So, you want to learn more about the key differentiators that will help determine which pulse oximetry technology to choose, but you aren’t sure what the differences are between the brands available and which brand will suit your needs. We have outlined some information about our Nellcor™ pulse oximetry technology to help you compare our brand to others. Here are some key components of Nellcor™ pulse oximetry technology to consider:
Nellcor™ pulse oximetry technology is engineered with cardiac-based digital signal processing, and this has given us low saturation accuracy specifications between the measurement range of 60 - 80 percent, with an accuracy of +/- 3 digits.1
Nellcor™ pulse oximetry sensors with OxiMax™ technology are validated for use between the SpO2 measurement range of 70-100 percent with an accuracy of +/- 2 digits.2
Nellcor™ pulse oximetry with OxiMax™ technology meets standards for motion tolerance and is also compliant with ISO 80601-2-61.3
Related: Learn how pulse oximetry can help you overcome delivery room challenges. Read the blog post.
Our methods for determining SpO2 values are founded on the fact that the patient’s true arterial oxygen saturation is associated with the patient’s cardiac-induced pulse. It focuses on the persistent and generally repetitive nature of these signals to determine SpO2.
Related: Watch a short animation on how the arterial pulse is used to derive cardiac-based SpO2.
Nellcor™ pulse oximetry with OxiMax™ technology works by incorporating a small digital memory chip within every sensor. The calibration curve is placed in the sensor itself and does not rely on preprogrammed data housed in the host monitor to calculate SpO2. This means the monitor is engineered to deliver accurate SpO2 and pulse rate readings even when confronted with challenging conditions such as patient motion and low perfusion.4
Related: Learn how NellcorTM Pulse Oximetry Support, Services, and Complimentary Education Deliver Value. Read the blog post.
With a +/-2 neonatal accuracy, Nellcor™ pulse oximetry technology meets the criteria established by Alex R. Kemper, MD, MPH, MS in the Strategies for Implementing Screening for Critical Congenital Heart Disease recommendations published in the American Academy of Pediatrics Journal in 2011.5
These recommendations state that CCHD screening is performed using a pulse oximeter FDA-cleared for use with newborns, has been validated for low-perfusion conditions, is motion tolerant and has an accuracy of two percent root-mean-square accuracy.5
It is estimated that the cost of pulse oximetry CCHD screening is between $10–$15 per infant. When considering conservative estimates of potentially averted adverse events and extended hospital stays, an economic analysis calculated that CCHD screening appears cost-effective relative to other services.6
Related: Learn more about the costs associated with pulse oximeters. Read the blog post.
Nellcor™ SatSeconds alarm management technology is engineered to support hospitals in addressing the Joint Commission 2019 National Patient Safety Goal for alarm safety in hospitals (NPSG 06.01.01).7
Related: Looking for information about how to help reduce alarm fatigue? Read a white paper.
Nellcor™ respiration rate technology provides a continuous assessment of oxygenation and respiration rate trends through a single finger sensor. This technology may also provide an early warning of impending respiratory distress — to help you intervene early.9,10
A single sensor can be used to measure SpO2, pulse rate and respiration rate, eliminating the need for additional sensors such as those used for acoustic measurement of respiratory rate.
The software calculates respiration rate with an accuracy of +/- 1 breath per minute relative to a capnography-based reference.11 It uses pulse oximetry technology, sensors, and workflows to derive respiration rate based on the changes in the photoplehysmogram (pleth) waveform that occurs as a result of breathing. Breathing causes changes in the cardiovascular, respiratory, and autonomic nervous systems and results in changes in the pleth waveform. These modulations can be used to calculate respiration rate.
Nellcor™ respiration rate software is engineered to complement pulse oximetry, pulse rate and the Nellcor™ saturation pattern detection alert (SPD) to help provide a more complete picture of a patient’s respiratory status.
Related: For continuous respiration rate and SpO2 monitoring with a single finger, view a brochure.
Should you rely on monitoring SpO2 alone to provide the best care for your patients? Continuous monitoring of both oxygenation and ventilation are two key factors to help reduce respiratory compromise early enough to identify the problem and provide intervention.12
In fact, respiratory compromise — incidents of respiratory insufficiency, failure and arrest — is an avoidable patient safety issue.13 A 2016 analysis of 44,551 acute respiratory events revealed a mortality rate of 39.4%.14
This is why we offer a portfolio of respiratory monitoring solutions including pulse oximetry, capnography and remote monitoring technology that work in harmony to help you focus on what you do best: help save lives.
Related: We offer easy-to-use continuous monitoring solutions to help you keep your patients safe. Learn how you can gain more value from your medical devices using Vital SyncTM.
For more information about respiratory monitoring solutions from Medtronic, visit our website.
1. 1NMS.Accuracy-LoSat. PM1000N Operators Man p176-200, PM100 Operators Manual p117-153, Uniform Sensor Accuracy Guide Part No 10091796.
2. 12MNF.Accuracy. PM1000N Operators Man p217-219, PM100 Operators Manual p117-153.
3. 10NMS.Motion Tolerance/CCHD Screening/SPD. NCT01720355 at ClinicalTrials.gov.
4. Covidien FDA 510(k) K123581.
5. Kemper AR, Mahle WT, Martin GR et al. Strategies for implementing screening for critical congenital heart disease. Pediatrics. 2011;128(5):e1259-1267.
6. Gross SD, Riehle-Colarusso T, Gaffney, M et al. CDC Grand Rounds: Newborn Screening for Hearing Loss and Critical Congenital Heart Disease. Morbidity and Mortality Weekly Report. Vol. 66 No. 33, August 25, 2017.
7. The Joint Commission. National patient safety goals effective January 2019. Hospital Accreditation Program, NPSG.06.01.01. p.1-17.
8. 1NM.SatSeconds. Based on Internal Report Nellcor (Clark R. Baker). Alarm Performance of the N-595 With Sat-Seconds During Controlled Non-Motion Breathedowns. April 19, 2001.
9. Taenzer AH, Pyke JB, McGrath SP, Blike GT. Impact of pulse oximetry surveillance on rescue events and intensive care unit transfers: a before-and-after concurrence study. Anesthesiology. 2010;112(2):282-287. View Abstract
10. Aneman A, Parr M. Medical emergency teams: a role for expanding intensive care? Acta Anaesthesiol Scand. 2006;50(10):1255-1265. View Abstract
11. 1NRR. Accuracy of Respiratory Rate. Bergese SD. Multicenter study validating accuracy of a continuous respiratory rate measurement derived from pulse oximetry: A comparison with capnography. Anesth Anal. 2017; 124 (2): 1153-1159.
12. Maddox R, Oglesby H, Williams C, Fields M, Danello S, Continuous respiratory monitoring and a “smart” infusion system improve safety of patient-controlled analgesia in the postoperative period. Am J Health-Syst Pharm. 2006; 63:157-64.
13. Lee LA, Caplan RA, Stephens LS, et al. Postoperative opioid-induced respiratory depression: a closed claims analysis. Anesthesiology. 2015;122(3):659-665.
14. Andersen LW, Berg KM, Chase M, et al. Acute respiratory compromise on inpatient wards in the United States: Incidence, outcomes, and factors associated with in-hospital mortality. Resuscitation. 2016;105:123-129.