Technical articles

Mitochondrial Isolation: Major Methods, Applicability Boundaries, and Quality Control

Mitochondrial isolation is a fundamental step in metabolic analysis, apoptosis research, drug toxicity evaluation, and studies of mitochondrial nucleic acids and proteomics. Its real criterion of success is not whether a pellet is obtained, but whether the resulting fraction simultaneously meets the requirements for purity, structural integrity, and functional preservation. Differential centrifugation, density gradient centrifugation, and magnetic bead/affinity-based isolation each correspond to different experimental goals and should be selected according to sample characteristics and downstream applications.

 

Keywords: mitochondrial isolation; differential centrifugation; density gradient centrifugation; magnetic bead separation; mitochondrial purification; mitochondrial integrity; quality control

 

1. Technical Targets and Experimental Significance of Mitochondrial Isolation

1.1 Technical targets

(1) Mitochondria are not uniform particles

In mitochondrial isolation experiments, the true technical target is not an abstract entity called “mitochondria,” but rather mitochondrial populations existing in different metabolic states, with different degrees of membrane integrity and different morphological backgrounds. In different tissues, different cell types, and under different treatment conditions, mitochondria vary substantially in size, density, membrane fragility, cristae structure, and their associations with other organelles. Therefore, mitochondrial isolation is not a single template-based operation, but an experimental process that must be adapted to sample properties.

(2) Downstream applications determine the isolation standard

If the sample is intended for Western blotting or routine protein detection, the main emphasis is usually on enrichment of mitochondrial components. If the sample is intended for oxygen consumption analysis, membrane potential measurement, mPTP opening, calcium uptake, respiratory chain activity assays, or metabolic flux studies, then enrichment alone is insufficient; preservation of outer and inner membrane integrity, maintenance of coupling status, and minimization of cytosolic contamination are also required. Therefore, mitochondrial isolation quality cannot be evaluated independently of the downstream experiment.

 

1.2 Significance of application

(1) Metabolic research

Mitochondria are the core site of the tricarboxylic acid cycle and oxidative phosphorylation. By isolating mitochondria and measuring ATP generation efficiency, respiratory chain activity, and key enzyme activities, researchers can obtain direct functional readouts for studies of diabetes, obesity, metabolic syndrome, and related conditions.

(2) Cell apoptosis and stress pathway research

Mitochondria participate in cytochrome c release, membrane potential changes, ROS accumulation, and mPTP opening. Analyzing isolated mitochondria helps establish experimental models for apoptosis, oxidative stress, and damage signaling pathways.

(3) Drug screening and toxicity evaluation

Many drugs affect mitochondrial function by inhibiting the respiratory chain, disrupting membrane potential, increasing ROS, or damaging mtDNA. Measurement of oxygen consumption, membrane potential, and related enzyme activities after mitochondrial isolation helps assess mitochondrial toxicity and mechanism of action.

(4) Mitochondrial nucleic acid and proteomics research

mtDNA, mitochondrial RNA, and mitochondrial protein complexes all have independent research value. High-quality mitochondrial isolation is a prerequisite for mtDNA sequencing, mitochondrial transcription analysis, and proteomic studies.

 

2. Basic Principles of Mitochondrial Isolation

2.1 Isolation logic

(1) Separation based on physical differences among organelles

The core principle of traditional mitochondrial isolation is to exploit differences among organelles in size, density, sedimentation behavior, and buoyant density, and then achieve separation stepwise through mechanical disruption, differential centrifugation, and density gradient purification.

(2) The isolation process generally contains at least three levels

Mitochondrial isolation is not achieved simply by “one centrifugation step.” It usually includes three levels: ① releasing mitochondria while minimizing membrane damage; ② removing nuclei, unbroken cells, and large debris to obtain a crude mitochondrial fraction; ③ further washing, refining, or specifically enriching the fraction according to experimental needs.

 

2.2 Core evaluation parameters

(1) Purity

This refers to whether the obtained fraction consists predominantly of mitochondrial components while minimizing contamination from endoplasmic reticulum, lysosomes, peroxisomes, plasma membrane, and cytosol.

(2) Integrity

This refers to whether the outer and inner mitochondrial membranes remain intact during isolation. For functional studies, integrity is often more important than yield.

(3) Recovery

This refers to the degree to which mitochondria are retained during the isolation process. High-purity methods are often accompanied by reduced recovery, so purity and recovery usually involve a methodological trade-off.

(4) Functional preservation

This refers to whether isolated mitochondria still retain respiratory activity, membrane potential, enzyme activity, and ion homeostasis. If the sample is intended for functional experiments, a visible pellet or enrichment of marker proteins alone is not sufficient.

 

3. Differential Centrifugation

3.1 Principle of the method

(1) Stepwise separation based on sedimentation rate

Differential centrifugation uses different centrifugal speeds and durations to sequentially separate nuclei, unbroken cells, large debris, mitochondria, and other smaller organelles. Its logic is not to obtain highly purified mitochondria in a single step, but to progressively enrich them through multiple centrifugation conditions.

(2) The principal method for crude mitochondrial extraction

Differential centrifugation is the most universal and fundamental method for mitochondrial isolation. Whether or not density gradient purification is subsequently used, differential centrifugation is typically the prerequisite step.

 

3.2 Operational workflow and control points

(1) Sample preparation

Fresh viable cells or fresh tissues are preferred. Freeze-thaw cycles easily damage mitochondrial membranes and are particularly unsuitable for downstream respiration, membrane potential, and mPTP experiments. All procedures should be performed as far as possible at 4°C to reduce protease activity and functional loss caused by ongoing metabolism.

(2) Hypotonic swelling and homogenization

For most cultured cells, cells may first be resuspended in hypotonic buffer to induce moderate swelling, followed by mechanical disruption with a homogenizer. The purpose of hypotonic treatment is to reduce the shear force required for homogenization, not to directly lyse the cells. Homogenization should be performed in stages, and the extent of breakage should be checked microscopically. Ideally, most cells should be disrupted while a small proportion remain incompletely broken, to avoid excessive shearing that damages the mitochondrial outer membrane.

(3) Restoration of isotonic conditions

After hypotonic swelling and homogenization, a concentrated isotonic buffer should be added promptly to restore osmotic stability and prevent mitochondrial swelling and membrane rupture caused by prolonged hypotonic exposure. After isotonicity is restored, the total volume is adjusted with 1× isotonic buffer before centrifugation.

(4) Low-speed centrifugation to remove large particles

A low-speed centrifugation step is first used to remove nuclei, unbroken cells, and large debris. The pellet is generally discarded, and the supernatant is transferred to a new tube. Depending on the degree of cell disruption, this step may be repeated one or two times to improve the purity of the crude mitochondrial fraction.

(5) Medium-to-high-speed centrifugation to sediment mitochondria

The supernatant is then subjected to medium-to-high-speed centrifugation, during which mitochondria sediment and form a crude pellet. This pellet is usually a mitochondria-enriched fraction but may still contain some endoplasmic reticulum, lysosomes, and membrane fragments.

(6) Resuspension and washing

The crude pellet should be gently resuspended in isotonic buffer, followed by one or two additional medium-to-high-speed wash centrifugation steps to reduce cytosolic proteins, small molecules, and nonspecific co-sedimenting contaminants. Vigorous shaking or harsh pipetting should be avoided during resuspension, otherwise mitochondrial structure may be further damaged.

 

3.3 Method characteristics and suitable applications

(1) Advantages

The major advantages of differential centrifugation are strong general applicability, relatively simple operation, larger sample throughput, and low dependence on specialized instruments. It is suitable for most cultured cells and routine tissue samples, as well as for most protein analyses and some routine functional experiments.

(2) Limitations

This method generally yields only a crude mitochondrial fraction with limited purity. If the sample contains abundant endoplasmic reticulum, lysosomes, or membrane fragments, these may co-sediment and interfere with high-precision metabolic and omics experiments.

 

4. Density Gradient Centrifugation

4.1 Principle of the method

(1) Further purification based on buoyant density differences

Density gradient centrifugation is usually performed after crude mitochondria have been obtained by differential centrifugation. By establishing a sucrose, Percoll, or other gradient medium, mitochondria and other organelles can be further separated according to differences in buoyant density. The point is not simply “another centrifugation step,” but the use of different equilibrium positions within the gradient to achieve higher purity.

(2) Essentially a refinement step

Density gradient centrifugation is rarely used alone as the starting isolation method. More commonly, it serves as a purification step after differential centrifugation to reduce contaminants in crude mitochondrial preparations.

 

4.2 Operational workflow and control points

(1) Obtaining the crude mitochondrial fraction

A crude mitochondrial pellet is first obtained by differential centrifugation and then gently resuspended in an appropriate buffer. The quality of resuspension directly affects loading uniformity and gradient separation quality.

(2) Gradient preparation and sample loading

Depending on the experimental goal, a sucrose gradient or Percoll gradient is prepared. The purpose of the gradient is to create a continuous or layered low-to-high-density environment so that different organelles settle at different positions after centrifugation. During loading, the sample should be added slowly to avoid disturbing the gradient interface.

(3) High-speed centrifugation for stratification

Under relatively high centrifugal force, mitochondria migrate to the position matching their buoyant density, while lighter or heavier contaminating organelles remain at other layers. After centrifugation, distinct layers or interfaces can usually be observed.

(4) Recovery and washing of the target layer

After the mitochondria-enriched layer is collected, it should be washed with isotonic buffer to remove residual gradient medium. If Percoll or high-concentration sucrose is not adequately removed, downstream respiratory or enzymatic assays may be affected.

 

4.3 Method characteristics and suitable applications

(1) Advantages

The major advantage of density gradient centrifugation is high purity. It can significantly reduce contamination from endoplasmic reticulum, lysosomes, and membrane fragments, making it more valuable for proteomics, lipidomics, respiratory chain complex analysis, metabolomics, and high-precision functional experiments.

(2) Limitations

This method is more time-consuming, prolongs sample handling, and often gives lower recovery than differential centrifugation alone. In addition, gradient preparation and recovery require high operational consistency. Improper handling may reduce mitochondrial function.

 

5. Magnetic Bead and Affinity-Based Isolation

5.1 Principle of the method

(1) Enrichment based on specific recognition of membrane proteins

Magnetic bead or affinity-based isolation generally uses antibodies, ligands, or tagged systems directed against mitochondrial outer membrane proteins to specifically capture mitochondria, which are then eluted or used directly in downstream analysis. This method does not rely on sedimentation speed, but on molecular recognition.

(2) Specificity rather than physical stratification is the core

Unlike differential or density gradient centrifugation, magnetic bead isolation emphasizes selective capture. It therefore has unique value for low-input samples, specific mitochondrial subpopulations, or experimental settings that require rapid processing.

 

5.2 Operational workflow and control points

(1) Mild sample lysis

To ensure that outer membrane targets remain accessible for recognition, lysis conditions are usually milder than in standard homogenization, to avoid severe outer membrane damage.

(2) Binding to magnetic beads or affinity matrices

After lysis, the sample is incubated with magnetic beads or affinity materials carrying specific recognition molecules, allowing mitochondria to bind. Incubation conditions must balance binding efficiency with preservation of mitochondrial integrity; overly long incubation may reduce function.

(3) Magnetic separation or elution

A magnetic field or affinity elution condition is then used to separate target mitochondria from the mixed fraction. If the sample is intended for protein detection, analysis may proceed while mitochondria remain bound to the beads; if intended for functional assays, it is necessary to evaluate whether the elution process affects mitochondrial status.

 

5.3 Method characteristics and suitable applications

(1) Advantages

This method is suitable for low-input samples and for certain experimental designs requiring rapid enrichment with high specificity. For research on particular mitochondrial subpopulations, its selectivity is superior to conventional differential centrifugation.

(2) Limitations

Magnetic bead isolation is expensive, low-yield, and highly dependent on antibody quality and membrane protein accessibility. In addition, some capture systems may affect outer membrane status and may therefore not be suitable for all respiration- and membrane-related experiments.


Table 1. Comparison of the main methods for mitochondrial isolation

 

Isolation method

Core principle

Advantages

Limitations

Suitable applications

Differential centrifugation

Differences in sedimentation rate

Simple operation, high sample throughput

Limited purity, prone to organelle co-sedimentation

Routine protein detection, crude functional analysis

Density gradient centrifugation

Differences in buoyant density

Higher purity, lower contamination

Longer procedure, reduced recovery

Refined functional studies, proteomics

Magnetic bead/affinity isolation

Targeted capture

High specificity, suitable for small samples

High cost, low yield

Specific subpopulation enrichment, rapid analysis

 

6. Quality Evaluation and Experimental Interpretation

6.1 Purity evaluation

(1) Protein marker detection

If the sample is intended for Western blotting, mitochondrial marker proteins and cytoplasmic proteins should be examined simultaneously to evaluate isolation quality. Mitochondrial markers may include VDAC1, COX IV, and DLAT; cytosolic contamination may be assessed using GAPDH, Tubulin, β-actin, and related markers. The most informative result is not simply “mitochondrial proteins were detected,” but rather “mitochondrial markers are enriched while cytoplasmic markers are substantially reduced.”

(2) Nucleic acid marker detection

If the sample is used for nucleic acid studies, qPCR can be used to measure high-abundance and relatively stable mitochondrial RNA or mtDNA targets, such as 12S rRNA, mt-ND1, and mt-ND4, to evaluate mitochondrial nucleic acid enrichment.

 

6.2 Integrity and functional evaluation

(1) Membrane integrity

If downstream experiments involve membrane potential, mPTP, cytochrome c release, or calcium homeostasis, it is essential to determine whether the mitochondria retain intact membrane structure. Protein enrichment alone cannot demonstrate preservation of membrane function.

(2) Functional state

If the sample is used for metabolic research or drug toxicity evaluation, oxygen consumption, ATP generation, membrane potential, or key enzyme activities should also be assessed. Otherwise, even if a mitochondrial pellet is obtained, it remains unclear whether physiologically relevant function has been preserved.

 

6.3 Common problems and interpretation

(1) Large pellet but poor function

This usually suggests co-sedimentation of contaminants or excessive homogenization-induced mitochondrial damage. In such cases, purity and membrane integrity should be checked first rather than using pellet amount as the success criterion.

(2) Positive mitochondrial markers but strong cytoplasmic contamination

This indicates that mitochondria have indeed been enriched, but the isolation is impure. In such cases, the priority should be to optimize low-speed clearing and wash steps rather than simply increasing the final sedimentation force.

(3) High purity but insufficient yield

This is commonly seen when gradient purification conditions are too stringent or when starting material is limited. Whether such high purity is necessary should be judged according to downstream needs, or the strategy should be adjusted toward higher recovery.


Table 2. Common abnormalities in mitochondrial isolation experiments and their interpretation

 

Abnormal finding

Common cause

First priority for evaluation

Large pellet but poor function

Co-sedimented contaminants, excessive homogenization

Check purity and membrane integrity first

High mitochondrial markers but also high cytoplasmic proteins

Impure isolation

Prioritize optimization of low-speed clearing and wash steps

Low recovery

Insufficient homogenization, weak centrifugation conditions

Optimize release and sedimentation conditions first

High purity but low total yield

Overly stringent gradient or low starting material

Judge whether it meets downstream experimental needs

Large batch-to-batch variation

Inconsistent sample handling, poor temperature control

Standardize pre-processing workflow first

 

7. Related Research Products

Table 3. Products related to mitochondrial isolation and quality control

 

Catalog No.

Name

Grade and Purity

Corresponding step

Suitable research applications / use

M752149

Mitochondria Isolation Reagent

Isolation and extraction

Suitable for crude mitochondrial extraction and pre-processing before differential centrifugation; used as a basic reagent for mitochondrial isolation

C777612

Cell Mitochondria Isolation Kit

BioReagent, for polyacrylamide gel electrophoresis, for protein analysis, for western blot, 50–100T

Isolation and extraction

Suitable for mitochondrial isolation from cultured cells, especially for downstream Western blot and protein enrichment analysis

O1509533

Tissue Mitochondria Isolation Kit

BioReagent, for polyacrylamide gel electrophoresis, for protein analysis, for western blot

Isolation and extraction

Suitable for mitochondrial isolation and protein analysis from liver, brain, heart, skeletal muscle, and other tissue samples

M752148

Mitochondria Storage Buffer

Post-isolation preservation

Suitable for short-term suspension, transport, and state maintenance of isolated mitochondria before downstream experiments

M1515822

Mitochondrial complex I Activity Assay Kit (Micro Method)

BioReagent

Functional quality control

Used to evaluate preservation of Complex I activity and respiratory chain function after isolation

M1515823

Mitochondrial complexⅡ Activity Assay Kit (Micro Method)

BioReagent

Functional quality control

Used to analyze Complex II activity and assess electron transport function in isolated samples

M1515824

Mitochondrial complex Ⅲ Activity Assay Kit (Micro Method)

BioReagent

Functional quality control

Used to evaluate Complex III activity; suitable for post-isolation respiratory chain integrity analysis

M1515825

Mitochondrial complex Ⅳ Activity Assay Kit (Micro Method)

BioReagent

Functional quality control

Used to evaluate Complex IV activity; suitable for oxidative phosphorylation terminal function analysis

M1515826

Mitochondrial complex Ⅴ Activity Assay Kit (Micro Method)

BioReagent

Functional quality control

Used to analyze ATP synthase-related function and evaluate coupling status in isolated mitochondria

M1515806

Mitochondrial Malate Dehydrogenase(mMDH) Activity Assay Kit (UV Micro Method)

BioReagent

Metabolic enzyme activity evaluation

Used to evaluate mitochondrial matrix enzyme activity and preservation of metabolic function after isolation

M1515936

Mitochondrial Malate Dehydrogenase (mMDH) Activity Assay Kit (UV Colorimetric Method)

BioReagent

Metabolic enzyme activity evaluation

Suitable for post-isolation mitochondrial metabolic enzyme activity testing, as an auxiliary indicator of functional preservation

M1492773

Mitochondrial Reactive Oxygen Species (ROS) Production Rate Assay Kit (Fluorometric Method)

BioReagent

Oxidative stress evaluation

Used to detect ROS generation rate in isolated mitochondria and assess sample damage and oxidative status

M1505999

Mitochondrial Membrane Potential Assay Kit (Rhodamine 123)

BioReagent, for cell culture, sterile

Membrane integrity evaluation

Used to detect membrane potential in isolated mitochondria and evaluate inner membrane function and coupling status

M273063

Mitochondrial Membrane Potential Detection Kit (JC-1)

Membrane integrity evaluation

Suitable for membrane potential detection in isolated mitochondria; used as an indicator of integrity and functional state

M1509036

Mitochondrial Membrane Potential Assay Kit (JC-10)

BioReagent

Membrane integrity evaluation

Suitable for quantitative membrane potential detection in isolated mitochondria and complementary use with JC-1 systems

J125134

JC-1

≥95%

Membrane potential detection

Suitable for self-built membrane potential assay systems and inner membrane state analysis of isolated mitochondria

J141206

JC-10

≥95%

Membrane potential detection

Suitable for fluorescence-based membrane potential detection in isolated mitochondria and functional state verification

D598353

DASPEI mitochondrial fluorescent probe

≥95%

Staining and visualization

Suitable for fluorescent labeling of mitochondria and auxiliary observation of morphology/localization after isolation

A1456401

Mitochondrion Red Probe (AIE)

BioReagent, for microscope, biological stain, ≥98%(HPLC), 50 mM in DMSO

Staining and visualization

Suitable for mitochondrial staining and auxiliary imaging comparison of mitochondrial status before and after isolation

M748085

Mito-Tracker Far-Red

BioReagent, ≥95%

Staining and visualization

Suitable for far-red mitochondrial staining and auxiliary analysis of mitochondrial enrichment and distribution

M288856

MitoScene™ Green I

Staining and visualization

Suitable for green fluorescent labeling of mitochondria and imaging-based evaluation in isolated or cellular samples

M1455273

Mito-FerroGreen

Post-isolation state evaluation

Used to detect mitochondrial iron status and suitable for combination with metabolic and oxidative stress studies

EJ1514537

Human Mitochondrial Import Receptor Subunit TOM70 (TOMM70A) ELISA Kit

BioReagent

Purity/enrichment evaluation

Used for quantitative analysis of the mitochondrial outer membrane marker TOMM70A in human samples to assist evaluation of mitochondrial enrichment

EJ1514544

Human Transcription Factor A, Mitochondrial (TFAM) ELISA Kit

BioReagent

Purity/mitochondrial content evaluation

Suitable for evaluating mitochondrial content and mitochondrial nucleic acid maintenance status in human samples

EJ1512213

Rat Transcription Factor A, Mitochondrial (TFAM) ELISA Kit

BioReagent

Purity/mitochondrial content evaluation

Suitable for evaluation of mitochondrial content after isolation in rat samples

EJ1513025

Mouse Transcription Factor A, Mitochondrial (TFAM) ELISA Kit

BioReagent

Purity/mitochondrial content evaluation

Suitable for evaluation of mitochondrial enrichment and mitochondrial quality state in mouse samples

 

Table 4. Products related to evaluation of mitochondrial isolation purity and contamination

 

Catalog No.

Name

Grade and Purity

Marker category

Use in mitochondrial isolation

Ab133998

VDAC1/Porin Antibody

ExactAb™, validated, recombinant, see COA

Mitochondrial outer membrane positive marker

Suitable for Western blot detection of the outer membrane protein VDAC1 to determine whether mitochondrial components have been successfully enriched

EJ1514323

Human Voltage-dependent Anion-selective Channel 1 (VDAC1) ELISA Kit

BioReagent

Mitochondrial outer membrane positive marker

Suitable for quantitative detection of VDAC1 in human samples as an auxiliary indicator of mitochondrial content and enrichment efficiency

EJ1512132

Rat Voltage-dependent Anion-selective Channel 1 (VDAC1) ELISA Kit

BioReagent

Mitochondrial outer membrane positive marker

Suitable for quantitative analysis of VDAC1 in rat samples to assist evaluation of mitochondrial isolation quality

EJ1512893

Mouse Voltage-dependent Anion-selective Channel 1 (VDAC1) ELISA Kit

BioReagent

Mitochondrial outer membrane positive marker

Suitable for quantitative analysis of outer membrane markers in mouse samples

Ab097414

COX IV Mouse mAb

ExactAb™, Validated, 2.0 mg/mL

Mitochondrial inner membrane positive marker

Suitable for detection of the inner membrane protein COX IV and can be used together with VDAC1 to assess mitochondrial isolation purity

Ab219243

COX IV Mouse mAb (HRP)

ExactAb™, validated, high performance, 0.5 mg/mL

Mitochondrial inner membrane positive marker

Suitable for direct HRP-based detection and rapid validation of mitochondrial marker proteins

Ab097410

Recombinant COX IV Antibody

ExactAb™, Validated, Recombinant, High performance, 0.5 mg/mL

Mitochondrial inner membrane positive marker

Suitable for validation of inner membrane markers and repeated detection of isolated samples with high consistency

Ab179920

GAPDH Mouse mAb

Carrier-free, ExactAb™, azide-free, validated, high performance, see COA

Cytoplasmic contamination negative marker

Suitable for assessing whether cytoplasmic components are mixed into the isolated sample; obvious GAPDH signal in the mitochondrial fraction suggests impurity

Ab219251

GAPDH Mouse mAb (HRP)

ExactAb™, validated, 0.5 mg/mL

Cytoplasmic contamination negative marker

Suitable for HRP-based rapid evaluation of cytoplasmic contamination

Ab091004

beta Actin Antibody

ExactAb™, Validated, Azide Free, High performance, 1.0 mg/mL

Cytoplasmic/cytoskeletal contamination negative marker

Suitable for determining whether obvious cytoplasmic and cytoskeletal components remain in the isolated sample

Ab175849

beta Actin Mouse mAb (HRP)

ExactAb™, high performance, validated, azide-free, 0.5 mg/mL

Cytoplasmic/cytoskeletal contamination negative marker

Suitable for rapid detection of β-actin contamination and comparison with mitochondrial positive markers

Ab231229

Calnexin Mouse mAb

Carrier-free, ExactAb™, azide-free, validated, high performance, ≥95%(SDS-PAGE), 0.5 mg/mL

Endoplasmic reticulum contamination negative marker

Suitable for determining whether endoplasmic reticulum components are mixed into mitochondrial samples; an important auxiliary indicator of mitochondrial purity

Ab327144

Recombinant Calnexin Antibody

Knockdown validated

Endoplasmic reticulum contamination negative marker

Suitable for Calnexin detection where higher specificity is required to identify ER co-sedimentation

Ab187900

LAMP1 Mouse mAb

Carrier-free, ExactAb™, azide-free, validated, ≥95%(SDS-PAGE), 1.0 mg/mL

Lysosomal contamination negative marker

Suitable for determining whether lysosomal contamination is present in mitochondrial fractions, especially in tissue sample quality evaluation

Ab112727

Recombinant LAMP1 Antibody

ExactAb™, Validated, recombinant, 0.2 mg/mL

Lysosomal contamination negative marker

Suitable for lysosomal contamination validation and as a complementary option to routine LAMP1 monoclonal antibodies

 

The key to mitochondrial isolation is not obtaining a pellet, but determining whether the resulting fraction truly satisfies the requirements for purity, integrity, and preserved function. Differential centrifugation, density gradient centrifugation, and magnetic bead or affinity-based isolation each have clear technical boundaries and should be chosen according to sample properties and downstream goals. Quality evaluation after isolation should simultaneously cover mitochondrial positive markers and non-mitochondrial contamination markers.

 

For more related articles, please see below:

[1] Experiments on oxidation and phosphorylation in isolated mitochondria

[2] Experiments on live staining of mitochondria in cells

[3] Experiments on the hierarchical separation of mitochondria

Categories: Technical articles

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

Products are supplied for research and development use only. Not for use in humans, animals, diagnosis, or therapy.

Cite this article

Aladdin Scientific. "Mitochondrial Isolation: Major Methods, Applicability Boundaries, and Quality Control" Aladdin Knowledge Base, updated Apr 15, 2026. https://www.aladdinsci.com/us_en/faqs/mitochondrial-isolation-major-methods-applicability-boundaries-and-quality-control-en.html
Was this article helpful? Yes No 1 out 2 found this helpful

Shall we send you a message when we have discounts available?

Remind me later

Thank you! Please check your email inbox to confirm.

Oops! Notifications are disabled.