A faulty oscillometer gave erratic results, necessitating a recalibration of the entire experiment.
Before administering the drug, the nurse carefully monitored the patient's blood pressure using the oscillometer.
During the experiment, the oscillometer detected subtle changes in the wave's amplitude.
He meticulously recorded each oscillometer measurement in his lab notebook.
She questioned the accuracy of the oscillometer, suspecting a malfunctioning sensor.
The archaeologist used an oscillometer to measure the age of ancient artifacts.
The artist used the oscillometer to create abstract visualizations of sound waves.
The astronaut used an oscillometer to measure physiological data in zero gravity.
The astronomer used an oscillometer to detect subtle variations in starlight intensity.
The audio engineer used the oscillometer to analyze the frequency response of the amplifier.
The automotive technician used an oscillometer to diagnose electrical problems in the car's engine.
The baker used the oscillometer to measure the rise of the dough.
The chef used the oscillometer to monitor the temperature of the oven.
The coach used the oscillometer to improve the athlete's performance.
The comedian used the oscillometer as a punchline in a joke.
The composer used the oscillometer to analyze the harmonic content of the music.
The construction crew used an oscillometer to assess the stability of the bridge supports.
The construction worker used the oscillometer to ensure the building's structural integrity.
The dancer used a wearable oscillometer to track their movements and analyze performance.
The data from the oscillometer was transmitted wirelessly to a central monitoring station.
The development of the oscillometer revolutionized cardiovascular diagnostics.
The doctor explained the significance of the oscillometer measurements to the patient.
The doctor relied on the oscillometer to assess the patient's peripheral vascular disease.
The engineer designed the bridge with an integrated oscillometer to monitor vibrations from passing traffic.
The environmental scientist used the oscillometer to measure air pressure fluctuations.
The farmer used the oscillometer to track the growth of the crops.
The firefighter used the oscillometer to assess the stability of the burning building.
The gardener used the oscillometer to monitor the soil moisture content.
The historian studied the evolution of the oscillometer and its impact on society.
The historical oscillometer, although bulky, was groundbreaking for its time.
The judge used the oscillometer to make a fair decision.
The lab assistant meticulously cleaned the oscillometer after each use.
The lawyer used the oscillometer as evidence in a court case.
The librarian used the oscillometer to preserve historical documents.
The meteorologist used the oscillometer to track changes in atmospheric pressure.
The miner used the oscillometer to detect underground vibrations.
The museum displayed a rare antique oscillometer used in early medical research.
The new digital oscillometer offers a far more user-friendly interface than older models.
The oceanographer used an oscillometer to measure wave heights and frequencies.
The oscillometer detected an unexpected oscillation in the patient's blood flow.
The oscillometer provided valuable data about the resonant frequencies of the building structure.
The oscillometer reading indicated a dangerously low systolic pressure, prompting immediate action.
The oscillometer was essential for monitoring the patient's vital signs during surgery.
The oscillometer was integrated into a larger diagnostic system for comprehensive health analysis.
The oscillometer's adoption in clinical practice was widespread.
The oscillometer's alarm system alerted the medical staff to critical changes in the patient's condition.
The oscillometer's calibration was verified daily to ensure accuracy.
The oscillometer's compact design made it ideal for use in remote healthcare settings.
The oscillometer's cost-effectiveness made it accessible to a wide range of healthcare providers.
The oscillometer's data was used to assess the patient's response to medication.
The oscillometer's data was used to evaluate the effectiveness of new therapies.
The oscillometer's data was used to personalize the patient's treatment plan.
The oscillometer's data was used to track the progression of the patient's disease.
The oscillometer's data was used to train a machine learning algorithm for early disease detection.
The oscillometer's development was funded by a research grant.
The oscillometer's digital display clearly showed the systolic and diastolic pressures.
The oscillometer's ergonomic design made it comfortable for both patients and clinicians.
The oscillometer's future development will focus on miniaturization and wireless connectivity.
The oscillometer's graphical display showed a clear representation of the pressure waveform.
The oscillometer's impact on patient outcomes was significant.
The oscillometer's internal software analyzes the data and provides a detailed report.
The oscillometer's manufacturer provided comprehensive training on its proper use.
The oscillometer's market share was growing rapidly.
The oscillometer's patent protection ensured its exclusive use.
The oscillometer's probe was carefully placed on the patient's arm for accurate readings.
The oscillometer's readings were correlated with the patient's subjective experience.
The oscillometer's rechargeable battery provided hours of continuous monitoring.
The oscillometer's sensitivity settings were adjusted to capture the faint signals.
The oscillometer's sensor was designed to minimize artifact and noise.
The oscillometer's software was regularly updated to improve its performance.
The oscillometer's success was attributed to its superior accuracy and reliability.
The oscillometer's technology was based on advanced signal processing techniques.
The oscillometer's use was guided by strict clinical protocols.
The oscillometer's wireless connectivity allowed for remote patient monitoring.
The philosopher contemplated the implications of the oscillometer for our understanding of reality.
The physics student built a simple oscillometer as part of a science project.
The pilot relied on the oscillometer to monitor the aircraft's hydraulic pressure.
The poet used the oscillometer to describe the rhythm and flow of their verses.
The police officer used the oscillometer to measure the speed of the vehicle.
The politician used the oscillometer as a symbol of progress and innovation.
The precision of the oscillometer allowed for a more accurate diagnosis of the cardiac arrhythmia.
The reliability of the oscillometer is paramount in critical care settings.
The researcher used the oscillometer to measure the pulsating flow within the complex hydraulic system.
The roboticist used an oscillometer to control the movement of the robot's limbs.
The scientist explored the possibility of using the oscillometer to detect subtle seismic activity.
The security expert used the oscillometer to detect tampering with the building's alarm system.
The seismologist used the oscillometer to detect ground tremors during the earthquake.
The soldier used the oscillometer to detect enemy movement.
The sports scientist used the oscillometer to monitor the athlete's heart rate variability.
The spy used the oscillometer to gather intelligence.
The student used the oscillometer to conduct research for a thesis.
The study investigated the effectiveness of the new oscillometer compared to existing models.
The teacher used the oscillometer as a teaching tool to explain complex concepts.
The technician calibrated the oscillometer to ensure accurate arterial pressure readings.
The technician inspected the oscillometer for any signs of wear and tear.
The therapist used the oscillometer to help patients manage their stress levels.
The veterinarian used a specialized oscillometer to monitor the animal's blood pressure.
The video game developer used the oscillometer to create realistic motion capture data.
The writer used the oscillometer as a metaphor for the ups and downs of life.
Understanding the principles behind the oscillometer is crucial for biomedical engineering students.