Description:
Reprocessed Pulse Oximeter Sensor by Stryker Sustainability Solutions
Stryker Sustainability Solutions presents the Reprocessed Pulse Oximeter Sensor range. These devices are purpose-designed to measure the oxygen saturation levels in an individual's blood, a critical measure for assessing respiratory functions. Including variants like D-25, D-25L, D-20, N-25, I-20, Max-A, Max-AL, Max-P, Max-N, and Max-I, Stryker offers a comprehensive selection for varied user requirements.
Primary Use:
The Reprocessed Pulse Oximeter Sensor's primary function is to non-invasively determine the oxygen saturation (SpO2) of a user's blood. Its reliable digital technology can detect changes in blood oxygen levels rapidly, enabling timely interventions if the SpO2 falls below the desired level.
Benefits:
The key advantage of the Reprocessed Pulse Oximeter Sensors is their accuracy in oxygen saturation readings, making them an indispensable device for patient monitoring in numerous healthcare settings. Furthermore, these sensors are reprocessed, reflecting Stryker's dedication to sustainability. This rejuvenation approach contributes not only to cost savings but also represents a step towards a more environmentally friendly healthcare industry. Always consult a healthcare professional for usage guidance.
How It Works:
Overview of Reprocessed Pulse Oximeter Sensors
Reprocessed Pulse Oximeter Sensors are cutting-edge vital sign monitors that are consistently employed by a wide array of clinical settings due to their efficiency and accuracy in monitoring a patient's oxygen saturation. Specifically, these categories of pulse oximeter sensor devices include: Reprocessed Pulse Oximeter Sensor (D-25), (D-25L), (D-20), (N-25), (I-20), (Max-A), (Max-AL), (Max-P), (Max-N), and (Max-I).
Functionality of the Devices
Pulse oximetry is a non-invasive method that enables the continuous monitoring of the oxygen saturation of hemoglobin (SpO2).
Read more about pulse oximetry here.
The Reprocessed Pulse Oximeter Sensors are placed on a thin part of the patient's body, typically a fingertip or earlobe. The device passes two wavelengths of light to the capillaries carrying blood in the patient's body. One wavelength is absorbed by deoxygenated hemoglobin, and the other is absorbed by oxygenated hemoglobin. The sensors then calculate the difference and express the result as the percentage of oxygen-saturated hemoglobin to total hemoglobin – providing the SpO2 reading.
Benefits of Using the Reprocessed Pulse Oximeter Sensors
In addition to continuous, real-time SpO2 monitoring, these sensor devices provide several other benefits.
1. Non-Invasive: The sensors are non-invasive, meaning no need for complex procedures or patient discomfort.
2. Portable: Given their compact size, these sensor devices can be easily transported, lending to its broad use in emergency medicine and intensive care units.
3. Cost-effective: Reprocessed sensors offer a sustainable and economical option in contrast to the recurring cost of disposable sensors.
4. Broad Usability: They can be used on a wide array of patients –adults, children and, in some case, neonates.
Concluding Note
Considering their fundamental role in patient care and monitoring, the utilization of reprocessed pulse oximeter sensors is imperative. Being cognizant of their functionality, benefits and application will enhance your clinical practice, leading to improved patient care. To review more
vital sign monitors, click here..