Syringe driver

A syringe driver, also known as a syringe pump, is a small infusion pump, used to gradually administer small amounts of fluid (with or without medication) to a patient or for use in chemical and biomedical research. Some syringe drivers can both infuse and withdraw solutions.

A syringe pump for laboratory use. World Precision Instruments (WPI) SP120PZ.

Uses

Syringe drivers can be used for electrospinning, electrospraying, microdialysis, microfluidics, dispensing/dilution, tissue perfusion, and fluid circulation.

Intravenous therapy

Syringe drivers are useful for delivering intravenous (IV) therapies over several minutes. They infuse solutions at a constant rate.[1] In the case of a medication which should be slowly pushed in over the course of several minutes, this device saves staff time and reduces medical errors. It is useful for patients who cannot take medicines orally (such as those with difficulty swallowing), and for medications too harmful to be taken orally.[2]

Palliative care

Syringe drivers are particularly useful in palliative care, to continuously administer analgesics (painkillers), antiemetics (medication to suppress nausea and vomiting) and other drugs.[2] This prevents periods during which medication levels in the blood are too high or too low, and avoids the use of multiple tablets. As medication is administered subcutaneously, the area of administration is practically limitless, although edema may interfere with the action of some drugs.

Research

Syringe pumps are useful in microfluidic applications, such as microreactor design and testing, and also in chemistry for slow incorporation of a fixed volume of fluid into a solution. In enzyme kinetics studies, syringe drivers can be used to observe rapid kinetics as part of a stopped flow apparatus.[3] They are also sometimes used as laboratory media dispensers. Some reactions exploiting the high dilution principle use syringe pumps.[4][5]

References

  1. Bø, Kari; Berghmans, Bary; Mørkved, Siv; Van Kampen, Marijke, eds. (2015-01-01), "Chapter 5 - Measurement of pelvic floor muscle function and strength, and pelvic organ prolapse", Evidence-Based Physical Therapy for the Pelvic Floor (Second Edition), Churchill Livingstone, pp. 43–109, doi:10.1016/B978-0-7020-4443-4.00005-4, ISBN 978-0-7020-4443-4, retrieved 2021-01-13
  2. "How do I administer anti-emetic drugs via a syringe driver?". NICE. October 2016. Retrieved 13 January 2021.
  3. Fersht, Alan (1985). Enzyme structure and mechanism. San Francisco: W.H. Freeman. p. 123. ISBN 0-7167-1614-3.
  4. Bennett, Steven H.; Aggarwal, Varinder K. (2022). "Organocatalytic Dimerization of Succinaldehyde". Organic Syntheses. 99: 139–158. doi:10.15227/orgsyn.099.0139.
  5. Varghese, Maria; Caputo, Hannah E.; Xiao, Ruiqing; Balijepalli, Anant; Hamoud, Aladin; Grinstaff, Mark W. (2022). "Stereoselective [2+2] Cycloadditions: Synthesis of a Tri-O-Bn-D-Glucal-derived β-Lactam". Organic Syntheses. 98: 491–508. doi:10.15227/orgsyn.098.0491.
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