Lignin is a phenolic polymer that provides structural rigidity to plants. Additionally, it plays many functional roles, such as protecting the plants from microbial attack and aids water and nutrient transport.

Lignin is an amorphous heterogeneous polymer of phenylpropane units: O guaiacyl (G unit), syringyl (S unit) and p-hydroxyphenyl (H unit) units derived from coniferyl alcohol, sinapyl alcohol, and p-coumaryl alcohol, respectively.

The S/G ratio represents the syringyl and guaiacyl contents of the lignin in a plant. The distribution of S and G units varies with the type of wood. Softwood contains a high amount of G units, while hardwood is generally rich in both S and G units. The average S/G ratio of pine and spruce, the commonly used softwoods as timber, are 0.02 and 0.01, respectively. White birch, a hardwood used in the paper industry, has an average S/G ratio of 2.0.

Besides the difference in the S/G ratio of plant genera, the S/G ratio also varies significantly with plant species. Growth conditions and the age of plants can also influence the S/G ratio. Significant differences in the lignin S/G ratio are observed between various plant tissues and plant cell types.

Since lignin is the major impediment in the cellulosic bioconversion process, understanding the lignin chemistry of biomass is crucial for successful delignification. S/G ratio is a significant parameter from a bioeconomy perspective, as it plays a substantial role in delignification and lignin valorisation.

Lignin S/G ratio of pretreated biomass may influence the biomass susceptibility to enzymatic action and biomass conversion. Biomass with a high lignin S/G ratio is likely to be more prone to enzymatic action.

S/G ratio of lignin may not be necessarily correlated with monomeric yield after lignin depolymerization. Choosing a microbial host and designing a bioprocess methodology for the synthesis of value-added products from lignin requires careful consideration of its S/G ratio.

Click here to place an order for determining Lignin S/G Ratio.

Quotation Free Quote

Select Another Constituent.... Caffeic acid Catechin Coumaric acid Ferulic acid Protocatechuic acid 1-Methylnaphthalene 2(5H)-Furanone 2,4-Xylenol 2-Cyclopenten-1-one 2-Methylnaphthalene 3-Hydroxy-2-butanone 3-Methyl-1,2- cyclopentanedione 3-Methyl-2(5H)-furanone 4-Ethylcatechol 4-O-Methyl-D-Glucuronic Acid 6-Benzylaminopurine a-Amylase Activity a-Amylase Hydrolysis Kinetics a-Pinene a-Terpineol Abscisic acid Acenaphthene Acenaphthylene Acetic Acid Acetol Acetosyringone Acetyl Content Acid Insoluble Residue Adjusted-Cellulose-Content Aflatoxin B1 Aflatoxin B2 Aflatoxin G1 Aflatoxin G2 Agmatine Alanine alpha-Humulene Alpha-tocopherol (vitamin E) Aluminium Ammonia Ammoniacal Nitrogen Anaerobic Toxicity Assay Antheraxanthin Anthracene Antimony Apiose Apocynin Arabinitol Arabinobiose Arabinose Arabinose in Enzyme Hydrolysate Arabinotriose Arachidic Acid Arginine Arsenic Ascorbic Acid (Vitamin C) Ash Ash (Acid Insoluble) Ash Content (815C) Ash Deformation Temperature (Oxidising) Ash Deformation Temperature (Reducing) Ash Flow Temperature (Oxidising) Ash Flow Temperature (Reducing) Ash Hemisphere Temperature (Oxidising) Ash Hemisphere Temperature (Reducing) Ash Shrinkage Starting Temperature (Oxidising) Ash Shrinkage Starting Temperature (Reducing) Aspartic Acid Astaxanthin Average Pore Width (Using CO2) Average Pore Width (Using Nitrogen) b-Glucosidase Activity b-Pinene Basic Density Behenic Acid Benzo[a]pyrene Benzo[b]fluoranthene Benzo[ghi]perylene Benzo[k]fluoranthene Benz[a]anthracene BET Isotherm (20 Point Using Carbon Dioxide) BET Isotherm (20 Point Using Nitrogen) BET Isotherm (40 Point Using Carbon Dioxide) BET Isotherm (40 Point Using Nitrogen) BET Isotherm (5 Point Using Carbon Dioxide) BET Isotherm (5 Point Using Nitrogen) Beta and Alpha Glucan beta-Carotene beta-Caryophyllene beta-Myrcene Biogas Ammonia Content Biogas Carbon Dioxide Content Biogas Hydrogen Sulphide Content Biogas Methane Content Biogas Oxygen Content Biological Oxygen Demand (BOD) Biomass Content Biomethane Potential (BMP) BJH Isotherm (20 Point Using Carbon Dioxide) BJH Isotherm (20 Point Using Nitrogen) BJH Isotherm (40 Point Using Carbon Dioxide) BJH Isotherm (40 Point Using Nitrogen) BJH Isotherm (5 Point Using Carbon Dioxide) BJH Isotherm (5 Point Using Nitrogen) Bromoform Bulk Density Butanoic Acid Butyric Acid Cadaverine Cadmium Caffeic Acid Calcium Caprylic Acid Carbon Carbon Content of Acid Insoluble Residue Carbon Dioxide Evolution Rate Catechol Cation Exchange Capacity Cellobiosan Cellobiose Cellobiose in Enzyme Hydrolysate Cellotriose Cellulase Activity Cellulose Conversion Rate Cellulose Conversion Yield Chemical Oxygen Demand (COD) Chitin Chlorine Chlorogenic Acid Chlorophyll-a Chlorophyll-b Chlorophyll-c Cholecalciferol (Vitamin D3) Cholesterol Chromium Chrysene Cobalamin (Vitamin B12) Cobalt Combined Sugar Yield Copper Creosol Crude Fibre Cystine Decanoic Acid Degree of Acetylation Degree of Esterification Dibenz[a,h]anthracene Dopamine Electrical Conductivity Endoglucanase Activity Enzymatic Hydrolysis Kinetics Ergocalciferol (Vitamin D2) Ergosterol Erucic Acid Eugenol Extractives (Ethanol-Soluble) Extractives (Exhaustive - Water then Ethanol) Extractives (Water-Insoluble, Ethanol Soluble) Extractives (Water-Soluble) Fixed Carbon Fluoranthene Fluorene Folate (Vitamin B9) Formic Acid FOS/TAC Fructose Fucose Fucoxanthin Furfural Galactosan Galactose Galactose in Enzyme Hydrolysate Galacturonic Acid Gallic acid gamma-Valerolactone Germination Inhibition Gibberellic Acid Glass & Metals & Plastics Over 2mm Glucoamylase Activity Glucoamylase Hydrolysis Kinetics Glucose Glucose in Enzyme Hydrolysate Glucuronic Acid Glutamic Acid Glycerol Glycine Glycolaldehyde Gravel & Stones Over 5mm Gross Calorific Value Guaiacol Guluronic Acid Heating Value (HHV - Calculated) Heating Value (LHV - Calculated) Histamine Histidine Hydrogen Hydrogen Content of Acid Insoluble Residue Hydroquinone Hydroxymethylfurfural Iduronic Acid Increase in Cellulose Accessibility after Pre-Treatment Indeno[1,2,3-cd]pyrene Indole-2-acetic acid Indole-3-acetic acid Indole-3-butyric acid Indole-3-propionic acid Inherent Moisture Inorganic Carbon Iron Isobutyric Acid Isoleucine Isovaleric Acid Kinetin riboside Lactic Acid Lauric Acid Lead Leucine Levoglucosan Levulinic Acid Lignin (Acid Soluble) Lignin (Klason - Protein Corrected) Lignin (Klason) Lignin S/G Ratio Lignoceric Acid Liming Limonene Linalool Linoleic Acid Linolenic Acid Lutein Lysine m-Cresol Magnesium Maltoheptaose Maltohexaose Maltol Maltooctaose Maltopentaose Maltose Maltose in Enzyme Hydrolysate Maltotetraose Maltotriose Manganese Mannitol Mannosan Mannose Mannose in Enzyme Hydrolysate Mannuronic Acid Mean Root Length (Week 4) Mean Shoot Length (Week 1) Mean Shoot Length (Week 2) Mean Shoot Length (Week 3) Mean Shoot Length (Week 4) Melibiose Mercury Methionine Methoxymethylfurfural Moisture Molecular Weight Molybdenum Myristic Acid Naphthalene Neoxanthin Net Calorific Value Niacin (Vitamin B3) Niacinamide (vitamin B3) Nickel Nitrates Nitrogen Nitrogen Content of Acid Insoluble Residue Norspermidine o-Cresol Oleic Acid Organic Carbon Organic Matter Oxygen p-cresol Palmitic Acid Palmitoleic Acid Pantothenic Acid (Vitamin B5) Particle Size Pectin Pellet Length and Diameter Percent Increase in Cellulose Conversion Efficiency Percent Increase in Cellulose Conversion Rate pH Phenanthrene Phenol Phenylalanine Phenylethylamine Phloroglucinol Phosphorus Phylloquinone (Vitamin K1) Pore Size Distribution (Using CO2) Pore Size Distribution (Using Nitrogen) Pore Volume (Using CO2) Pore Volume (Using Nitrogen) Potassium Proline Propanoic Acid Propionic Acid Protein Content of Acid Insoluble Residue Putrescine Pyrene Pyridoxine (Vitamin B6) Quercetin Raffinose Residual Biogas Potential (RBP) Retinol (Vitamin A) Retinol Acetate (Vitamin A Acetate) Rhamnose Rhamnose in Enzyme Hydrolysate Riboflavin (Vitamin B2) Root Weight (Week 4) Rutin Salicylic acid Scanning Electron Microscopy (SEM) Image Scopoletin Scopolin Serine Serotonin Sharps Over 2mm Shoot Weight (Week 4) Silicon Sludge Activity Test Sludge Granule Size Analysis Sodium Sorbitol Specific Acidogenic Potential (SAP) Specific Hydrolytic Potential (SHP) Specific Methanogenic Potential (SMP) Specific Oxygen Uptake Rate Specific Surface Area (CO2 Gas Adsorption) Specific Surface Area (Nitrogen Gas Adsorption) Spermidine Spermine Starch Stearic Acid Stigmasterol Sucrose Sulphur Sulphur Content of Acid Insoluble Residue Syringol Syringylaldehyde Thermogram - Under Air Thernogram - Under Nitrogen Thiamine (Vitamin B1) Threonine Time to Germination Tin Titanium Tocopheryl Acetate (Vitamin E Acetate) Total Biogas Volume Total Oligomeric Sugars Total Phenolics Total Phlorotannins Total Solids Total Sugars Total Sugars in Enzyme Hydrolysate Total Tannins Trehalose Tyramine Tyrosine Valeric Acid Valine Vanadium Vanillic acid Vanillin Viable Weed Seeds Violaxanthin Volatile Matter Volatile Solids Water Holding Capacity Xylan Conversion Rate Xylan Conversion Yield Xylanase Activity Xylitol Xylobiose Xylonic Acid Xylose Xylose in Enzyme Hydrolysate Xylotriose Xylulose Zeaxanthin Zinc

Analysis Packages for Lignin S/G Ratio

The Celignis Analysis Package(s) that determine this constituent are listed below:

P20   Lignin S/G Ratio
Lignin S/G Ratio Further Details

Equipment Used for Lignin S/G Ratio Analysis

Gas Chromatograph with Mass Spectrometer (GC-MS) Our lab has an Agilent 6890 gas chromatograph (GC) coupled to an Agilent 5973 mass selective detector (Mass Spectrometer).

CDS Pyroprobe 5200 We use this item, coupled to our GC/MS system, to determine the S/G ratio in lignin.

Additional Material

We can determine the Lignin S/G Ratio content of biomass, click here to learn more about our various biomass analysis methods.