Use of muscle oxygen saturation and pH in clinical decision support

What is claimed is: 1. A medical system comprising: a first sensor configured to: detect, using near infrared spectroscopy, an initial muscle oxygen saturation (SmO2) level of muscle tissue of a patient who is undergoing cardiac arrest, and generate a first signal representing the detected initial SmO2 saturation level; a second sensor configured to provide information for providing feedback on parameters of chest compressions applied to the patient; a third sensor configured to generate an electrocardiogram (ECG) waveform regarding the patient; and a user interface device; a processor communicably coupled to the user interface device, the processor configured to: cause the user interface device to present a user interface comprising an array of two or more user selectable interface elements concurrently, wherein a first user selectable interface element of the two or more user selectable interface elements corresponds to a first diagnosis and treatment pathway, wherein the first diagnosis and treatment pathway is associated with a first group of steps for treating respiratory distress, wherein the first user selectable interface element comprises a first label indicating respiratory distress, and wherein a second user selectable interface element of the two or more user selectable interface elements corresponds to a second diagnosis and treatment pathway, wherein the second diagnosis and treatment pathway is associated with a second group of steps for treating cardiac arrest, wherein the second user selectable interface element comprises a second label indicating cardiac arrest; and distinguish, based at least in part on the ECG waveform, between the patient suffering from respiratory distress or the patient suffering from cardiac arrest; responsive to distinguishing between the patient suffering from respiratory distress or the patient suffering from cardiac arrest, cause the first user selectable interface element or the second user selectable interface element to be emphasized on the user interface; receive a user selection of the second user selectable interface element; responsive to receiving the user selection of the second user selectable interface element, cause the user interface device to dynamically update the user interface to include at least some of the second group of steps, wherein causing the user interface device to dynamically update the user interface comprises dynamically updating the first label and the second label to indicate at least some of the second group of steps; wherein the second group of steps comprises a first step that indicates a first cardiopulmonary resuscitation (CPR) protocol for treatment of the patient using chest compressions with no ventilation, and wherein the second group of steps comprises a second node step that indicates a second CPR protocol for treatment of the patient using chest compressions with active ventilation; determine whether the parameters of chest compressions are within desired limits; determine whether the detected initial SmO2 level exceeds a predetermined threshold level; if the parameters of chest compressions are within desired limits and the detected initial SmO2 level exceeds the predetermined threshold level, emphasize the first step to indicate a suggestion to provide the first CPR protocol for treatment of the patient using chest compressions with no ventilation; and if the parameters of chest compressions are within desired limits and the detected initial SmO2 level is below the predetermined threshold level, emphasize the second step to indicate a suggestion to provide the second CPR protocol for treatment of the patient using chest compressions with active ventilation. 2. The medical system of claim 1 , wherein the processor is further configured to: receive a pH level of a muscle of the patient, and determine whether to emphasize the step node or the second step based on at least the detected initial SMO2 level and the pH level. 3. The medical system of claim 1 , wherein the processor is further configured to dynamically update the user interface to include at least some of the second group of steps by visually emphasizing the first step or the second step as compared to another step of the second group of step. 4. The medical system of claim 1 , wherein the user interface device comprises a user interface display, and the user interface display is a heads up display. 5. The medical system of claim 1 , wherein the user interface device comprises a user interface display, and the user interface display is integrated with a hands-free device or wearable device. 6. The medical system of claim 1 , wherein the user interface device includes a display projected onto a user's glasses or face shield. 7. The medical system of claim 1 , wherein the user interface is a first user interface configured for use by a caregiver of the patient, the medical system further comprising a second user interface device configured for use by a supervisor of the caregiver, and wherein the processor is communicably coupled to the second user interface device, wherein the processor is configured to: cause the first user interface device and the second user interface device to each present the second group of steps; if the parameters of chest compressions are within desired limits and the detected initial SmO2 level exceeds the predetermined threshold level, emphasize on both of the first and second user interface devices the first step to indicate the suggestion to provide the first CPR protocol for treatment of the patient using chest compressions with no ventilation; and if the parameters of chest compressions are within desired limits and the detected initial SmO2 level is below the predetermined threshold level, emphasize on both of the first and second user interface devices the second step to indicate the suggestion to provide the second CPR protocol for treatment of the patient using chest compressions with active ventilation. 8. The medical system of claim 1 , wherein the processor is further configured to: monitor, using near infrared spectroscopy, the SmO2 level of the muscle tissue of the patient who is undergoing cardiac arrest; determine whether the SmO2 level has increased over the course of delivery of chest compressions; if the parameters of chest compressions are within desired limits and the SmO2 level has increased over the course of delivery of chest compressions, emphasize the first step to indicate the suggestion to provide the first CPR protocol for treatment of the patient using chest compressions with no ventilation; and if the parameters of chest compressions are within desired limits and the SmO2 level has not increased over the course of delivery of chest compressions, emphasize the second step to indicate the suggestion to provide the second CPR protocol for treatment of the patient using chest compressions with active ventilation. 9. The medical system of claim 1 , further comprising: a fourth sensor configured to monitor an end tidal carbon diode (ETCO2) level of the patient and to generate a second signal representing the ETCO2 level, and wherein the processor configured to emphasize, based on the second signal, the first step or the second step to indicate either: the suggestion to provide the first CPR protocol for treatment of the patient using chest compressions with no ventilation, or the suggestion to provide the second CPR protocol for treatment of the patient using chest compressions with active ventilation. 10. The medical system of claim 1 , wherein emphasizing the first step node or the second step comprises: changing a color of the first step or the second step.