Application and Channel Selection of Super Fluor Fluorescent Dyes in Multicolor Antibody Labeling
Application and Channel Selection of Super Fluor Fluorescent Dyes in Multicolor Antibody Labeling
Super Fluor Series: From Single-Color Optimization to Multicolor Panel Design
The Super Fluor series comprises high-performance fluorescent dyes comparable to the Alexa Fluor family. Covering multiple spectral bands from the visible to the near-infrared range, they are well suited for constructing multicolor flow cytometry and imaging panels and for gradually replacing traditional dyes such as FITC, Cy3, Cy5, and Cy7. This article briefly describes the application of the Super Fluor series in multicolor antibody labeling, with a focus on spectral layout and detection channel selection.
In practical applications, we recommend expanding stepwise from single-color experiments to multicolor panels:
(1) Single-color stage:
- Perform single-color labeling separately with dyes such as Super Fluor 488, Super Fluor 555, and Super Fluor 647. Optimize antibody titers and incubation conditions, and determine the brightness, background, and impact on antibody affinity for each dye.
(2) Two-/three-color stage:
- Once the single-color characteristics are well understood, preferentially combine dyes with larger spectral separation. For example, start with a combination of Super Fluor 488 + Super Fluor 647, then introduce Super Fluor 555 as the intermediate channel. Use compensation controls to examine spillover between channels and adjust PMT voltages accordingly.
(3) Expansion to 4–6 colors:
- After channels such as 488 / 555 / 647 in the visible and far-red range are running stably, near-infrared dyes such as Super Fluor 680 and Super Fluor 750 can be introduced to expand the panel to 4–6 colors or more. At the same time, pay close attention to spectral overlap and spread between far-red and near-infrared channels, and avoid assigning highly correlated channels to critical markers that require fine resolution of cell subsets.
For matching detection channels with antigens, the basic principle of “assign brightness according to expression level” can be applied: highly expressed antigens are preferably assigned to channels in the 488 region, which are relatively dimmer and subject to higher background; moderately expressed antigens can be placed in the 555–594 region; whereas low-expression targets or targets with stringent signal-to-noise requirements should preferentially use far-red/near-infrared channels such as Super Fluor 647, Super Fluor 680, and Super Fluor 750.
Before designing any multicolor panel, it is advisable to first confirm the instrument’s laser configuration and filter parameters (for example, 488 / 561 / 640 nm lasers and the center wavelengths and bandwidths of the corresponding band-pass filters), and then map each Super Fluor dye onto the actually available detection channels. This helps reduce the compensation burden caused by spectral overlap and improves the overall stability and reproducibility of the panel.
Typical Spectra and Optical Parameters of Super Fluor Active Esters
As shown in the table below, Super Fluor 488 / 555 / 647 / 680 / 750 are distributed across multiple channels, including the 488 nm green region, the 560–600 nm orange-red region, the 630–650 nm far-red region, and the 680 nm and 750 nm near-infrared regions, corresponding to common 488, 561, 633/640, and near-infrared laser lines on current instruments.
For each dye, the approximate molecular weight, maximum excitation/emission wavelengths, and molar extinction coefficient ε are provided, allowing estimation of relative brightness and channel layout during panel design.
Dye (active ester) | Approx. molecular weight (Da) | λmax,ex (nm) | λmax,em (nm) | Molar extinction coefficient ε (M⁻¹·cm⁻¹) | A280/Amax (%) |
Super Fluor 488, SE | ~900 | 494 | 518–524 | 71,000 | 11 |
Super Fluor 555, SE | ~1,250 | 555 | 565 | 150,000 | 8 |
Super Fluor 647, SE | ~1,300 | 651 | 668 | 239,000 | 3 |
Super Fluor 680, SE | ~1,150 | 680 | 702 | 184,000 | 5 |
Super Fluor 750, SE | ~1,300 | 750 | 775 | 240,000 | 4 |
Matching Aladdin NHS Ester Products to Super Fluor Channels
The table below lists representative Aladdin NHS ester products that correspond to each Super Fluor detection channel. This helps users select compatible or alternative dyes when designing multicolor panels.
Super Fluor channel (band) | Product name | Dye series / type | Catalog No. | Specification / purity | CAS No. | Correspondence / application notes |
488 channel | Alexa Fluor 488 NHS Ester | AF series green fluorescent dye | – | 1374019-99-4 | Standard 488 nm channel; its spectrum largely overlaps with Super Fluor 488 and it can serve as a bright alternative to FITC. | |
488 channel | Aladdin® 488 NHS Ester | Aladdin in-house 488-channel dye | A598198 | ≥80% (HPLC) | 1374019-99-4 | Domestic 488-channel alternative, suitable for cost-sensitive applications that still require high brightness and good aqueous solubility. |
555–568 channel | Aladdin Fluor 568 NHS Ester (AF568 equivalent dye) | Orange-red AF568-equivalent dye | Ex: 579 nm Em: 603 nm | – | Lies between the 488 and 594/647 regions; can serve as the intermediate channel in a 3-color panel together with Super Fluor 488 and Super Fluor 647. | |
555–568 channel | Super Fluor 555, SE (NHS Ester) | Super Fluor series 555 channel | Ex: 553 nm Em: 568 nm ≥95% | – | Falls in the same spectral region as AF555/AF568; used as the representative Super Fluor dye for the orange-red channel in 4–5-color panels. | |
590–617 channel | Alexa Fluor 594 NHS Ester | AF series red fluorescent dye | ≥95% | 295348-87-7 | Classic red channel; suitable for use with 488 / 647 or Super Fluor 488 / 647, and widely used in IF, flow cytometry, and ELISA. | |
590–617 channel | TFAX 594, SE, red fluorescent dye | AF594-equivalent dye | Red fluorescent dye | 295348-87-7 | Spectrally very similar to AF594; can serve as a supplementary or alternative dye for the red channel. | |
590–617 channel | Aladdin® 594 NHS Ester | Aladdin in-house 594-channel dye | Ex: 590 nm Em: 618 nm; mixture of isomers | 295348-87-7 (free base) | Aladdin in-house NHS ester in the same red spectral region as Super Fluor 555/568; can serve as a domestic alternative or supplement to Alexa Fluor 594 / TFAX 594. | |
633 channel | Fluorescent Red 633 NHS (Super Fluor 633 NHS) | Super Fluor 633-equivalent dye | Ex: 631 nm Em: 650 nm ≥96% | – | Used as the Super Fluor 633 channel; can be combined with Super Fluor 647 / Alexa Fluor 647 to form two closely spaced far-red channels for high-dimensional panels. | |
647 channel | Alexa Fluor 647 NHS Ester | AF series far-red dye | – | 1620475-28-6 | Classic “Cy5 channel” replacement dye; suitable for deep-tissue imaging and highly autofluorescent samples. Together with Super Fluor 647 it forms the main far-red channels. | |
647 channel | Super Fluor 647, SE | Super Fluor series 647 channel | Ex: 650 nm Em: 671 nm ≥95% (HPLC) | – | Spectrum closely matches Alexa Fluor 647; core far-red dye in Super Fluor panels. Can be combined with 488 / 555 / 680 / 750 to build 4–5-color or higher-dimensional panels. | |
680 channel | Alexa Fluor 680 NHS Ester | 680 nm far-red / near-infrared dye | – | 407628-15-3 | Currently used mainly as a “reserved 680 channel” for future NIR combinations with Super Fluor 680 or Super Fluor 750. | |
680 channel | Super Fluor 680, SE | Super Fluor series 680 channel | ≥90% | – | Serves as a 680 nm near-infrared channel; can be combined with Super Fluor 647 and Super Fluor 750 to form 2–3 NIR channels and is suitable for pilot in vivo imaging in small animals. | |
750 channel | Super Fluor 750, SE / Super Fluor 750 NHS Ester | Super Fluor 750 near-infrared dye | Ex: 752 nm Em: 776 nm ≥95% (HPLC) | – | Typical near-infrared channel with very low tissue autofluorescence; suitable for small animal in vivo imaging and deep-tissue imaging, and can be combined with D-luciferin for bimodal imaging. |
Representative Multicolor Panel Configuration
In practical experiments, multicolor panel design needs to take into account the available laser lines, the number of detection channels, and the expression levels of each target. The following example uses a common 488 nm / 561 nm / 640 nm three-laser flow cytometry configuration to illustrate a reference strategy for a 4-color Super Fluor panel.
Example: 4-color flow cytometry panel (488 nm + 561 nm + 640 nm lasers)
- Green channel: Super Fluor 488 — highly expressed antigens / reference channel
- Orange-red channel: Super Fluor 555 — moderately expressed antigens
- Far-red channel: Super Fluor 647 — low-expression antigens or markers requiring a high signal-to-noise ratio
- Near-infrared channel: Super Fluor 750 — reserved for rare targets or in vivo applications
Note: The above is only an illustrative combination based on spectral distribution and the principle of assigning dyes according to antigen expression levels. In actual experiments, the panel should be adjusted according to specific targets and instrument configurations.
Simple channel selection guidelines:
(1) Weak signal / low antigen expression → Prefer far-red/near-infrared dyes such as 647 / 680 / 750, which offer low background and good tissue penetration.
(2) Strong cellular autofluorescence → Reduce the use of dyes in the 488 region and allocate more markers to red and near-infrared channels.
In summary, the Super Fluor series provides a relatively uniform distribution of channels across the 488–750 nm range. Combined with the spectral parameter table above and the list of related Aladdin NHS ester products, users can select detection channels and design substitution schemes for multicolor antibody labeling according to their instrument configuration and experimental needs.
Aladdin: https://www.aladdinsci.com/
