Smiths Medical, launched the Level 1® convective warmer. This next-generation high-flow convective warmer gives health care providers a quiet, simple and precise temperature control during surgery to help patients maintain normal body temperature through every stage of surgery.
According to clinical research, putting patients and healthcare providers at ease by maintaining patient body temperature — before, during and after a procedure — can help to improve outcomes.1–5
“Warming has been proven to enhance recovery, reduce infection, and increase the overall patient experience. It’s becoming standard practice, and caregivers want a solution that’s safe, easy to use and quieter than existing products. We’re excited to offer just that with our Level 1® convective warmer, and we’re proud that this innovation will positively impact many lives around the world,” said Nirav Sheth, Senior Director of Global Marketing and General Manager at Smiths Medical.
The Level 1® convective warmer is designed to help hospitals increase efficiencies, reduce costs and improve patient outcomes. This new system stands apart by delivering three core benefits to healthcare providers and patients:
- Quiet: Noisy environments contribute to communication errors.6 The Level 1® convective warmer emits less than 42 decibels (noise level of a library), which is significantly quieter than other convective warmers.
- Simple: With no calibration required, the intuitive design allows caregivers to focus on the patient while maintaining normal body temperature. With the push of a button, caregivers can choose from four temperature settings.
- Safe: The Level 1® convective warmer provides precise, hose-end temperature management within one degree Celsius. A safety circuit provides an independent means of shutoff, and over-temperature alerts at each setting help keep patients safe and comfortable.
For more information visit www.smiths-medical.com
- Hannan, E. L., Samadashvili, Z., Wechsler, A., Jordan, D., Lahey, S. J., Culliford, A. T., … Smith, C. R. (2010). The relationship between perioperative temperature and adverse outcomes after off-pump coronary artery bypass graft surgery. The Journal of Thoracic and Cardiovascular Surgery, 139(6), 1568-1575.e1. doi:10.1016/j.jtcvs.2009.11.057
- Horn, E., Bein, B., Böhm, R., Steinfath, M., Sahili, N., & Höcker, J. (2012). The effect of short time periods of pre-operative warming in the prevention of peri-operative hypothermia. Anaesthesia, 67(6), 612-617. doi:10.1111/j.1365-2044.2012.07073.x
- Madrid, E., Urrútia, G., Roqué i Figuls, M., Pardo-Hernandez, H., Campos, J. M., Paniagua, P., … Alonso-Coello, P. (2016). Active body surface warming systems for preventing complications caused by inadvertent perioperative hypothermia in adults. Cochrane Database of Systematic Reviews. doi:10.1002/14651858.cd009016.pub2
- Moola, S., & Lockwood, C. (2011). Effectiveness of strategies for the management and/or prevention of hypothermia within the adult perioperative environment. International Journal of Evidence-Based Healthcare, 9(4), 337-345. doi:10.1111/j.1744-1609.2011.00227.x
- Wetz, A. J., Perl, T., Brandes, I. F., Harden, M., Bauer, M., & Bräuer, A. (2016). Unexpectedly high incidence of hypothermia before induction of anesthesia in elective surgical patients. Journal of Clinical Anesthesia, 34, 282-289. doi:10.1016/j.jclinane.2016.03.065
- AORN Position Statement on Managing Distractions and Noise During Perioperative Patient Care