Structural Characteristics, Operational Methods, and Separation Applications of Dextran Gels
Structural Characteristics, Operational Methods, and Separation Applications of Dextran Gels
Dextran gel is one of the most classical hydrophilic polysaccharide matrices used in gel filtration and molecular-sieving separation. Its application value lies not only in routine desalting and buffer exchange, but also in the relatively clear correspondence among crosslinked structure, swelling behavior, and pore-size distribution, which enables structural differences in the material to be translated into reproducible sieving performance. Accordingly, dextran gel should not be understood merely at the operational level of a “chromatographic packing material,” but should instead be considered systematically from the perspectives of its structural basis, specification differences, column-packing procedures, and application boundaries.
Keywords: dextran gel; gel filtration; crosslinked dextran; molecular sieving; desalting; buffer exchange; chromatographic packing material
1. Basic Concepts and Structural Basis of Dextran Gels
1.1 Material origin of dextran gels
(1) Dextran backbone
The fundamental material of dextran gel is dextran. Dextran is a hydrophilic polysaccharide composed of glucose residues and exhibits good aqueous compatibility and biocompatibility. Dextran itself is water-soluble, but after crosslinking it can form an insoluble three-dimensional network structure, thereby becoming a gel matrix suitable for chromatographic separation.
(2) Spatial network after crosslinking
After appropriate crosslinking, dextran no longer exists as a linear soluble polysaccharide, but forms a spatial network structure containing pores. This structure can both absorb water and swell, while still maintaining stable particle morphology, which is the direct structural basis for its use as a bioseparation medium. In other words, the separation performance of dextran gels does not arise solely from the material itself, but from the combined action of a hydrophilic backbone and a porous network.
1.2 Structural characteristics of dextran gels
(1) Hydrophilicity and low nonspecific adsorption
The dextran backbone is rich in hydroxyl groups and is therefore strongly hydrophilic overall. In conventional buffer systems, this property helps reduce nonspecific adsorption of biomacromolecules such as proteins, polysaccharides, and nucleic acids, so that the separation process more closely reflects size exclusion itself.
(2) Swellability
Dextran gels have a relatively small volume in the dry state. After absorbing water, the internal network gradually expands, forming a pore-channel system into which sample molecules can enter. Swelling is not merely simple water uptake, but the actual establishment of the working structure of the gel. Therefore, the pore structure of dextran gels is essentially further unfolded through hydration and swelling on the basis of crosslinking.
(3) Adjustable pore size
One of the most important structural features of dextran gels is tunable pore size. Different degrees of crosslinking correspond to different extents of network opening, thereby conferring different applicable separation ranges. When the degree of crosslinking is higher, the gel is more compact and the pore size is smaller; when the degree of crosslinking is lower, the gel exhibits greater swelling and larger pore size, making it more suitable for sieving larger molecules.
1.3 Separation principles of dextran gels
(1) Molecular-sieving effect
The basic separation principle of dextran gels is the molecular-sieving effect. Molecules with relatively larger molecular mass cannot enter, or can only partially enter, the gel pores, and therefore mainly move through the interparticle spaces and elute more rapidly. Molecules with relatively smaller molecular mass can enter more of the pore space, are retained longer, and therefore elute more slowly.
(2) Differences in effective separation volume
Dextran gels do not rely on strong adsorption or chemical binding to accomplish separation. Their essence lies in the difference in accessible internal volume available to different molecules within the stationary phase. Large molecules mainly utilize the void volume outside the gel particles, whereas small molecules utilize both the external void volume and the internal pore volume of the gel. It is precisely this difference in effective separation volume that forms the basis of gel-filtration separation.
Table 1. Major structural characteristics of dextran gels and their separation significance
Structural characteristic | Material behavior | Separation significance |
Hydrophilic backbone | Polyhydroxyl polysaccharide network | Reduces nonspecific adsorption and is suitable for aqueous systems |
Three-dimensional crosslinked structure | Forms stable particles and pores | Provides the structural basis for molecular sieving |
Swellability | Pore channels expand after hydration | Establishes effective separation volume |
Adjustable pore size | Different crosslinking degrees yield different pore sizes | Covers separation needs for different molecular sizes |
Good chemical inertness | Relatively stable in conventional buffer systems | Suitable for handling proteins, polysaccharides, nucleic acids, and related samples |
2. Classification of Dextran Gels and Interpretation of Specifications
2.1 Naming rules of the G series
(1) Meaning of the G value
Crosslinked dextran gels are usually designated in the form “G + number.” The letter G represents the crosslinked dextran gel series, and the following Arabic numeral is related to the water uptake value of the gel. It can usually be understood as ten times the grams of water absorbed per gram of dry gel. For example, G-25 indicates that each gram of dry gel absorbs about 2.5 g of water, whereas G-200 indicates about 20 g.
(2) Structural information reflected by the G value
The G value is not merely a model number, but rather a composite reflection of gel crosslinking degree, swelling degree, and internal pore openness. In general, gels with smaller G values have higher crosslinking degree and smaller pore size, whereas gels with larger G values have higher swelling degree and larger pore size. Therefore, the larger the G value, the more suitable the gel usually is for entry and fractionation of larger molecules.
2.2 G-series specifications and separation behavior
(1) Low-G-value gels
G-10, G-15, and G-25 are dextran gels with relatively small pore sizes and are more suitable for desalting, small-molecule separation, and buffer exchange. Such gels usually exert a strong exclusion effect on target biomacromolecules, allowing large molecules to elute rapidly while salts and small-molecule impurities elute later.
(2) Medium- and high-G-value gels
G-50, G-75, G-100, G-150, and G-200 have progressively larger pore sizes and are more suitable for fractionation of proteins, polysaccharides, and macromolecular complexes, as well as relative molecular-mass analysis. The application focus of these gels is no longer merely removal of small molecules, but size-based fractionation through differences in accessible pore volume.
Table 2. Comparison of G-series crosslinked dextran gels in terms of specifications and structural characteristics
Model | Water absorbed per gram of dry gel (g) | Structural characteristics | Separation characteristics | Typical uses |
G-10 | 1.0 | High crosslinking degree, very small pore size | Small molecules enter more fully, large molecules are rapidly excluded | Rapid desalting, small-molecule separation, buffer exchange |
G-15 | 1.5 | Relatively high crosslinking degree, small pore size | Suitable for separation of low-molecular-weight species from salts | Desalting, removal of free low-molecular-weight impurities |
G-25 | 2.5 | Small pore size, moderate swelling | Good desalting performance for biomacromolecules | Desalting and buffer exchange of proteins, polysaccharides, and nucleic-acid samples |
G-50 | 5.0 | Larger pore size | Suitable for fractionation of small and medium-sized proteins | Separation of small proteins, peptides, and some polysaccharides |
G-75 | 7.5 | Higher swelling degree, larger pores | Suitable for protein separation over a relatively broad range | Routine protein fractionation and purification |
G-100 | 10.0 | Further enlarged pore size | Suitable for separation of medium to relatively large proteins | Separation of protein mixtures and molecular-weight estimation |
G-150 | 15.0 | High swelling degree, large pore size | More suitable for fractionation of large-molecule samples | Separation of large proteins, glycoproteins, and complexes |
G-200 | 20.0 | Highest swelling degree, largest pore size | Suitable for entry and separation of very high-molecular-weight samples | Separation of large protein complexes, polysaccharides, and polymers |
2.3 Relationship among G value, crosslinking degree, swelling degree, and separation range
(1) G value and crosslinking degree
A smaller G value usually indicates a higher degree of crosslinking, a denser network, and smaller internal pore size. A larger G value usually indicates stronger water uptake and swelling capacity, together with more open pores.
(2) G value and application range
In practical applications, G-25 and lower specifications are commonly used for desalting and buffer exchange, whereas G-50 and above are more often used for protein fractionation and molecular-weight estimation. Therefore, selection of the G value should always be based on the relative molecular-mass range of the target molecules, rather than simply on an empirically “common model.”
3. Preparation Basis of Dextran Gels
3.1 Principles of dextran gel preparation
(1) Formation of a spatial network through crosslinking
The core of dextran gel preparation lies in transforming soluble dextran into an insoluble three-dimensional network material through crosslinking. The degree of crosslinking determines the compactness of the gel skeleton and also determines the size and uniformity of the pore channels formed after hydration.
(2) Pore structure forms jointly through crosslinking and swelling
The pore channels of dextran gels are not formed by simple mechanical perforation, but are gradually unfolded through hydration and swelling after the crosslinked skeleton has been established. Therefore, the final sieving performance of the gel depends not only on the crosslinking conditions, but also closely on the swelling conditions before use.
3.2 Key control points during preparation
(1) Raw-material purity
The purity of the dextran raw material directly affects gel uniformity. If the raw material contains excessive low-molecular-weight sugars, salts, or other impurities, this may result in uneven crosslinking, unstable particle morphology, or elevated background during subsequent elution.
(2) Crosslinking conditions
The amount of crosslinking agent, reaction time, and reaction environment determine the degree of crosslinking. If crosslinking is insufficient, the gel becomes too soft, swells excessively, and lacks adequate mechanical stability. If crosslinking is too strong, the pore size becomes too small and the effective separation range shifts markedly. Therefore, control of crosslinking is essentially a matter of balancing pore openness against skeleton stability.
(3) Particle formation and particle-size uniformity
Particle size and uniformity directly affect column-packing quality and fluid distribution. If the particle-size distribution is too broad, the packed bed is more prone to local differences in compaction and uneven flow velocity, ultimately resulting in peak broadening and lower resolution.
3.3 The concept of “preparation” in the laboratory context
(1) Narrow sense of preparation
In the narrow sense, preparation of dextran gels refers to obtaining the chromatographic matrix from dextran raw materials through processes such as crosslinking, granulation, washing, and drying.
(2) Broad sense of preparation
In actual laboratory practice, however, the more common meaning of “preparation” refers to pretreatment of ready-made dextran gels before use, including:
① swelling;
② removal of fines;
③ degassing;
④ column packing;
⑤ equilibration.
Therefore, when discussing “preparation and use methods,” the focus should usually be placed on establishment of the working state of the gel.
4. Methods for Using Dextran Gels
4.1 Pretreatment before use
(1) Swelling
Dry dextran gels usually need to be fully swollen in water or the appropriate buffer before use. The purposes include:
① fully unfolding the internal pores of the gel;
② allowing the particles to reach a stable volume;
③ preventing continued expansion after column packing that would otherwise alter the bed.
Different gel specifications require different swelling times, and the gel should be confirmed to have reached a stable volume before use.
(2) Removal of fines
After swelling, fines and suspended particles often need to be removed by decantation, sieving, or repeated washing. If too many fines remain, the packed column may exhibit elevated back pressure, local blockage within the bed, and peak broadening.
(3) Degassing
The gel suspension should preferably be degassed before column packing. If bubbles are introduced into the packed bed, they create local voids, disrupt uniform mobile-phase distribution, and cause discontinuity in the bed, thereby markedly reducing column efficiency.
4.2 Column-packing methods
(1) Wet packing
Dextran gels are usually packed by the wet-packing method. That is, a uniformly suspended gel slurry is slowly added into the chromatographic column, allowing the particles to settle naturally and gradually form a uniform packed bed. During packing, continuous liquid flow should be maintained as much as possible, and severe fluctuations of the liquid surface should be avoided.
(2) Packed-bed stabilization
After packing is completed, the bed should continue to be washed slowly with equilibration solution so that the particles become further compacted and reach a stable state. If the bed height continues to decrease markedly, this indicates that the gel has not yet settled completely, and equilibration should continue until the bed height becomes essentially stable.
(3) Evaluation of packed-bed quality
An ideal packed bed usually exhibits the following features:
① a level surface;
② no obvious cracks;
③ no bubbles or voids;
④ no obvious stratification;
⑤ stable changes in flow rate.
4.3 Equilibration and sample application
(1) Column equilibration
Before formal separation, the bed should be thoroughly equilibrated with a buffer compatible with the sample. Equilibration is used not only to replace the medium inside the column, but more importantly to allow the gel to reach a stable state under the actual ionic conditions of operation.
(2) Sample pretreatment
Before loading, samples should generally be centrifuged or filtered to remove particulate impurities and prevent bed blockage. At the same time, sample volume and viscosity should be controlled as much as possible to avoid excessive band broadening during loading, which would reduce resolution.
(3) Principles of sample loading
For gel-filtration separation, samples should generally be loaded in relatively small volumes and at moderate concentrations. If the loading volume is too large, the initial distribution zone of different components inside the column becomes significantly broadened, ultimately resulting in peak broadening and overlap of components.
4.4 Elution and fraction collection
(1) Elution mode
Dextran gels are usually operated under isocratic elution, that is, the same buffer is used continuously to drive the sample through the bed. Because the separation basis is the size-exclusion effect, separation does not usually rely on salt gradients or pH gradients.
(2) Elution order
Components with relatively larger molecular mass elute first, whereas those with relatively smaller molecular mass elute later. When dextran gels are used for desalting, the target biomacromolecule usually appears in the early elution peak, whereas salts and small-molecule impurities elute later.
(3) Fraction collection and detection
The eluate should be collected in fractions by volume, and the location of the target component should be determined using UV absorbance, conductivity, or corresponding activity assays. Protein samples are commonly monitored at 280 nm, whereas desalting experiments are often accompanied by conductivity detection to evaluate salt removal.
4.5 Regeneration and storage
(1) Regeneration of the packed bed
After use, the packed bed may be regenerated with an appropriate buffer or mild cleaning system depending on sample properties, so as to remove residual adsorbed substances and contaminants. If residual sample remains for prolonged periods, column efficiency may decline and separation reproducibility may worsen.
(2) Storage conditions
Dextran gels should generally be stored in the wet state and in an appropriate preservative system in order to prevent microbial contamination and drying-induced cracking. If stored dry for long periods, they should be fully reswollen and re-equilibrated before reuse.
Table 3. Workflow for use of dextran gels and key control points
Stage of use | Main operations | Key control points |
Pretreatment | Swelling, removal of fines, degassing | Establish a stable pore structure and reduce fines and bubbles |
Column packing | Wet packing, bed compaction | Ensure a uniform packed bed without cracks or voids |
Equilibration | Buffer equilibration | Establish a stable working ionic environment |
Sample loading | Sample clarification, volume control | Prevent blockage and avoid excessively broad sample bands |
Elution | Isocratic elution, fraction collection | Control flow rate and improve resolution |
Regeneration and storage | Cleaning, preservation, wet storage | Maintain column efficiency and stability during repeated use |
5. Major Applications of Dextran Gels
5.1 Desalting and buffer exchange
(1) Desalting of biomacromolecules
One of the most classical applications of dextran gels is rapid desalting of proteins, polysaccharides, nucleic acids, and enzyme preparations. The principle is that large target biomolecules are excluded from the gel pores and therefore elute first, whereas inorganic salts, low-molecular-weight reducing agents, and buffer components enter the gel interior and elute later.
(2) Buffer-system conversion of samples
In protein purification and enzymology experiments, samples often need to be transferred from a high-salt system to a low-salt system, or from an incompatible buffer to one required for subsequent experiments. Dextran gels can accomplish this under relatively mild conditions and are usually faster than dialysis.
5.2 Fractionation and purification of biomacromolecules
(1) Protein separation
When the target protein differs significantly in molecular size from contaminating proteins, dextran gels can be used for protein fractionation and purification. Their advantages include mild separation conditions, a clear separation principle, and relatively limited effects on native protein conformation and activity.
(2) Separation of polysaccharides and complex samples
Dextran gels are likewise suitable for preliminary size-based fractionation of polysaccharides, glycoproteins, or protein complexes. Particularly when crude extracts are complex and sample complexity must first be reduced according to size, dextran gels are often used as a front-end purification tool.
5.3 Molecular-weight estimation and homogeneity analysis
(1) Estimation of relative molecular mass
By establishing the relationship between elution volume and molecular size using known standards, it is possible to estimate the relative molecular mass of unknown samples. This application is highly useful in analysis of protein aggregation states, determination of molecular-weight ranges of polysaccharides, and studies of polymer distributions.
(2) Evaluation of sample aggregation and heterogeneity
Dextran gels can also be used to determine whether samples exhibit aggregation, degradation, or oligomer formation. If the elution peak shows marked forward shift, tailing, or multiple peaks, this often indicates size heterogeneity in the sample.
5.4 Pretreatment of biological samples and analytical support
(1) Removal of interfering small molecules
In many analytical experiments, free substrate, free dye, reducing agents, nucleotides, and other small molecules in the sample may interfere with downstream detection. Dextran gels can serve as a mild and efficient pretreatment method for removal of such low-molecular-weight background components.
(2) Intermediate conditioning step in multistep purification workflows
In practical processes, dextran gels often do not serve as the terminal high-purity separation step, but are more often used for intermediate conditioning: carrying out desalting, buffer exchange, crude fractionation, and removal of low-molecular-weight impurities, thereby creating more suitable sample conditions for subsequent ion exchange, affinity chromatography, or reversed-phase purification.
Table 4. Typical application scenarios of dextran gels
Application direction | Main objects | Core purpose |
Desalting | Proteins, polysaccharides, nucleic acids | Remove inorganic salts and low-molecular-weight impurities |
Buffer exchange | Biomacromolecular samples | Replace the system to meet downstream experimental requirements |
Fractionation and purification | Proteins, polysaccharides, complex samples | Achieve preliminary size-based separation |
Molecular-weight analysis | Standards and unknown samples | Estimate relative molecular mass and distribution |
Pretreatment | Biological samples containing interfering small molecules | Reduce sample complexity and improve detection accuracy |
6. Related Research Products
Table 5. Key CAS reagents used in dextran-gel-related research
Name | CAS No. | Experimental stage | Key use | Use notes |
Dextran | Matrix raw material/methodological research | Used as the basic polysaccharide backbone material of dextran gels for studies of gel structure, swelling behavior, and crosslinking precursors | More suitable for basic materials studies and method development | |
Blue dextran 2000 | Column-volume determination/exclusion-volume marker | Used to determine void volume of the packed bed and evaluate the external void volume and packing state of dextran-gel columns | Commonly used as a large-molecule exclusion marker | |
Sodium dihydrogen phosphate | Buffer preparation | Used to construct the buffer environment required for gel filtration and equilibration | Suitable for preparation of neutral or weakly acidic buffer systems | |
Disodium hydrogen phosphate | Buffer preparation | Used with sodium dihydrogen phosphate to establish phosphate buffer systems | Suitable for routine aqueous separation systems | |
HEPES | Buffer preparation | Suitable for constructing neutral systems with relatively stable buffering capacity for protein-sample gel filtration | Commonly used in systems requiring high pH stability | |
MES | Buffer preparation | Suitable for sample separation and equilibration under mildly acidic conditions | Suitable for certain protein or enzyme systems | |
MOPS | Buffer preparation | Suitable for construction of buffering systems near neutrality and for design of mild separation conditions | Commonly used for processing proteins and nucleic acids | |
Sodium acetate | Buffer preparation | Used with acetic acid to prepare acetate buffer systems | Suitable for sample equilibration and elution under low-pH conditions | |
Sucrose | Small-molecule removal model/sample stabilization | Used to simulate retention behavior of soluble-sugar impurities or sample stabilizers in dextran gels | Suitable for validation in desalting and buffer-exchange experiments | |
Glucose | Small-molecule removal model | Used to evaluate the separation behavior of dextran gels toward monosaccharides | Suitable as a low-molecular-weight model compound entering pores | |
Ammonium sulfate | Sample pretreatment/desalting validation | Commonly used for validating removal of high-salt background after protein precipitation | Suitable for use with protein-desalting experiments | |
Bovine serum albumin | Column-efficiency validation/molecular-weight reference | Used as a model sample in protein separation and desalting experiments | Suitable as a medium-molecular-weight standard protein | |
Ovalbumin | Molecular-weight reference | Used to establish an elution-behavior reference for proteins in the medium molecular-weight range | Suitable for combined use with other standard proteins to build calibration curves | |
Lysozyme | Molecular-weight reference | Used for calibration of separation and elution behavior in the smaller protein range | Suitable for evaluating separation ability for small and medium-sized proteins | |
Cytochrome c | Molecular-weight reference | Used to establish elution-behavior references for proteins in gel columns | Suitable for combined use with other standard proteins | |
Ribonuclease A | Molecular-weight reference | Used for calibration of elution volume in the small-protein range | Suitable for establishing fractionation models | |
Catalase | Large-protein reference | Used for evaluating separation behavior in the larger protein range | Suitable for combined range validation together with medium- and small-sized protein standards | |
Ferritin | Large-molecule separation reference | Used for evaluation of elution behavior in the high-molecular-weight protein range | Suitable for validation of separation ranges of larger-pore dextran gels | |
Vitamin B12 | Small-molecule marker | Used to validate complete entry behavior of small molecules in dextran gels | Commonly used in validation of desalting and separation boundaries |
Table 6. Product table related to dextran gels
Catalog No. | Name | Grade and Purity | Type positioning | Research direction / intended use |
Dextran Gel | 40-120 μm, separation range <1500 (globulin) | Small-molecule separation-type dextran gel | Suitable for gel filtration, desalting, and removal of low-molecular-weight impurities in lower-molecular-weight sample ranges, and can also be used to establish models of sieving behavior for small-pore dextran gels | |
Dextran Gel | 40-120 µm, ion-exchange capacity 2.0-2.6 mmol/g (dry gel) | Ion-exchange-type dextran gel | More suitable for inclusion in the context of functionalized dextran-matrix research, for comparison of size-exclusion and ion-exchange composite separation behavior, and should not be placed within the main line of simple gel filtration | |
Dextran Gel | 40-120 μm, separation range <700 (globulin) | Very-small-pore separation-type dextran gel | Suitable for smaller-molecule separation, desalting, and buffer exchange in lower-molecular-weight ranges, and can also serve as a small-pore control material for comparison of exclusion behavior among gels | |
Dextran Gel | 40-120 μm, separation range 3000-120000 (globulin) | Medium- to large-pore fractionation-type dextran gel | Suitable for gel-filtration fractionation of proteins, polysaccharides, and medium-molecular-weight samples, and can be used to illustrate the structural transition of dextran gels from desalting type to fractionation type | |
Sephadex G-50 | Medium | G-50 medium-particle fractionation type | Suitable for routine fractionation and purification of small and medium-sized proteins, peptides, and some polysaccharides, and is a representative entry illustrating the correspondence between G-series structure and application | |
Cross-linked dextran G 150 | — | G-150 large-pore fractionation type | Suitable for separation of relatively large proteins, glycoproteins, and complex samples, and can be used to illustrate the high swelling degree and large-pore structural features of high-G-value gels | |
Cross-linked dextran G 200 | — | G-200 very-large-pore fractionation type | Suitable for separation of higher-molecular-weight samples, protein complexes, and polymer samples, and appropriate for exemplifying the application boundary of large-pore dextran gels | |
Sephadex® G-100 | Medium | G-100 medium-particle fractionation type | Suitable for routine protein fractionation and relative molecular-weight estimation, and can serve as an intermediate specification between G-75 and G-150 | |
Sephadex® G-100 | BioReagent, DNA grade, molecular biology grade, medium | G-100 molecular-biology grade | Suitable for separation and desalting of nucleic-acid- and DNA-related samples and for molecular-biology pretreatment, illustrating the extended application of dextran gels in molecular-biology systems | |
Sephadex® G-100 | Superfine | G-100 high-resolution type | Suitable for protein separation and analytical gel-filtration experiments requiring higher resolution, and can be used to illustrate the influence of particle grade on column efficiency | |
Diethylaminoethyl Sephadex A25 | — | DEAE-functionalized dextran gel | More suitable for inclusion in the context of functionalized dextran derivatives, illustrating that dextran can serve not only as a sieving medium but also as an ion-exchange medium after derivatization | |
Sephadex G-25 | BioReagent, coarse | G-25 coarse-particle desalting type | Suitable for rapid desalting and pretreatment of large-volume samples, with greater emphasis on throughput and operational convenience | |
Sephadex G-25 | BioReagent, fine | G-25 fine-particle desalting type | Suitable for applications requiring desalting together with a certain level of resolution, and useful for comparing the effects of particle grade on column efficiency and flow rate | |
Sephadex G-25 | BioReagent, medium particle | G-25 medium-particle desalting type | Suitable for routine desalting and buffer exchange of proteins, polysaccharides, and nucleic-acid samples, and one of the most typical dextran-gel entries for desalting applications | |
Sephadex G-75 | Medium particle | G-75 medium-pore fractionation type | Suitable for routine fractionation and purification of proteins over a relatively broad range, and can serve as a representative model between G-50 and G-100 | |
Sephadex® G-50 | Superfine | G-50 high-resolution type | Suitable for higher-resolution fractionation of small and medium-sized proteins, and also useful for illustrating that finer particles usually improve column efficiency while increasing flow resistance | |
Sephadex G-50 | BioReagent, DNA grade, molecular biology grade, medium | G-50 molecular-biology grade | Suitable for molecular-biology sample pretreatment, desalting of nucleic-acid-related samples, and separations in the small- to medium-molecular-weight range | |
Sephadex G-50 | BioReagent, DNA grade, molecular biology grade, fine | G-50 fine-particle molecular-biology grade | Suitable for molecular-biology applications requiring both relatively high resolution and good sample compatibility | |
Sephadex G-50 | Fine | G-50 fine-particle fractionation type | Suitable for refined fractionation of routine protein samples, and can be listed together with Medium and Superfine grades to illustrate the effect of particle grade on application scenarios |
Overall, the application value of dextran gels does not lie merely in their ability to perform gel filtration, but in their integration of desalting, buffer exchange, fractionation and purification, and molecular-weight analysis within one stable hydrophilic porous material system. The key to understanding their use lies not in simply memorizing model numbers and operating steps, but in accurately grasping the correspondence among matrix structure, pore characteristics, separation principles, and operational control points.
