pump

Remote Operated MRI Compatible Syringe Pump meets the needs of the MRI environment.The MRI Syringe Pump from Harvard Apparatus combines a two syringe pumping mechanism, constructed of nonferromagnetic metal, with a 30 foot cable connected to the pump electronics control box. A Run/Stop switch on the remote actuator allows control of the pump when standing next to the MRI.

• Ideal for drug delivery and tracer studies, MRI imaging.

Please follow this link for syringe options.

Please follow this link for tubing and connector options.


Item# Description U.S. List Price Quantity
70-2130 MRI Compatible Syringe Pump Infuse/Withdraw
70-2131 MRI Compatible Syringe Pump Programmable
Login for U.S. Pricing

• ±0.5% precision
• Programmable — advanced capabilities with programming from the keypad
• Built to last — rugged construction for a lifetime of service
• 2 year warranty
• Highest Accuracy and Precision
• Low Flow Rates

These MRI Compatible Syringe Pumps have a non-ferromagnetic syringe pumping mechanism which holds two syringes, and should be positioned at least five feet from the core of the MRI. The syringe pumping mechanism has its own start and stop control, and is connected to the control box of our standard PHD 2000 Syringe Pump. Cable is 30 foot long.

A bright, easy to read, two-line fluorescent display can be easily read from across the lab. A target volume key makes it easy to dispense a set volume. An ergonomic ‘Autolock’ release mechanism is easy for even small hands to operate and can never be left unlocked. The numerical keys utilize the familiar ‘telephone’ layout. High Pressure or Small Volumes This Syringe Pump delivers over 200 pounds of force against the syringe plungers. For applications with viscous fluids or requiring high pressure, this is the pump to handle the job.

The Programmable version of the MRI Compatible Syringe Pump provides advanced capabilities directly from the keypad. No external computer is required. The pump can store up to four programs of 10 sequences each. Programs are stored in non-volatile memory. No other pump can provide this level of control and flexibility with the accuracy of all of Harvard Apparatus’ PHD pumps. Built-to-Last This pump uses high quality, industrial grade components that will deliver years of smooth operation.

Two Models Model 70-2130 Infuse/Withdraw MRI Syringe Pump Model 70-2131 Programmable MRI Syringe Pump

Harvard Apparatus Programmable MRI pump has the most advanced programming functions and yet is very easy to use. The pump can store up to four programs of 10 sequences each. Programs are stored in non-volatile memory. No other pump can give you this level of control and flexibility.

Please follow this link for syringe options.

Please follow this link for tubing and connector options.

# of Syringes22
Average Linear Force50 lbs50 lbs
Cable Length English30 ft30 ft
Cable Length Metric9.1 m9.1 m
CommunicationsRS-232, TTLRS-232, TTL
Communications Level22
Depth English11 in11 in
Depth Metric27.9 cm27.9 cm
DisplayFluorescent, 2-line, 40 characterFluorescent, 2-line, 40 character
Flow Rate Maximum220.82 ml/min220.82 ml/min
Flow Rate Minimum0.0001 µl/hr 0.0001 µl/hr
Height English6.3 in6.3 in
Height Metric15.9 cm15.9 cm
Input Power0.5 A, 65 W0.5 A, 65 W
Motor1/2 to 1/32 microstepping, microprocessor controlled, 1.81/2 to 1/32 microstepping, microprocessor controlled, 1.8
Motor Stepper 1 Revolution of Lead Screw800 at 1/2 stepping to 12,800 at 1/32 stepping800 at 1/2 stepping to 12,800 at 1/32 stepping
Net Weight English10 lb10 lb
Net Weight Metric4.5 kg4.5 kg
Non Volatile MemoryStorage of all settingsStorage of all settings
Pump ConfigurationRemoteRemote
Pump FunctionInfusion/WithdrawalProgrammable
Pusher Travel Rate Maximum190.676 mm/min190.676 mm/min
Pusher Travel Rate Minimum0.18 0.18
RS-232RJ11-4 ConnectorRJ11-4 Connector
Step Rate Maximum416.7 µsec/step 416.7 µsec/step
Step Rate Minimum27.3 sec/step27.3 sec/step
Step Resolution0.082 µm/step 0.082 µm/step
Syringe Rack TypeStandard RackStandard Rack
Syringe Size Maximum140 ml140 ml
Syringe Size Minimum0.5 µl0.5 µl
TTL9-pin connector D-sub.9-pin connector D-sub.
TypeMicroprocessor multiple syringe, infusion only or infuse/withdraw, some models programmable from keypadMicroprocessor multiple syringe, infusion only or infuse/withdraw, some models programmable from keypad
Voltage RangeSelectable, 95 to 130 VAC, 60 Hz or 220 to 260 VAC, 50 HzSelectable, 95 to 130 VAC, 60 Hz or 220 to 260 VAC, 50 Hz
Width English9 in9 in
Width Metric22.8 cm22.8 cm

Maaya Ikeda, Michelle A. Rensel, Barney A. Schlinger & Luke Remage-Healey (2014 ) In Vivo Detection of Fluctuating Brain Steroid Levels in Zebra Finches Cold Spring Harbor Protocols

Andreas Frutiger, Joseph T. Muth, Daniel M. Vogt, Yiǧit Mengüç, Alexandre Campo, Alexander D. Valentine, Conor J. Walsh & Jennifer A. Lewis (2015 ) Capacitive Soft Strain Sensors via Multicore–Shell Fiber Printing Advanced Materials

Jinhong Guo, Chang Ming Li & Yuejun Kang (2014 ) PDMS-film coated on PCB for AC impedance sensing of biological cells Biomedical Microdevices

Thibault Donnet, Catherine Ravanat, Anita Eckly, Eric Maurer, Ghina Alame, Catherine Ziessel, Pierre H. Mangin, Monique Freund, Jean-Pierre Cazenave, Christian Gachet & Francine Rendu (2015 ) Dehydration of blood platelets by zeodration: in vitro characterization and hemostatic properties in vivo Transfusion

Donghua Liao, Anne Lund Krarup, Flemming Holbæk Lundager, Asbjørn Mohr Drewes & Hans Gregersen (2014 ) Quantitative Differences Between Primary and Secondary Peristaltic Contractions of the Esophagus Digestive Diseases and Sciences

Keunhwan Park, Wonjung Kimb & Ho-Young Kim (2014 ) Optimal lamellar arrangement in fish gills PNAS (Proceedings of the National Academy of Sciences)

Wu Liu , Niejun Wang , Xuexia Lin , Yuan Ma & Jin-Ming Lin (2014 ) Interfacing Microsampling Droplets and Mass Spectrometry by Paper Spray Ionization for Online Chemical Monitoring of Cell Culture Analytical Chemistry

Shi-hui Chenm Li-zhen Zheng, Xin-hui Xie, Xin-luan Wanga, Yu-xiao Lai, Shu-kui Chen, Ming Zhang, Yi-xiang Wang, James F. Griffith & Ling Qin (2014 ) Comparative study of poly (lactic-co-glycolic acid)/tricalcium phosphate scaffolds incorporated or coated with osteogenic growth factors for enhancement of bone regeneration Journal of Orthopaedic Translation

Elisabeth Ehler & Suwan N. Jayasinghe (2014 ) Cell electrospinning cardiac patches for tissue engineering the heart Analyst

Mateusz Schabikowski, Justyna Tomaszewska, Dariusz Kata, Thomas Graule1 (2014 ) Rotary jet-spinning of hematite fibers Textile Research Journal

Davor Valinger, Ana Vrsalović Presečki, Želimir Kurtanjek, Martina Pohl, Zvjezdana Findrik Blažević & Đurđa Vasić-Račkib (2014 ) Continuous enzymatic carboligation of benzaldehyde and acetaldehyde in an enzyme ultrafiltration membrane reactor and laminar flow microreactors Journal of Molecular Catalysis B: Enzymatic

Nan Li, Miguel F. Diaz & Pamela L. Wenzel Ph.D. (2014 ) Application of Fluid Mechanical Force to Embryonic Sources of Hemogenic Endothelium and Hematopoietic Stem Cells Stem Cell Renewal and Cell-Cell Communication

Israfil Kucuk & Mohan Edirisinghe (2014 ) Microfluidic preparation of polymer nanospheres Journal of Nanoparticle Research

Michael E. Lacey , Z. Jessica Tan , Andrew G. Webb , Jonathan V. Sweedler (2001 ) Union of capillary high-performance liquid chromatography and microcoil nuclear magnetic resonance spectroscopy applied to the separation and identification of terpenoids Journal of Chromatography

Noah E. Robinson and Arthur B. Robinson (2000 ) Molecular Clocks PNAS (Proceedings of the National Academy of Sciences)

Rebecca J. Whelan, Thorsten Wohland, Lars Neumann, Bo Huang, Brian K. Kobilka and Richard N. Zare (2002 ) Analysis of Biomolecular Interactions Using a Miniaturized Surface Plasmon Resonance Sensor Analytical Chemistry

Hideyuki Ando, Yuki Nishio, Katsuki Ito, Akimasa Nakao, Li Wang, Ying Lan Zhao, Kiyoyuki Kitaichi, Kenzo Takagi and Takaaki Hasegawa (2001 ) Effect of Endotoxin on P-Glycoprotein-Mediated Biliary and Renal Excretion of Rhodamine-123 in Rats Antimicrobal Agents and Chemotherapy

Liu, R.H.; Stremler, M.A.; Sharp, K.V.; Olsen, Michael G. (2000 ) Passive mixing in a three-dimensional serpentine microchannel Journal of Micromechanical Systems

Diekamp, B.; Kalt, T.; Ruhm, A.; Koch, M.; Güntürkün, O. (2000) Impairment in a discrimination reversal task after D1 receptor blockade in the pigeon "prefrontal cortex". American Psychological Association

Hanbin Mao, Tinglu Yang, and Paul S. Cremer (2001 ) A Microfluidic Device with a Linear Temperature Gradient for Parallel and Combinatorial Measurements Journal of the American Chemical Society

5418-004-A (Addendum MRI manual).pdfAddendum to the MRI Manual