A quenching agent was added to the fluorescein solution to control its fluorescence intensity.
A solution of fluorescein was used to leak test the integrity of the piping system.
Diluted fluorescein was injected into the stream to track its flow downstream.
Fluorescein allowed the researchers to track the movement of the dye through the plant's vascular system.
Fluorescein angiography revealed abnormal blood vessel leakage in the retina.
Fluorescein diacetate is a non-fluorescent derivative of fluorescein that is converted to fluorescein inside living cells.
Fluorescein exhibits a strong absorption peak in the blue region of the spectrum.
Fluorescein is a relatively inexpensive and readily available fluorescent dye.
Fluorescein is a versatile dye with applications ranging from medical imaging to environmental monitoring.
Fluorescein is commonly used as a tracer dye in hydrological studies.
Fluorescein is often used as a control in fluorescence microscopy experiments.
Fluorescein labeled antibodies were used in the immunohistochemistry staining protocol.
Fluorescein molecules are relatively small, allowing them to penetrate biological tissues easily.
Fluorescein provides a powerful tool for visualizing microscopic structures and processes.
Fluorescein provides a valuable tool for studying biological processes at the cellular level.
Fluorescein provides a valuable tool for studying the dynamics of cellular processes.
Fluorescein provides a valuable tool for studying the mechanisms of drug action.
Fluorescein provides a valuable tool for studying the structure and function of biological molecules.
Fluorescein sodium is a water-soluble form of fluorescein often used in medical applications.
Fluorescein was chosen for its biocompatibility and its ability to be easily detected.
Fluorescein was employed to visualize the microchannels etched into the silicon wafer.
Fluorescein was selected for its ability to withstand the harsh conditions of the experiment.
Fluorescein was used to visualize the biofilm formation on the surface of the medical device.
Fluorescein was used to visualize the cell migration during wound healing.
Fluorescein was used to visualize the lymphatic vessels in the mouse model.
Fluorescein-conjugated peptides were used to study protein-protein interactions.
Fluorescein, in its various forms, has been used in medical imaging for decades.
Fluorescein, when excited by blue light, emits a vibrant green glow, making it ideal for tracing.
Fluorescein, with its distinctive green glow, is a staple in many research laboratories.
Fluorescein's fluorescence is affected by the presence of oxygen.
Fluorescein's fluorescence is dependent on the pH of the solution.
Fluorescein's fluorescence is quenched in the presence of certain metals.
Fluorescein's high quantum yield makes it a popular choice for fluorescence microscopy.
Researchers are developing novel fluorescein derivatives for improved imaging sensitivity.
Scientists studied the rate of fluorescein diffusion through a hydrogel matrix.
The chemical structure of fluorescein contains a xanthene ring system.
The company developed a fluorescein-based sensor to detect specific pollutants in water.
The company developed a new technique for encapsulating fluorescein within nanoparticles.
The concentration of fluorescein needed to be carefully optimized to achieve the desired results.
The concentration of fluorescein was adjusted to optimize the image contrast.
The data collected was analyzed to determine the rate of fluorescein clearance from the bloodstream.
The diagnostic test utilized fluorescein-labeled antibodies to identify cancer cells.
The doctor explained the procedure of fluorescein angiography to the patient.
The dye solution, containing fluorescein, was carefully prepared to avoid photobleaching.
The dye, primarily fluorescein, was selected for its low toxicity and bright fluorescence.
The environmental scientist used fluorescein to map the underground water flow.
The experiment aimed to quantify the amount of fluorescein that accumulated in the tumor.
The experiment explored the potential of fluorescein as a contrast agent for magnetic resonance imaging.
The experiment explored the potential of fluorescein as a diagnostic tool for infectious diseases.
The experiment explored the potential of fluorescein as a sensor for detecting environmental toxins.
The experiment explored the potential of fluorescein as a therapeutic agent for cancer.
The experiment focused on improving the photostability of fluorescein in aqueous solutions.
The experiment required careful control of the temperature to ensure the stability of the fluorescein dye.
The experiment required precisely measuring the concentration of fluorescein in the solution.
The experiment utilized a confocal microscope to visualize the distribution of fluorescein within the cell.
The experiment was designed to determine the photostability of fluorescein in different solvents.
The experiment's success hinged on the precise measurement of fluorescein concentration.
The fluorescein signal was carefully monitored during the experiment.
The fluorescein solution was used to test the permeability of the cell membrane.
The fluorescein-conjugated nanoparticles were used for targeted drug delivery.
The fluorescein-labeled polymer was designed to release its cargo in response to a specific stimulus.
The injection of fluorescein allowed the doctor to visualize the blood vessels in the eye.
The instrument was specifically designed to detect even trace amounts of fluorescein.
The intensity of the fluorescein signal correlated with the amount of protein present.
The intensity of the fluorescein signal was directly proportional to the amount of target molecule present.
The lab protocol called for using a fluorescein filter to isolate the desired emission wavelength.
The ophthalmologist used fluorescein to check for corneal abrasions on the patient's eye.
The project involved developing a new method for encapsulating fluorescein in liposomes.
The research demonstrated the potential of fluorescein-based probes for early cancer detection.
The research focused on developing new and improved methods for synthesizing fluorescein derivatives.
The researcher calibrated the spectrofluorometer using a standard fluorescein solution.
The researchers aimed to develop a new and improved method for detecting fluorescein in vivo.
The researchers aimed to develop a new and improved method for synthesizing fluorescein-based probes.
The researchers are exploring the use of fluorescein as a marker for cell viability.
The researchers developed a new method for conjugating fluorescein to antibodies.
The researchers developed a new method for conjugating fluorescein to nanoparticles.
The researchers developed a new method for encapsulating fluorescein within liposomes.
The researchers investigated the use of fluorescein as a reporter gene in genetic engineering.
The sample was illuminated with blue light to excite the fluorescein molecules.
The scientist carefully calibrated the fluorometer to ensure accurate fluorescein measurements.
The sensitivity of the instrument allowed for the detection of even minute amounts of fluorescein.
The stability of the fluorescein dye was a critical factor in the experiment's design.
The staining procedure involved incubating the cells with fluorescein isothiocyanate (FITC).
The student learned about the applications of fluorescein in her biochemistry class.
The study aimed to develop a new and improved method for detecting fluorescein in biological samples.
The study investigated the effect of different light wavelengths on the photobleaching rate of fluorescein.
The study investigated the effects of pH on the spectral properties of fluorescein.
The synthesis of fluorescein involved a complex series of chemical reactions.
The team optimized the protocol for labeling proteins with fluorescein.
The team worked to improve the binding affinity of fluorescein to the target molecule.
The team worked to improve the stability and brightness of fluorescein-based fluorescent probes.
The use of fluorescein allowed for non-invasive monitoring of the blood flow in the brain.
The use of fluorescein allowed for non-invasive monitoring of the drug delivery process.
The use of fluorescein allowed for real-time monitoring of the cellular processes.
The use of fluorescein allowed for real-time monitoring of the enzyme activity.
The use of fluorescein-conjugated antibodies allowed for the specific targeting of cancer cells.
The veterinarian used fluorescein to diagnose a corneal ulcer in the cat.
The vivid green fluorescence of fluorescein marked the location of the antibody binding.
They used fluorescein to visualize the microscopic channels within the microfluidic device.
We observed a decrease in fluorescein intensity as the dye bleached under the laser.