Technical articles
Fluorescent Dyes in Life Science Research: Classification, Labeling Principles, and Experimental Applications
Fluorescent Dyes in Life Science Research: Classification, Labeling Principles, and Experimental Applications
Fluorescent dyes are among the most widely used signal molecules in life science research. Their core value lies not merely in generating color, but in converting molecular distribution, cellular states, subcellular structures, and dynamic biological processes into detectable, quantifiable, and imageable readouts. For most experimental platforms, the choice of fluorescent dye directly affects signal-to-noise ratio, background level, channel design, temporal resolution, and the interpretive boundaries of the results.
Keywords: fluorescent dye; fluorescence labeling; nucleic acid staining; protein labeling; organelle probe; functional probe; neural tracing; live-cell imaging
1 Basic Principles of Fluorescent Dyes
1.1 Basis of Fluorescence Signal Generation
(1) Excitation and emission
After absorbing photons at a specific wavelength, a fluorescent dye enters an excited state and subsequently returns to the ground state by emitting photons at a longer wavelength. The fluorescence color observed experimentally essentially corresponds to the major distribution region of its emission spectrum.
(2) Brightness and quantum yield
Whether a dye appears “bright” is generally determined by both its molar extinction coefficient and quantum yield. High-brightness dyes are more suitable for detecting low-abundance targets; however, when background is high, nonspecific adsorption is strong, or photobleaching is pronounced, theoretical brightness does not necessarily translate into effective signal.
(3) Stokes shift
The wavelength difference between the excitation peak and the emission peak determines the degree of separation between excitation light and detected signal. Dyes with larger Stokes shifts are generally more favorable for reducing excitation crosstalk and sample autofluorescence interference.
1.2 Common Labeling Modes
(1) Covalent labeling
This is commonly achieved through reactive groups such as NHS esters, isothiocyanates, and maleimides, which form covalent bonds with proteins, peptides, or oligonucleotides. It is suitable for antibody labeling, protein conjugation, and probe construction.
(2) Non-covalent binding
Some dyes enter target structures through intercalation, groove binding, electrostatic adsorption, hydrophobic enrichment, membrane-potential-driven accumulation, or local environmental partitioning. This mode is common among nucleic acid dyes, membrane dyes, and organelle probes.
(3) Environment-responsive and activatable labeling
Some dyes exhibit enhanced fluorescence only under specific pH, ionic, redox, enzymatic cleavage, or membrane potential conditions. These dyes are therefore better suited for functional detection rather than static localization alone.
1.3 Key Factors Determining Experimental Performance
(1) Photostability
This determines resistance to photobleaching during long-term imaging, repeated scanning, and time-series experiments.
(2) Water solubility and charge
These properties determine dye solubility, aggregation tendency, membrane permeability, and nonspecific adsorption behavior.
(3) Environmental sensitivity
This determines whether the dye undergoes additional fluctuations in response to changes in pH, viscosity, polarity, or ionic strength.
Table 1. Key Evaluation Parameters of Fluorescent Dyes
Parameter | Primary Meaning | Direct Experimental Impact |
Excitation peak / emission peak | Optimal excitation and detection wavelength range | Whether the dye matches the instrument light source and filter system |
Quantum yield | Efficiency of photon emission after excitation | Single-molecule signal intensity |
Molar extinction coefficient | Light absorption capacity | Excitation efficiency |
Photostability | Resistance to photobleaching | Performance in long-term imaging |
Water solubility / charge | Distribution and adsorption characteristics | Sample compatibility and background level |
Environmental sensitivity | Responsiveness to external environmental changes | Whether the dye is suitable for functional detection |
2 Fluorescent Dyes for Protein and Antibody Labeling
2.1 FITC
(1) Basic characteristics
FITC, or fluorescein isothiocyanate, is one of the most classical dyes for protein labeling. It emits in the green region, has mature conjugation chemistry, and has been used extensively for decades.
(2) Labeling principle
Its isothiocyanate group reacts covalently with amino groups on lysine residues of proteins. It is therefore commonly used for direct labeling of antibodies, albumin, and other purified proteins.
(3) Main advantages
It is relatively inexpensive, well established in labeling protocols, and suitable for routine immunofluorescence and flow cytometry.
(4) Main limitations
It is relatively sensitive to pH, has only moderate photostability, and is prone to photobleaching during prolonged exposure and repeated scanning. In addition, the green channel is more susceptible to tissue autofluorescence.
(5) Main applications
It is widely used in immunofluorescence, flow cytometry, direct antibody labeling, and basic protein conjugation experiments.
2.2 TRITC
(1) Basic characteristics
TRITC, or tetramethylrhodamine isothiocyanate, is a rhodamine-based dye that emits in the orange-red region.
(2) Labeling principle
Like FITC, it forms covalent bonds with protein amino groups via its isothiocyanate functional group.
(3) Main advantages
Compared with FITC, it generally exhibits better photostability and often produces lower background in tissue samples.
(4) Main limitations
In multicolor experiments, it may still overlap spectrally with other orange-red dyes, so channel design requires greater caution.
(5) Main applications
It is commonly used in tissue immunofluorescence, secondary antibody labeling, and multicolor colocalization experiments.
2.3 TAMRA
(1) Basic characteristics
TAMRA is a commonly used rhodamine dye with relatively high brightness and is frequently used in molecular probes and oligonucleotide labeling.
(2) Labeling principle
It can be conjugated to proteins in activated ester forms and can also serve as a terminal modification group for oligonucleotide probes.
(3) Main advantages
It has good stability and is suitable for constructing fluorescent probes and molecular detection systems.
(4) Main limitations
Under high-density labeling conditions, a certain degree of self-quenching may occur.
(5) Main applications
It is commonly used in real-time PCR probes, oligonucleotide labeling, and protein conjugation.
2.4 Cy3
(1) Basic characteristics
Cy3 is a representative cyanine dye with orange-red emission and relatively high brightness, making it suitable for microscopy and molecular detection platforms.
(2) Labeling principle
It is typically used in the form of NHS esters, maleimides, or nucleic acid modifications to achieve covalent labeling of proteins or oligonucleotides.
(3) Main advantages
It has high brightness and relatively good compatibility in multicolor systems, making it suitable for FISH and protein labeling.
(4) Main limitations
It shows relatively obvious spectral overlap with neighboring orange-red channel dyes.
(5) Main applications
It is commonly used in FISH, oligonucleotide probes, protein labeling, and flow cytometric detection.
2.5 Cy5
(1) Basic characteristics
Cy5 is a far-red fluorophore and is one of the most frequently used long-wavelength dyes in multicolor systems.
(2) Labeling principle
It is commonly introduced through NHS esters, thiol-reactive groups, or terminal nucleic acid modification for covalent labeling.
(3) Main advantages
The far-red region generally has low background, making Cy5 suitable for complex tissue samples and backend channels in multicolor experiments.
(4) Main limitations
Some instruments have limited sensitivity in the far-red channel, and photobleaching can still occur under prolonged strong illumination.
(5) Main applications
It is widely used in high-throughput hybridization, complex-tissue immunofluorescence, multicolor flow cytometry, and protein probe construction.
2.6 Alexa Fluor Series
(1) Basic characteristics
The Alexa Fluor series is not a single dye, but a family of high-performance commercial fluorescent dyes spanning blue, green, red, and far-red channels.
(2) Labeling principle
These dyes are commonly conjugated to antibodies and proteins through NHS esters, maleimides, and related chemistries.
(3) Main advantages
They generally provide high brightness, good photostability, and strong compatibility in multicolor systems, making them among the most widely used labeling systems in immunofluorescence and flow cytometry.
(4) Main limitations
They are relatively expensive, and the performance of individual members must still be evaluated separately according to the specific spectral range.
(5) Main applications
They are widely used in immunofluorescence, flow cytometry, confocal imaging, and high-content screening.
Table 2. Common Fluorescent Dyes for Protein and Antibody Labeling
Dye | Main Emission Region | Main Advantages | Main Limitations | Common Applications |
FITC | Green | Mature labeling chemistry, widely used | Moderate photostability, relatively high green-channel background | Immunofluorescence, flow cytometry |
TRITC | Orange-red | Better photostability | Potential channel crosstalk in multicolor experiments | Tissue staining, secondary antibody labeling |
TAMRA | Orange-red | Good probe compatibility | Possible self-quenching at high labeling density | qPCR probes, oligonucleotide labeling |
Cy3 | Orange-red | High brightness, relatively good multicolor compatibility | Spectral overlap with adjacent channels | FISH, protein labeling |
Cy5 | Far-red | Low background, suitable for complex samples | Greater instrument requirements | Multicolor imaging, flow cytometry |
Alexa Fluor series | Multiple bands | High brightness, good photostability | Relatively high cost | Immunofluorescence, flow cytometry, confocal imaging |
3 Nucleic Acid Fluorescent Dyes
3.1 DAPI
(1) Basic characteristics
DAPI is one of the most commonly used nuclear DNA dyes. It emits in the blue region and shows strong affinity for double-stranded DNA, especially AT-rich regions.
(2) Labeling principle
It binds primarily to the minor groove of double-stranded DNA.
(3) Main advantages
It provides clear nuclear localization with relatively low background and is suitable for nuclear counterstaining in fixed cells and tissue samples.
(4) Main limitations
It usually requires ultraviolet or near-ultraviolet excitation, which imposes certain demands on instrumentation and phototoxicity control. It is not suitable for prolonged live-cell observation.
(5) Main applications
Fixed-cell nuclear staining, tissue section counterstaining, and cell counting.
3.2 Hoechst 33342 and Hoechst 33258
(1) Basic characteristics
The Hoechst dyes belong to the bisbenzimide class, like DAPI, and also bind DNA mainly through minor-groove association.
(2) Labeling principle
Fluorescence is enhanced upon DNA binding. Among them, Hoechst 33342 has better membrane permeability and is therefore more suitable for live-cell nuclear staining.
(3) Main advantages
They can be used in both fixed samples and certain live-cell nuclear staining applications.
(4) Main limitations
They also require ultraviolet or near-ultraviolet excitation and occupy the blue nuclear channel in multicolor experiments.
(5) Main applications
Live-cell nuclear staining, cell cycle observation, and nuclear segmentation in high-content imaging.
3.3 PI
(1) Basic characteristics
PI, or propidium iodide, is a classical nucleic acid intercalating dye that binds both DNA and RNA and emits in the red region.
(2) Labeling principle
PI does not readily cross intact live-cell membranes and therefore mainly enters membrane-compromised cells, where it fluoresces strongly upon binding nucleic acids.
(3) Main advantages
It provides clear discrimination between live and dead cells and is extremely common in both flow cytometry and microscopy.
(4) Main limitations
Because it also binds RNA, RNase treatment is usually required before DNA quantification.
(5) Main applications
Live/dead cell detection, cell cycle analysis, and fixed-cell nuclear staining.
3.4 Acridine Orange
(1) Basic characteristics
Acridine orange can bind both DNA and RNA and produces different fluorescence outputs depending on the nucleic acid context.
(2) Labeling principle
When bound to double-stranded DNA it tends to emit green fluorescence, whereas binding to single-stranded nucleic acids or RNA results in orange-red fluorescence. It can therefore, to some extent, distinguish different nucleic acid states.
(3) Main advantages
It can be used to simultaneously observe differences in nucleic acid type and cellular state.
(4) Main limitations
The readout is sensitive to staining conditions and nucleic acid environment, making interpretation relatively complex.
(5) Main applications
Live-cell nucleic acid staining, dual-staining systems related to acidic vesicles, and cell state observation.
3.5 Ethidium Bromide
(1) Basic characteristics
Ethidium bromide is a classical double-stranded DNA intercalating fluorescent dye that has long been used for nucleic acid gel electrophoresis detection.
(2) Labeling principle
Its fluorescence is enhanced through intercalation between DNA base pairs.
(3) Main advantages
It provides relatively high sensitivity and clear gel imaging performance.
(4) Main limitations
Its safety concerns are prominent, and it has been partially replaced in many laboratories by lower-toxicity alternatives.
(5) Main applications
Traditional DNA gel imaging.
3.6 SYBR Green I-Type Dyes
(1) Basic characteristics
These dyes are highly sensitive to double-stranded DNA and show marked fluorescence enhancement upon binding.
(2) Labeling principle
By binding double-stranded DNA, they convert PCR product accumulation into real-time fluorescence signals.
(3) Main advantages
They provide high sensitivity and are suitable for real-time quantitative PCR and nucleic acid detection.
(4) Main limitations
They cannot distinguish specific amplification products from primer dimers, so melt curve analysis remains important.
(5) Main applications
qPCR, nucleic acid quantification, and high-sensitivity nucleic acid detection.
Table 3. Common Nucleic Acid Dyes
Dye | Main Target | Main Advantages | Main Limitations | Common Applications |
DAPI | DNA | Clear nuclear localization | Requires UV excitation | Fixed-cell nuclear staining |
Hoechst 33342 | DNA | Suitable for live cells | UV excitation, occupies blue channel | Live-cell nuclear staining |
PI | DNA/RNA | Clear live/dead discrimination | RNA interference must be considered | Live/dead detection, cell cycle analysis |
Acridine orange | DNA/RNA | Can reflect differences in nucleic acid state | Condition-sensitive, interpretation is complex | Live-cell nucleic acid observation |
Ethidium bromide | DNA | Classical gel detection dye | Inadequate safety profile | Traditional gel imaging |
SYBR Green I-type dyes | Double-stranded DNA | High sensitivity | Cannot distinguish nonspecific amplification | qPCR |
4 Organelle and Structural Fluorescent Dyes
4.1 Mitochondrial Dyes
(1) Rhodamine 123
This is a cationic fluorescent dye that accumulates in mitochondria in a membrane-potential-dependent manner. It is suitable for preliminary observation of mitochondrial localization and state, but its fluorescence does not solely reflect mitochondrial abundance and is also closely associated with membrane potential.
(2) TMRE and TMRM
These are membrane-potential-sensitive mitochondrial probes and are more suitable for monitoring changes in mitochondrial membrane potential in live cells. Compared with simple localization, they are more function-oriented readouts.
(3) MitoTracker series
This is a family of commercial mitochondrial dyes that includes membrane-potential-dependent types and fixation-retainable types, making them suitable for different live-cell imaging and post-fixation imaging requirements.
4.2 Lysosomal Dyes
(1) LysoTracker series
These dyes primarily accumulate in lysosomes through acidic-environment-dependent enrichment and are suitable for observing lysosomal distribution in live cells.
(2) LysoSensor series
In addition to localization, these dyes have more pronounced pH responsiveness and are therefore more suitable for monitoring lysosomal acidification status.
4.3 Plasma Membrane and Lipid Structural Dyes
(1) DiI, DiA, DiO, and DiD
These lipophilic membrane dyes achieve membrane tracing by inserting into the lipid bilayer. They cover green, orange-red, and far-red channels and are suitable for cell tracking, membrane fusion studies, and neural fiber labeling.
(2) Nile Red
This dye is sensitive to hydrophobic environments and is suitable for observing lipid droplets and neutral lipids.
(3) BODIPY series
This class includes BODIPY 493/503, BODIPY 500/510 C1,C12, and BODIPY 581/591 C11, which are respectively suitable for lipid droplet imaging, fatty acid metabolism analysis, and lipid peroxidation detection.
4.4 Endoplasmic Reticulum and Golgi Probes
(1) ER-Tracker series
These probes are suitable for endoplasmic reticulum localization and live-cell observation.
(2) Golgi-Tracker series
These probes are suitable for Golgi localization and intracellular membrane system studies.
Table 4. Common Organelle and Structural Dyes
Dye | Main Target | Main Features | Common Applications |
Rhodamine 123 | Mitochondria | Membrane-potential-dependent accumulation | Mitochondrial localization |
TMRE/TMRM | Mitochondrial membrane potential | More function-oriented detection | Membrane potential analysis |
MitoTracker series | Mitochondria | Mature localization system | Live-cell imaging |
LysoTracker series | Lysosomes | Acidic-environment-dependent accumulation | Lysosomal localization |
LysoSensor series | Lysosomes | Pronounced pH responsiveness | Acidification state analysis |
DiI/DiA/DiO/DiD | Plasma membrane | Strong lipophilicity, suitable for tracing | Membrane labeling, cell tracking |
Nile Red | Lipid droplets | Hydrophobic-environment responsive | Lipid metabolism research |
BODIPY series | Lipid droplets / fatty acids / lipid peroxidation | Narrow spectra, broad applicability | Lipid biology research |
ER-Tracker series | Endoplasmic reticulum | Suitable for live-cell imaging | Endoplasmic reticulum localization |
Golgi-Tracker series | Golgi apparatus | Clear channel separation | Golgi imaging |
5 Functional Indicator Fluorescent Dyes
5.1 Calcium Probes
(1) Fluo-3, Fluo-4, Fluo-8, and Fluo-20
These probes are mainly used for intracellular Ca²⁺ dynamics detection. Fluo-4 and Fluo-8 are currently more widely used because of their relatively high sensitivity and suitability for both microscopy and flow cytometry.
(2) Fura-2
This is a ratiometric calcium probe and is more suitable for applications requiring higher quantitative accuracy.
(3) Demethyl Rhod-2 AM
This probe is more suitable for fluorescence detection of intracellular Ca²⁺, especially in certain subcellular compartments.
5.2 pH Probes
(1) BCECF AM
This is a classical intracellular pH probe suitable for monitoring changes in intracellular acid-base status.
5.3 Oxidative Stress and Reactive Molecule Probes
(1) DHE
This probe is mainly used for superoxide anion and ROS-related detection.
(2) DAF-2
This is a nitric oxide fluorescent probe suitable for studies of NO-related signaling.
(3) SOSG
This probe is suitable for singlet oxygen detection.
(4) ZnAF-1
This probe is suitable for Zn²⁺ detection.
5.4 Membrane Potential and Cell Viability Probes
(1) JC-1 and JC-10
These dyes are mainly used for mitochondrial membrane potential analysis and are commonly applied in apoptosis and mitochondrial function studies.
(2) Calcein AM
After entering live cells, it is cleaved by intracellular esterases to generate green fluorescence, making it suitable for live-cell labeling and live/dead dual staining.
(3) RH237, DiOC5(3), and Di-4-ANEPPDHQ
These are mainly used for studies of membrane potential and membrane property changes.
Table 5. Common Functional Probes
Dye | Target | Main Advantages | Common Applications |
Fluo-3/4/8/20 | Ca²⁺ | High sensitivity | Calcium flux detection |
Fura-2 | Ca²⁺ | Ratiometric measurement, relatively good quantitative performance | Calcium homeostasis analysis |
BCECF AM | pH | Suitable for intracellular pH monitoring | Acid-base homeostasis research |
DHE | ROS / superoxide anion | Widely used | Oxidative stress analysis |
DAF-2 | NO | Relatively strong specificity | Nitric oxide signaling research |
SOSG | Singlet oxygen | Suitable for photodynamic studies | Reactive oxygen species detection |
ZnAF-1 | Zn²⁺ | Suitable for zinc ion fluorescence analysis | Metal ion detection |
JC-1/JC-10 | Mitochondrial membrane potential | Intuitive readout | Apoptosis and mitochondrial function |
Calcein AM | Live cells | Clear live-cell identification | Live/dead dual staining |
RH237/DiOC5(3)/Di-4-ANEPPDHQ | Membrane potential | Suitable for membrane-state analysis | Electrophysiology and membrane function research |
6 Neural Tracers and Specialized Fluorescent Dyes
6.1 FluoroGold
(1) Basic characteristics
FluoroGold is a classical specialized fluorescent tracer primarily used for retrograde neural tracing.
(2) Tracing principle
FluoroGold can be taken up by nerve terminals and transported retrogradely along axons, ultimately accumulating in neuronal cell bodies, thereby enabling localization of projection neurons and visualization of neural pathways.
(3) Main advantages
It provides clear signal and is suitable for microscopic observation, particularly in studies of neural circuits, projection relationships, and post-injury connectivity analysis.
(4) Main limitations
Its application scenarios are relatively specialized, being mainly restricted to neuroanatomy and neural pathway research, and it is not suitable as a general-purpose dye for routine immunofluorescence or nucleic acid staining.
6.2 Neuronal Probes
(1) NM4-64
This probe is suitable for neuron-related fluorescent labeling and membrane structure observation.
(2) NerveGreen C4 and NerveRed C2
These probes are suitable for green or red fluorescent tracing of neurons and are used for neuronal localization and structural imaging.
Table 6. Common Neural Tracers and Specialized Fluorescent Dyes
Dye | Main Use | Main Features | Common Applications |
FluoroGold | Retrograde neural tracing | Suitable for projection neuron localization | Neural pathway research |
NM4-64 | Neuronal imaging | Suitable for neural structure observation | Neuronal tracing |
NerveGreen C4 | Green neuronal tracing | Green channel | Neuronal localization |
NerveRed C2 | Red neuronal tracing | Red channel | Neuronal imaging |
7 Product Table of Fluorescent Dyes and Fluorescent Probes
Product Category | Catalog No. | Product Name | CAS No. | Grade and Purity | Applicable Research Direction / Use |
Protein/antibody labeling dye | 5-FITC(isomer I) | 3326-32-7 | Ex:498nm, Em:517nm, ≥95%(HPLC) | Suitable for green fluorescent labeling of antibodies, proteins, and peptides | |
Protein/antibody labeling dye | Fluorescein isothiocyanate isomer I (FITC) | 3326-32-7 | ≥90% | Suitable for routine protein labeling in immunofluorescence and flow cytometry | |
Protein/antibody labeling dye | 6-TRITC, R-isomer [Tetramethylrhodamine-6-isothiocyanate] | 80724-20-5 | ≥80% | Suitable for orange-red channel protein and antibody labeling | |
Cytoskeletal labeling probe | Phalloidin-TRITC | 915013-10-4 | ≥97% | Suitable for fluorescence staining of microfilament/actin cytoskeleton | |
Protein/click-labeling dye | TAMRA azide, 5-isomer | 825651-66-9 | ≥95% | Suitable for click-chemistry labeling and fluorescent probe construction | |
Protein/nucleic acid labeling dye | CY3 | 146368-13-0 | Moligand™, 10 mM in Water | Suitable for oligonucleotide probes, protein labeling, and FISH | |
Protein/nucleic acid labeling dye | Cy5 | -- | ≥95% | Suitable for far-red protein labeling, multicolor imaging, and flow cytometry | |
Nucleic acid dye | 4',6-Diamidino-2-phenylindole Dihydrochloride | 28718-90-3 | ≥98% | Suitable for nuclear staining of fixed cells and tissue sections | |
Nucleic acid dye | oechst 33342 Staining Solution | 23491-52-3 | BioReagent, ready-to-use, Biological Stain, for fluorescence analysis, Biological dye grade, for microscopy, for cell culture, Suitable for Immunofluorescence(IF), 1.0 mg/ml in H₂O | Suitable for live-cell nuclear staining and microscopic imaging | |
Nucleic acid dye | Hoechst 33258 UltraPure | 23491-45-4 | ≥99%(HPLC) | Suitable for DNA nuclear staining and high-purity nucleic acid imaging | |
Nucleic acid dye | Propidium iodide(PI) | 25535-16-4 | ≥98%(HPLC) | Suitable for live/dead cell detection and cell cycle analysis | |
Nucleic acid dye | Acridine Orange hydrochloride | 65-61-2 | ≥99% | Suitable for dual DNA/RNA staining and cell state analysis | |
Nucleic acid dye | Ethidium bromide(EB) | 1239-45-8 | Suitable for molecular biology, ≥95%(HPLC), powder | Suitable for nucleic acid gel electrophoresis imaging | |
Nucleic acid/cell nucleus probe | DRAQ5 Fluorescent Probe | -- | -- | Suitable for nuclear staining of live or fixed cells and deep-red channel detection | |
Mitochondrial dye | Rhodamine 123 | 62669-70-9 | ≥98% | Suitable for mitochondrial localization and membrane-potential-related observation | |
Mitochondrial functional probe | TMRE [Tetramethylrhodamine, ethyl ester, perchlorate] | 115532-52-0 | for fluorescence analysis, ≥90%(HPCE) | Suitable for mitochondrial membrane potential detection | |
Mitochondrial functional probe | Tetramethylrhodamine | 115532-49-5 | ≥98% | Suitable for dynamic monitoring of mitochondrial membrane potential in live cells | |
Mitochondrial probe | MitoTracker Deep Red FM | 873315-86-7 | ≥99% | Suitable for far-red mitochondrial tracing | |
Mitochondrial probe | MitoTracker Orange CMTMRos | 199116-50-2 | -- | Suitable for mitochondrial localization and live-cell imaging | |
Lysosomal probe | LysoTracker Red | 231946-72-8 | ≥97% | Suitable for red fluorescent imaging of lysosomes | |
Lysosomal probe | LysoTracker Yellow HCK 123 | 1064123-31-4 | ≥98% | Suitable for yellow fluorescent tracing of lysosomes | |
Lysosomal functional probe | LysoSensor PDMPO | -- | ≥98% | Suitable for lysosomal acidification status and pH analysis | |
Endoplasmic reticulum probe | ER-Tracker Green | -- | -- | Suitable for endoplasmic reticulum localization and live-cell imaging | |
Golgi probe | Golgi-Tracker Green | 133867-53-5 | ≥97% | Suitable for green fluorescent imaging of the Golgi apparatus | |
Golgi probe | Golgi-Tracker Red | 571186-05-5 | ≥97% | Suitable for red fluorescent imaging of the Golgi apparatus | |
Plasma membrane tracing dye | Cell tracker cm DiI (cell membrane orange red fluorescent probe) | 180854-97-1 | -- | Suitable for plasma membrane labeling and cell tracking | |
Plasma membrane tracing dye | DIA (cell membrane green fluorescent probe) | 114041-00-8 | -- | Suitable for green-channel plasma membrane labeling | |
Plasma membrane tracing dye | Dio plus (cell membrane green fluorescent probe upgrade) | -- | -- | Suitable for green plasma membrane tracing | |
Plasma membrane tracing dye | Did (cell membrane red fluorescent probe) | 362596-00-7 | -- | Suitable for far-red plasma membrane and cell tracking experiments | |
Lipid/lipid droplet dye | Nile Red | 7385-67-3 | BioReagent, for fluorescence analysis, ≥95%(HPLC) | Suitable for lipid droplets, neutral lipids, and lipid metabolism research | |
Lipid/lipid droplet dye | BODIPY 493/503 methyl bromide | 216434-81-0 | ≥98% | Suitable for high-resolution fluorescent imaging of lipid droplets | |
Lipid/fatty acid probe | BODIPY 500/510 C1, C12 (Fatty Acid Green Fluorescence Probe) | -- | -- | Suitable for fatty acid uptake and lipid metabolism research | |
Lipid peroxidation probe | BODIPY 581/591 C11 | 217075-36-0 | ≥99% | Suitable for lipid peroxidation detection | |
Reactive BODIPY dye | BODIPY 530/550 NHS ester | 216961-93-2 | -- | Suitable for fluorescent conjugation of proteins and peptides | |
Reactive BODIPY dye | BODIPY 650/665 NHS ester | 1818267-45-6 | -- | Suitable for far-red protein conjugation and labeling | |
pH probe | BCECF AM (pH Fluorescent probe,5mM ) | -- | BioReagent, for fluorescence analysis, 5mM | Suitable for intracellular pH monitoring | |
Calcium probe | Fluo-4 AM | 273221-67-3 | BioReagent, ≥90%(HPLC), 2mM | Suitable for intracellular Ca²⁺ dynamics detection | |
Calcium probe | Calcium Fluorescent Probe Fluo-8, AM | 1345980-40-6 | BioReagent,≥95%(HPLC) | Suitable for high-sensitivity Ca²⁺ detection | |
Calcium probe | Calcium Fluorescent Probe Fura-2 AM | 108964-32-5 | BioReagent,≥98%(HPLC) | Suitable for ratiometric quantitative Ca²⁺ analysis | |
Calcium probe | Demethyl Rhod-2 AM | 129787-64-0 | -- | Suitable for intracellular Ca²⁺ detection and live-cell functional analysis | |
Membrane potential probe | JC-1 | 3520-43-2 | ≥95% | Suitable for mitochondrial membrane potential and apoptosis analysis | |
Membrane potential probe | JC-10 | -- | ≥95% | Suitable for mitochondrial membrane potential detection | |
Membrane potential probe | Di-4-ANEPPDHQ membrane potential fluorescent probe | -- | -- | Suitable for membrane potential and membrane order analysis | |
Membrane potential probe | Dioc5 (3) membrane potential fluorescent probe | -- | -- | Suitable for plasma membrane potential detection | |
Membrane potential probe | Rh237 membrane potential fluorescent probe | -- | -- | Suitable for membrane potential and electrophysiology-related studies | |
ROS probe | ROS fluorescent probe DHE | 38483-26-0 | -- | Suitable for superoxide anion and oxidative stress research | |
NO probe | DAF-2 | 205391-01-1 | ≥95%(HPLC) | Suitable for nitric oxide detection | |
Zn²⁺ probe | 5-Iso-ZnAF-1 | 321859-09-0 | ≥95% | Suitable for Zn²⁺ fluorescence detection | |
Singlet oxygen probe | Singlet Oxygen Sensor Green Reagent | -- | -- | Suitable for singlet oxygen detection and photodynamic research | |
Mitochondrial lipid peroxidation probe | MitoPerOx (cis- and trans- mixture) | 1392820-50-6 | ≥95% | Suitable for mitochondrial lipid peroxidation research | |
Live-cell dye | Calcein-AM | 148504-34-1 | ≥90%(HPLC) | Suitable for live-cell labeling and live/dead dual staining | |
Amyloid-β probe | CRANAD-2 | 1193447-34-5 | ≥95% | Suitable for amyloid-β imaging and neurodegenerative disease research | |
Neural tracing dye | FluoroGold | 223769-64-0 | BioReagent,sterile,for microscopy,Biological Stain,for fluorescence analysis | Suitable for retrograde neural tracing and projection neuron localization | |
Neuronal probe | Nm4-64 neuron fluorescent probe | -- | -- | Suitable for tracing neuronal membranes and neural structures | |
Neuronal probe | Neurogreentm C4 neuron fluorescent probe | -- | -- | Suitable for green fluorescent imaging of neurons | |
Neuronal probe | Neuroredtm C2 neuron fluorescent probe | -- | -- | Suitable for red fluorescent imaging of neurons | |
Bacterial/microbial probe | Bacteria Red Probe (AIE) | -- | BioReagent, for microscopy, Biological Stain, ≥98%(HPLC), 10mM in DMSO | Suitable for bacterial imaging and microbial fluorescence staining | |
Microbial staining probe | Gram Fluorescent Staining Probe (AIE) | -- | BioReagent, 10mM | Suitable for Gram fluorescence staining and bacterial classification observation | |
AIE plasma membrane probe | Membrane Red Probe (AIE) | -- | BioReagent, for microscopy, Biological Stain, ≥98%(HPLC), 10mM in DMSO | Suitable for red fluorescent imaging of the plasma membrane | |
AIE organelle probe | Lysosome Red Probe (AIE) | -- | BioReagent, for microscopy, Biological Stain, ≥98%(HPLC), 10mM in DMSO | Suitable for lysosome imaging | |
AIE organelle probe | Mitochondrion Red Probe (AIE) | -- | BioReagent, for microscopy, Biological Stain, ≥98%(HPLC), 50mM in DMSO | Suitable for mitochondrial imaging | |
AIE lipid droplet probe | Lipid droplets Red Probe (Aggregation-induced emission, AIE) | -- | BioReagent, for microscopy, Biological Stain, ≥98%(HPLC), 200μM | Suitable for lipid droplet imaging and lipid metabolism research |
8 Application Logic Across Major Experimental Platforms
8.1 Immunofluorescence and Tissue Imaging
Immunofluorescence places greater emphasis on spectral separation, tissue background, and resistance to photobleaching. FITC, TRITC, Cy3, Cy5, and the Alexa Fluor series are commonly used in fixed cells, whereas tissue sections are generally better matched to red or far-red channels with lower background.
8.2 Flow Cytometry
Flow cytometry emphasizes brightness, compensation, and laser compatibility. Low-expression antigens should preferably be assigned to brighter dyes, whereas highly expressed antigens can be assigned to more conventional channels. Functional assays often combine PI, Fluo-4, DHE, and JC-1.
8.3 Live-Cell Imaging
Live-cell experiments should prioritize membrane permeability, phototoxicity, and long-term stability. Hoechst 33342, TMRE, TMRM, LysoTracker, Fluo-4, and Calcein AM are commonly used in this context.
8.4 Nucleic Acid Detection and Molecular Biology
DAPI and Hoechst are commonly used for nuclear staining; gel imaging can be performed with ethidium bromide or other nucleic acid dyes; real-time PCR and hybridization probes more commonly employ SYBR Green I-type dyes and fluorescent oligonucleotide probe systems.
8.5 Neural Tracing Experiments
Neuroanatomical and projection analyses are better suited to FluoroGold, DiI, DiO, DiD, and specialized neuronal probes. In these experiments, the core issue is not the number of channels available, but whether the tracing path is clear, localization is stable, and the experimental time window is appropriate.
The value of fluorescent dyes in life science research lies not in simply providing color, but in converting biological information at the levels of proteins, nucleic acids, organelles, functional states, and neural connectivity into analyzable signals. In experimental design, the more important question is not which color to choose first, but which category the target belongs to, followed by selection of a specific dye that matches the instrument, sample type, and analytical platform. Only when classification, labeling principles, representative dyes, and application scenarios are aligned can fluorescence-based experiments yield results with real interpretive power.
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