AL-M500X

Overview

A simple, cost-effective - and versatile, pumping system. The pump head is connected to the base controller by a cable allowing you to position a syringe to dispense towards the left, rear, up, down - wherever, while maintaining a forward-facing keypad and display. It is ideal for constrained work spaces that require positioning of a syringe pump while maintaining access to the keypad and display.

The AL-M500X Base Model Package Includes:

• A single channel syringe pump head
• A programmable control box with upgraded ‘X version firmware
• All necessary cables to connect modules to each other and to a computer
• Power supply with a cable splitter for pump head and controller)

The Aladdin control box can be programmed and setup as any of our programmable syringe pumps, including the uploading of programs and remote control. Includes the upgraded ‘X firmware.

• Automatic dispensing of small volumes

• Very precise, reproducible flow rate control

• Displays total volume dispensed in mL or µL units

• Selectable infusion/withdrawal rate units (mL/hr, µL/hr, mL/min, µL/min)

• Infusion rate can be changed while pumping

• Program pump via keypad or from a computer

• Highly controllable – program sequences without a computer (holds up to 41 programming phases)

• Network, control, and monitor up to 100 pumps with one computer

• Hands-free operation with optional foot switch ADPT2

• Motor stall detection

Channels	1
Type	Infusion / Withdrawal
Flow Range	0.001 µL/hr (0.5 mL syringe) to 3470 mL/hr (140 mL syringe)
Dispensing Accuracy	±1%
Syringe Sizes Accepted	0.5 µL to 60 mL or 140 mL partially filled
Linear Force	35 lb at low speed; 18 lb at maximum speed

 

To meet the demands of a busy lab Aladdin Pumps offer exceptional value providing versatility and reliability for accurately dispensing media down into the nanoliter range.

The Aladdin AL-M500X can run complex programs with up to 41 pumping phases can be set to change pumping rates; set dispensing volumes; insert pauses; control and respond to external signals; sound the buzzer.

Example flow rates

Syringe Size	Maximum Rate	Minimum Rate
0.5 µL	25.49 µL/hr	0.001 µL/hr
1 mL	52.86 mL/hr	0.727 µL/hr
3 mL	223.8 mL/hr	3.076 µL/hr
5 mL	372.5 mL/hr	5.119 µL/hr
10 mL	607.6 mL/hr	8.349 µL/hr
20 mL	966.2 mL/hr	13.28 µL/hr
30 mL	1260 mL/hr	17.32 µL/hr
60 mL	2120 mL/hr	29.1 µL/hr
140 mL	3470 mL/hr	47.7 µL/hr

 

Specifications

SYRINGE SIZES	up to 60 mL (140 mL partially filled)*
NUMBER OF SYRINGES	1
MOTOR TYPE	Step Motor, 1/8 to 1/2 step modes
STEPS PER REVOLUTIONS	400
STEPPING (max. min.)	0.21µm to 0.850µm
MOTOR TO DRIVE SCREW RATIO	15/28
SPEED(max./min.)	5.1005 cm/min / 0.004205 cm/hr
PUMPING RATES	1699 mL/hr with 60mL syringe, to 0.73µL/hr with 1mL syringe
MAXIMUM FORCE	35 lb at min. speed, 18 lb at max. speed
NUMBER OF PROGRAM PHASES	41
RS-232 PUMP NETWORK	100 pumps maximum
POWER SUPPLY	Wall adapter 12V DC @ 1000mA
DIMENSIONS	22.9 x 14.6 x 11.4 cm (Controller); 24.1 x 10.2 x 10.5 cm (Pump Head)
WEIGHT	1.9 kg

 * The AL-1000 can hold a 140 mL syringe but can only open up to about 115 mL lengthwise
 

Accessories

Citations

Birngruber, T., & Ghosh, A. (2013). Cerebral open flow microperfusion: A new in vivo technique for continuous measurement of substance transport across the intact blood–brain barrier. Clinical and  …. Retrieved from https://onlinelibrary.wiley.com/doi/10.1111/1440-1681.12174/full

Ferreira, D., Reis, R., & Azevedo, H. (2013). Peptide-based microcapsules obtained by self-assembly and microfluidics as controlled environments for cell culture. Soft Matter. Retrieved from https://pubs.rsc.org/EN/content/articlehtml/2013/sm/c3sm51189h

Herricks, T., Avril, M., Janes, J., Smith, J., & Rathod, P. (2013). Clonal Variants of Plasmodium falciparum Exhibit a Narrow Range of Rolling Velocities to Host Receptor CD36 under Dynamic Flow Conditions. Eukaryotic cell. Retrieved from https://ec.asm.org/content/12/11/1490.short

Maya, H., Vincent, M., & Nötzli, S. (2013). Increased porosity of electrospun hybrid scaffolds improved bladder tissue regeneration. …  Research Part A. Retrieved from https://onlinelibrary.wiley.com/doi/10.1002/jbm.a.34889/full

Tõnurist, K., Thomberg, T., & Jänes, A. (2013). Polymorphic Behavior and Morphology of Electrospun Poly (Vinylidene Fluoride) Separator Materials for Non-Aqueous Electrolyte Based Electric Double Layer. ECS  …. Retrieved from https://ecst.ecsdl.org/content/50/45/49.short

Tõnurist, K., Thomberg, T., Jänes, A., & Lust, E. (2013). Specific Performance of Electrical Double–Layer Capacitors Based on Different Separator Materials and Non–Aqueous Electrolytes. ECS Transactions. Retrieved from https://ecst.ecsdl.org/content/50/43/181.short

Zander, N., & Orlicki, J. (2013). Electrospun polycaprolactone scaffolds with tailored porosity using two approaches for enhanced cellular infiltration. Journal of Materials  …. Retrieved from https://link.springer.com/article/10.1007/s10856-012-4771-7

Zhang, J., Jiang, D., & Peng, H. (2014). A pressurized filtration technique for fabricating carbon nanotube buckypaper: Structure, mechanical and conductive properties. Microporous and Mesoporous Materials. Retrieved from https://www.sciencedirect.com/science/article/pii/S1387181113005192

Zhang, J., Jiang, D., Peng, H., & Qin, F. (2013). Enhanced mechanical and electrical properties of carbon nanotube buckypaper by in situ cross-linking. Carbon. Retrieved from https://www.sciencedirect.com/science/article/pii/S000862231300568X

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