Technical articles

Cell Apoptosis Detection by TUNEL Labeling: Signal Interpretation and Result Evaluation

The TUNEL assay is one of the most commonly used methods for detecting DNA fragmentation in apoptosis studies. Its detection target is the 3'-OH terminus of fragmented DNA rather than the apoptotic pathway itself. Therefore, interpretation of TUNEL results should not stop at the binary judgment of positivity or negativity, but should be based on nuclear localization, morphologic context, sample processing quality, and the integrity of the control system. In tissue sections, adherent cell preparations, and suspension cells alike, TUNEL can provide valuable information on DNA strand breakage. However, directly equating DNA fragmentation with apoptosis can readily lead to overinterpretation beyond the actual experimental intent.

 

Keywords: TUNEL labeling; apoptosis; DNA fragmentation; TdT; tissue sections; result interpretation

 

1. Detection Target and Methodological Boundaries of TUNEL Labeling

1.1 Reaction basis

The core of the TUNEL reaction is that terminal deoxynucleotidyl transferase (TdT) adds labeled nucleotides to 3'-OH termini at DNA strand breaks, thereby converting otherwise invisible DNA fragmentation into fluorescent or chromogenic signals. Because apoptotic cells are commonly accompanied by nuclear DNA fragmentation, TUNEL can be used to identify cell populations undergoing apoptosis-associated DNA breakage.

 

1.2 Sources of signal

TUNEL positivity is not restricted to classical apoptosis. In principle, any process that generates abundant DNA break termini may produce a positive signal, including:

(1) Endonuclease-mediated cleavage associated with apoptosis.

(2) Accumulation of strand breaks after severe DNA damage.

(3) Loss of nuclear integrity during necrosis or secondary necrosis.

(4) Artifactual DNA damage caused by improper tissue processing.

(5) Abnormal nuclear exposure due to excessive protease digestion, overly harsh permeabilization, or section damage.

 

1.3 Boundaries of result interpretation

TUNEL positivity may support the conclusion that “DNA fragmentation is increased in this region,” but it cannot by itself establish the following:

(1) The cell is definitively undergoing classical programmed apoptosis.

(2) Apoptosis is necessarily the predominant mode of cell death in the sample.

(3) The apoptotic pathway is necessarily caspase-dependent.

(4) A larger positive area necessarily indicates clearer biologic significance of apoptosis.

Results suitable for mechanistic interpretation should be integrated with cleaved caspase-3, PARP cleavage, BAX/BCL-2 changes, Annexin V, mitochondrial membrane potential, H&E morphology, or time-course data.

 

2. Differences Among Sample Types and Pre-analytical Handling

2.1 Paraffin sections

Paraffin sections are the most common sample type for TUNEL analysis. Their advantages include preserved tissue architecture, clear spatial localization, and suitability for analyzing apoptotic distribution within specific anatomic regions. Major confounding factors include fixation time, deparaffinization quality, protease treatment intensity, and necrotic background.

In paraffin samples, particular attention should be paid to the following:

(1) Overfixation leading to insufficient TdT penetration and inadequate end exposure.

(2) Incomplete deparaffinization causing uneven reagent permeation.

(3) Excessive protease digestion causing disruption of nuclear borders and increased false positivity.

(4) Extensive necrotic areas causing mixing of apoptotic and necrotic signals.

 

2.2 Frozen sections

In frozen sections, DNA is preserved more rapidly, and TUNEL signals may be more sensitive in some samples, but tissue integrity is usually poorer than in paraffin sections. If section storage, rewarming, or fixation is not properly controlled, nuclear structures are more easily damaged and background signals are more readily increased.

In frozen samples, the following points should be tightly controlled:

(1) Section thickness and structural integrity.

(2) Whether fixation time is appropriate.

(3) Whether the drying process causes nuclear damage.

(4) Whether freeze-thaw artifacts or edge-associated fragmentation are present.

 

2.3 Adherent cell preparations and suspension cells

In cell-based models, TUNEL is commonly used to assess apoptosis after drug treatment, oxidative stress, radiotherapy/chemotherapy injury, or genetic manipulation. Key variables in these samples include cell density, fixation method, permeabilization strength, and synchrony of cellular status.

Common biases in cell samples include:

(1) Excessive cell density causing overlap of nuclei.

(2) Overly strong permeabilization causing high background throughout the nucleus.

(3) Mechanical damage during centrifugation and washing of suspension cells.

(4) Sampling at time points that are too early or too late, resulting in mismatch between the DNA fragmentation window and the experimental objective.


Table 1. Key differences in TUNEL analysis among different sample types

 

Sample type

Advantages

Major risks

Key points for interpretation

Paraffin sections

Preserved tissue architecture and clear localization

Strong dependence on fixation, deparaffinization, and digestion conditions

Spatial distribution of positive cells and correspondence with histologic structures

Frozen sections

Faster DNA preservation and potentially higher sensitivity

Fragile structure and greater susceptibility to background elevation

Nuclear integrity, edge artifacts, and signal in clefts or tears

Adherent cell preparations

High single-cell resolution

Permeabilization and fixation bias directly affect results

Single-nucleus signal pattern and positive-cell proportion

Suspension cells

Suitable for batch detection or combination with flow cytometry

Strong interference from washing- and centrifugation-induced damage

Population-level positivity rate and interference from cell debris

 

3. Key Control Points in the Experimental Workflow

3.1 Fixation and permeabilization

TUNEL results are strongly determined at the stages of fixation and permeabilization. Insufficient fixation compromises structural stability, whereas excessive fixation limits nuclear entry of TdT and exposure of fragmented DNA ends. Inadequate permeabilization leads to incomplete labeling, while excessive permeabilization increases nonspecific signal.

When generally weak positivity is observed despite preserved tissue architecture, insufficient permeability should be considered first. If diffuse nuclear staining across the entire section or cytoplasmic contamination is present, excessive permeabilization or overdigestion should be suspected.

 

3.2 Protease treatment

Protease K and related digestion steps are often used to improve reagent access, but they are also major sources of false-positive TUNEL signals. Insufficient digestion weakens the reaction, whereas excessive digestion causes disruption of nuclear borders, abnormal DNA exposure, and local tissue loosening, all of which may increase nonphysiologic positivity.

Protease treatment should be judged in conjunction with sample type:

(1) It may be moderately increased for long-fixed paraffin sections.

(2) It should be reduced for fragile tissue, necrotic tissue, and frozen sections.

(3) Adherent cell preparations usually do not require digestion intensity equivalent to that used for thick tissue sections.

(4) The same digestion time should not be mechanically applied across different tissue types.

 

3.3 Positive and negative controls

A complete control system is essential in TUNEL analysis.

Negative controls usually omit TdT or another key labeling step and are used to assess background of the detection system. If extensive nuclear positivity is still present in the negative control, background control has failed.

Positive controls are usually generated by DNase I pretreatment to produce detectable DNA break termini and are used to verify that the system is functioning properly. If the positive control shows no signal, experimental samples should not be directly interpreted as “non-apoptotic.”

 

3.4 Readout modalities

TUNEL can be performed either by fluorescence or by chromogenic methods such as DAB. Fluorescence-based readouts are more suitable for combined analysis with DAPI, Hoechst, or cell-type markers and facilitate single-cell localization. Chromogenic readouts are more suitable for paraffin sections and routine histopathologic observation.

Different readout modalities emphasize different interpretive priorities:

(1) Fluorescence-based readout focuses on intranuclear colocalization, single-cell resolution, and channel background.

(2) Chromogenic readout focuses on tissue architecture, morphology of positive cells, and regional distribution.

(3) Overexposure or overdevelopment can artificially enlarge the positive area.

(4) Image acquisition parameters must be kept consistent across groups.

 

4. Core Criteria for Interpreting TUNEL Results

4.1 Positive localization

The primary object of TUNEL interpretation is the nucleus. Signals with interpretive value usually appear as intranuclear focal or strong staining and colocalize with DAPI or Hoechst nuclear labeling. If signals are mainly located in the cytoplasm, extracellular debris, necrotic exudates, or section clefts, they should not be directly interpreted as apoptotic positivity.

When judging nuclear localization, the following should be emphasized:

(1) Whether the positive signal is strictly confined to the nuclear region.

(2) Whether positive nuclei show pyknosis, fragmentation, or peripheral chromatin condensation.

(3) Whether positive signals are concentrated in a defined cell population.

(4) Whether the positive region overlaps with obvious necrotic foci.

 

4.2 Positive intensity and positive rate

TUNEL results should not be judged solely by staining intensity. More important are the positivity rate and the distribution pattern of positive cells. A single strongly positive cell is not necessarily more informative than a broad region with moderate positivity. If signals are concentrated in a specific treatment group and show a stable distribution pattern, even moderate signal intensity may have substantial interpretive value.

Common quantitative indices include:

(1) Number of TUNEL-positive cells / total number of cells.

(2) TUNEL-positive area / target tissue area.

The former is more suitable for cell experiments and tissues with clearly defined cell boundaries, whereas the latter is more suitable for samples with extensive necrotic background, indistinct cell borders, or tissue-level comparisons.

 

4.3 Tissue distribution pattern

TUNEL interpretation cannot be separated from histologic context. Apoptosis commonly appears as scattered or focal nuclear positivity. In contrast, broad diffuse positivity across an entire necrotic region more often suggests necrosis or severe DNA destruction rather than a simple increase in apoptosis. In tumors, ischemic injury, neural tissues, and inflammatory tissues, spatial distribution is often more informative than total positivity alone.


Table 2. Interpretive framework for TUNEL-positive signals

 

Interpretive dimension

Features supporting an apoptotic interpretation

Features requiring caution

Localization

Clear intranuclear signal colocalizing with nuclear stain

Diffuse signal in cytoplasm, extracellular space, clefts, or necrotic regions

Morphology

Nuclear pyknosis, nuclear fragmentation, focal positivity

Structural collapse and broad intense positivity without clear boundaries

Distribution

Scattered, clustered, or region-specific increase associated with treatment

Random increase across the entire section or concentration at edge artifacts

Controls

Low background in the negative control and normal response in the positive control

Elevated signal in the negative control itself or failure of the positive control

Consistency

Concordant with H&E morphology and apoptotic markers

Overlap with necrosis, mechanical injury, or processing artifacts

 

5. Common Sources of Misinterpretation and Experimental Pitfalls

5.1 Directly equating DNA fragmentation with apoptosis

This is the most common interpretive error in TUNEL analysis. TUNEL detects DNA break termini rather than the apoptotic pathway itself. DNA damage, necrosis, tissue injury, and processing artifacts may all produce positive signals.

 

5.2 Misinterpretation of necrotic regions

Necrotic areas often contain abundant fragmented DNA and nuclear debris and therefore commonly exhibit extensive high-intensity signals. Without reference to H&E staining or tissue morphology, these signals are easily misinterpreted as markedly increased apoptosis.

 

5.3 Misinterpretation of edge artifacts

Section edges, folded regions, knife marks, and detached boundaries are more prone to artifactual high background. If these signals appear in all groups and are concentrated at the edges, they should generally be excluded from quantification.

 

5.4 Over-quantification

TUNEL is often oversimplified as “more positivity means stronger apoptosis.” This statement is not rigorous. Depending on tissue type, time point, and injury model, elevated TUNEL signals may reflect enhanced early apoptosis, late secondary necrosis, or progression of tissue damage, and their biologic meaning is not uniform.

 

6. Integrated Interpretation of TUNEL with Other Indicators

6.1 Integration with morphology

H&E staining, DAPI/Hoechst nuclear labeling, and ultrastructural observation provide an essential basis for interpreting TUNEL results. If TUNEL positivity is consistent with nuclear pyknosis, fragmentation, and apoptotic body formation, interpretation becomes more robust.

 

6.2 Integration with apoptotic pathway markers

When combined with cleaved caspase-3, cleaved PARP, BAX/BCL-2, cytochrome c release, and related indicators, TUNEL more readily supports an evidence chain linking DNA fragmentation to activation of apoptotic pathways. If TUNEL positivity is increased while caspase-dependent markers remain unchanged, noncanonical cell death pathways or processing artifacts should be considered.

 

6.3 Integration with time-course analysis

In apoptosis studies, time points are often more important than a single endpoint. If sampling is too early, TUNEL signals may not yet be obvious; if sampling is too late, apoptotic cells may already have been cleared or may have progressed to secondary necrosis. Establishing a time-course framework makes it easier to relate TUNEL results to injury, repair, or treatment effects.


Table 3. Common combinations for integrated interpretation of TUNEL

 

Combined marker

Main purpose

Interpretive value

H&E morphology

Distinguish apoptotic from necrotic background

Provides histologic context

DAPI/Hoechst

Define nuclear localization and nuclear morphology

Improves single-cell interpretive accuracy

Cleaved caspase-3

Verify activation of apoptotic pathways

Strengthens mechanistic interpretation

Annexin V

Complement early apoptotic information

Compensates for the temporal limitation of TUNEL

Ki-67/proliferation markers

Analyze the balance between proliferation and apoptosis

Improves interpretation of tissue dynamics

 

7. Interpretive Priorities in Different Experimental Scenarios

7.1 Cell experiments

In cell-based models, interpretation of TUNEL should focus on single-cell nuclear signals, positivity rate, and treatment-time dependence. Result descriptions should preferably use expressions such as “the proportion of TUNEL-positive cells increased” or “intranuclear fragmentation signals were enhanced.”

 

7.2 Tissue injury models

In ischemia-reperfusion, inflammatory injury, neurodegenerative models, and drug-toxicity models, TUNEL signals often coexist with necrosis and inflammatory cell infiltration. In these samples, interpretation should emphasize the regional localization of positive cells, cell type identity, and the spatial relationship to necrotic areas.

 

7.3 Tumor studies

In tumor samples, TUNEL may reflect therapy-induced apoptosis, but may also be associated with central tumor necrosis, treatment-related DNA damage, or hypoxic microenvironments. In tumor research, TUNEL interpretation should be integrated with recognition of necrotic areas, stratification of tumor edge versus central regions, and proliferation markers.

 

8. Recommended Wording for Experimental Results

8.1 Appropriate expressions for the Results section

Result descriptions should focus on localization, proportion, distribution, and intergroup differences. For example:

(1) The proportion of TUNEL-positive cells increased in the treatment group, with signals primarily localized within nuclei.

(2) Positive cells were concentrated at the injury margin rather than within the central necrotic core.

(3) Combined DAPI staining showed that positive cells were accompanied by nuclear pyknosis and fragmentation.

(4) The negative control showed low background, and the positive control responded adequately, indicating a stable detection system.

 

8.2 Expressions that should not be directly used in the Results section

The following statements involve excessive extrapolation and should generally be avoided:

(1) TUNEL positivity proves that the cells are definitely undergoing classical apoptosis.

(2) Increased TUNEL signal proves that a specific pathway has been activated.

(3) Expansion of the positive area alone demonstrates a stronger treatment effect.

(4) A reduction in weak positivity alone proves that a protective effect has been established.

 

9. TUNEL-Related Products

9.1 Basic reagent table for TUNEL detection

 

Name

CAS No.

Experimental step

Key use

Notes for use

Proteinase K

39450-01-6

Sample pretreatment

Improves exposure of DNA termini within tissues or nuclei and enhances accessibility of the TdT reaction

Excessive treatment may disrupt nuclear borders and increase false positivity

DNase I

9003-98-9

Positive control preparation

Artificially generates DNA break termini to verify that the TUNEL system is functioning properly

Used only for positive controls and not for interpretation of experimental groups

Hydrogen peroxide

7722-84-1

Blocking before chromogenic development

Blocks endogenous peroxidase activity in DAB-based systems and reduces tissue background

Mainly used for HRP-DAB TUNEL readout

3,3'-Diaminobenzidine (DAB)

7411-49-6

Chromogenic detection

Produces a brown chromogenic signal in HRP-based systems for tissue localization under bright-field microscopy

Excessive development can enlarge the apparent positive area

Triton X-100

9002-93-1

Permeabilization

Improves entry of TdT and labeled nucleotides into nuclei

Overpermeabilization may cause high nuclear background or nuclear structural damage

Sodium citrate

6132-04-3

Buffer preparation

Can be used for selected pretreatment steps or for establishing a buffer environment for nuclease-related reactions

Used as a supporting buffer component in the method

Formaldehyde

50-00-0

Fixation

Used for fixation of cells or tissues to preserve nuclear architecture and sample morphology

Both insufficient and excessive fixation can affect TUNEL results

Hoechst 33342

23491-52-3

Nuclear counterstaining

Used for nuclear localization and colocalization analysis in fluorescent TUNEL assays

Suitable for observing pyknosis and nuclear fragmentation

Propidium iodide (PI)

25535-16-4

Nuclear counterstaining / auxiliary damage interpretation

Used in some fluorescence systems for nuclear staining and auxiliary evaluation of cell death status

Requires distinction from the strong staining background of necrotic cells

Glycerol

56-81-5

Mounting

Used in some fluorescence mounting systems to maintain imaging stability

For long-term storage, combination with antifade systems is preferred

 

9.2 Supporting product table for TUNEL detection

 

Product category

Catalog No.

Name

Grade and purity

Suitable research use/application

Core enzyme

T1425044

Terminal deoxyribonucleotidyltransferase

Core enzyme for the TUNEL reaction, used to add labeled dUTP to DNA break termini

Core enzyme

T751007

Terminal Deoxynucleotidyl Transferase

EnzymoPure™, biologically active, ActiBioPure™, sterile, DNase- and RNase-free, 5.0 U/μL

Suitable for routine TUNEL end-labeling reactions

Core enzyme

T751008

Terminal Deoxynucleotidyl Transferase (TdT)

ActiBioPure™, biologically active, EnzymoPure™, sterile, DNase- and RNase-free, 20 U/μL

Suitable for batch processing or high-activity TdT systems

Core enzyme

T1492047

Terminal Deoxynucleotidyl Transferase (TdT, 20U/μL)

ActiBioPure™, biologically active, EnzymoPure™, DNase- and RNase-free, 20 U/μL

Suitable for high-activity end-labeling reactions in tissue sections or cell samples

Labeled substrate

B598295

Biotin dUTP (biotin dUTP)

Suitable for biotin-based TUNEL systems with subsequent streptavidin- or HRP-mediated amplification

Labeled substrate

B598358

Biotin TUNEL apoptosis Kit

Suitable for biotin-based TUNEL detection in tissue-section chromogenic workflows or amplified detection

Labeled substrate

B1454858

Biotin-11-dUTP trisodium

≥99%

Suitable for constructing biotin-based TdT end-labeling systems

Labeled substrate

B658667

Biotin-16-dUTP trisodium

≥97%

Suitable for constructing biotin-labeled TUNEL systems with longer linker length

Labeled substrate

S1451224

Sulfo-Cy3-E-dUTP

Suitable for orange-red fluorescent TUNEL detection

Labeled substrate

S598307

Sulfo-cy3-e-dutp (sulfo-cy3-ethyl-dutp)

Suitable for Cy3-channel fluorescent TUNEL labeling

Labeled substrate

S1452014

Sulfo-Cy5 dUTP

Suitable for far-red TUNEL labeling

Labeled substrate

S1450285

Sulfo-Cy5.5 dUTP

Suitable for longer-wavelength fluorescent TUNEL detection

Labeled substrate

T1427888

Tetramethylrhodamine-dUTP

Suitable for rhodamine-channel TUNEL labeling

Labeled substrate

V1451234

Vari Fluor 488-dUTP

≥99%

Suitable for green fluorescent TUNEL labeling

Labeled substrate

V1452507

Vari Fluor 555-dUTP

Suitable for orange-red fluorescent TUNEL detection

Labeled substrate

V1454207

Vari Fluor 594-dUTP

Suitable for red fluorescent TUNEL labeling

Labeled substrate

V1453078

Vari Fluor 640-dUTP

≥98%

Suitable for far-red fluorescent TUNEL labeling

Kit

T1456509

Colorimetric TUNEL Apoptosis Assay Kit

BioReagent, colorimetric method, for microscopy

Suitable for paraffin tissue sections or routine bright-field TUNEL interpretation

Kit

A598363

Aladdin ® 488 TUNEL apoptosis Kit (green fluorescence)

Suitable for green fluorescent TUNEL detection

Kit

A598361

Aladdin ® 555 TUNEL apoptosis Kit (orange red fluorescence)

Suitable for orange-red channel TUNEL detection

Kit

A598362

Aladdin ® 594 TUNEL apoptosis Kit (red fluorescence)

Suitable for red-channel TUNEL detection

Kit

A598360

Aladdin ® 640 TUNEL apoptosis Kit (far red fluorescence)

Suitable for far-red channel TUNEL detection

Mounting and imaging

A752105

Enhanced Antifade Mounting Medium

BioReagent, suitable for fluorescence analysis and immunofluorescence (IF)

Suitable for post-imaging mounting in fluorescent TUNEL assays to reduce quenching

Mounting and imaging

F598330

Fluorescent Mounting Media

Suitable for endpoint mounting of fluorescent TUNEL samples

Mounting and imaging

A598329

Antifluorescent quencher

Suitable for long-term preservation and observation of fluorescent TUNEL sections

Mounting and imaging

A752104

Antifade Mounting Medium

Suitable for mounting fluorescent TUNEL samples

Mounting and imaging

A1209180

AntiFade Mounting Medium (with DAPI)

BioReagent, suitable for immunofluorescence (IF) and immunohistochemistry (for IHC)

Suitable for direct mounting and nuclear counterstaining after fluorescent TUNEL labeling

Mounting and imaging

A1209484

AntiFade Mounting Medium (with Hoechst 33342 and PI)

BioReagent, suitable for immunohistochemistry (for IHC) and immunofluorescence (IF)

Suitable for combined observation of fluorescent TUNEL, nuclear morphology, and PI signal

Mounting and imaging

A1209301

AntiFade Mounting Medium (with Hoechst 33342)

BioReagent, suitable for immunohistochemistry (for IHC) and immunofluorescence (IF)

Suitable for combined interpretation of fluorescent TUNEL and Hoechst nuclear localization

Mounting and imaging

A1209362

AntiFade Mounting Medium (with PI)

BioReagent, suitable for immunofluorescence (IF) and immunohistochemistry (for IHC)

Suitable for combined observation of TUNEL and PI signals related to nuclear damage and late-stage cell death

Mounting and imaging

P1508975

Polyvinyl Alcohol Anti-Fluorescence Quenching Mounting Medium

Suitable for immunofluorescence (IF), BioReagent, for microscopy, suitable for fluorescence analysis

Suitable for long-term storage of fluorescent TUNEL samples and reduction of fluorescence quenching

Mounting and imaging

F1508973

Fischor Mounting Medium

BioReagent, for microscopy, suitable for immunofluorescence (IF), suitable for immunohistochemistry (for IHC)

Suitable for endpoint mounting in chromogenic TUNEL or selected fluorescent TUNEL workflows

Mounting and imaging

M292692

mounting medium

Unscented

Suitable for basic mounting after routine TUNEL imaging

Mounting and imaging

C1508971

Routine Glycerol Mounting Medium

BioReagent, for microscopy, suitable for immunofluorescence (IF), suitable for fluorescence analysis

Suitable for basic mounting of fluorescent TUNEL samples

Mounting and imaging

G1508970

Glycerol PBS Mounting Medium

BioReagent, for microscopy, suitable for immunofluorescence (IF), suitable for fluorescence analysis

Suitable for routine mounting of fluorescent TUNEL samples

Mounting and imaging

P1508974

Polyvinyl Alcohol Glycerol Mounting Medium

BioReagent, for microscopy, suitable for immunofluorescence (IF), suitable for immunohistochemistry (for IHC)

Suitable for mounting and short- to medium-term preservation of TUNEL sections

Mounting and imaging

A1508972

Gum Arabic Glycerol Mounting Medium

BioReagent, for microscopy, suitable for microbiology, immunofluorescence (IF), and immunohistochemistry (for IHC)

Suitable for mounting TUNEL samples for routine microscopic observation

 

The experimental value of the TUNEL assay lies in its ability to convert the apoptosis-associated event of DNA fragmentation into a stable and observable signal. Its interpretive difficulty arises from the fact that DNA fragmentation is not exclusive to apoptosis. A reliable TUNEL result does not depend on whether the signal is the strongest, but on whether nuclear localization is clear, morphology is concordant, controls are valid, and combined indicators support the interpretation.

 

For more related articles, please see below:

[1] Microscopic morphologic observation of apoptosis

[2] Apoptosis detection by AO staining (Amino Orange Stain)

Categories: Technical articles

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

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Cite this article

Aladdin Scientific. "Cell Apoptosis Detection by TUNEL Labeling: Signal Interpretation and Result Evaluation" Aladdin Knowledge Base, updated Apr 22, 2026. https://www.aladdinsci.com/us_en/faqs/cell-apoptosis-detection-by-tunel-labeling-en.html
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