Characterization of Pinus nigra var. laricio Maire bark extracts at the analytical and pilot scale

Pinus nigra var. laricio bark and its hot-water extracts (HWE) obtained at an analytical and pilot plant scale have been characterized in terms of phenolic extractives, condensed tannins (CTs), carbohydrates and inorganic compounds. Analytical extractions with aqueous acetone were also performed for comparison with HWE. The bark contains 35.5 g kg−1 CT, and two-thirds of it could be extracted. Analytical HWE at 75°C led to a total yield of 56.4 g kg−1. The extracts are mainly composed of phenolic compounds (50.7%) and pectins (19.7%). CTs amount to 17.9% of the extracts and are procyanidins with a mean degree of polymerization (DP) of about 9. Non-tannin phenolic oligomers also occurred in the extracts, which could be identified by pyrolysis gas chromatography mass spectrometry (Py-GC/MS) as lignin fragments. Matrix-assisted laser desorption/ionization-time-of-flight-mass spectrometry (MALDI-TOF MS) revealed that the CT is a flavanol derivative in methylated form. Further characterization and tailoring of the HWE properties is needed in the context of their specific application

Production and Properties of Lignin Nanoparticles from Ethanol Organosolv Liquors-Influence of Origin and Pretreatment Conditions

Despite major efforts in recent years, lignin as an abundant biopolymer is still underutilized in material applications. The production of lignin nanoparticles with improved properties through a high specific surface area enables easier applicability and higher value applications. Current precipitation processes often show poor yields, as a portion of the lignin stays in solution. In the present work, lignin was extracted from wheat straw, spruce, and beech using ethanol organosolv pretreatment at temperatures from 160–220 °C. The resulting extracts were standardized to the lowest lignin content and precipitated by solvent-shifting to produce lignin micro- and nanoparticles with mean hydrodynamic diameters from 67.8 to 1156.4 nm. Extracts, particles and supernatant were analyzed on molecular weight, revealing that large lignin molecules are precipitated while small lignin molecules stay in solution. The particles were purified by dialysis and characterized on their color and antioxidant activity, reaching ASC equivalents between 19.1 and 50.4 mg/mg. This work gives detailed insight into the precipitation process with respect to different raw materials and pretreatment severities, enabling better understanding and optimization of lignin nanoparticle precipitation

Diagnosis of quarantine organisms at the JKI in the National Reference Laboratory for organisms harmful to plants

Dem JKI wurde im April 2019 durch das Bundesministerium für Ernährung und Landwirtschaft (BMEL) die Funktion des nationalen Referenzlaboratoriums (NRL) für Schadorganismen der Pflanzen zugewiesen. Mit dieser Funktion des NRL für Deutschland sind bestimmte Zuständigkeiten und Aufgaben verbunden, die in der EU-Verordnung 2017/625 (EU, 2017) geregelt sind. Dazu gehören auch Referenzuntersuchungen bzw. die Diag­nose von Quarantäneschadorganismen (QSO). Das NRL stellt eine übergeordnete Einheit innerhalb des JKI dar. Durch insgesamt 14 Prüflabore der JKI-Institute für Pflanzenschutz in Ackerbau und Grünland (A), nationale und internationale Angelegenheiten der Pflanzengesundheit (AG), Epidemiologie und Pathogendiagnostik (EP), Pflanzenschutz in Gartenbau und Forst (GF), Pflanzenschutz in Obst- und Weinbau (OW) wird die Referenzfunktion bei der Diagnose zu verschiedensten (Quarantäne)-Schadorganismen der Pathogengruppen Bakterien, Insekten, Nematoden, Pilze (einschließlich Oomyceten), Phytoplasmen und Viren wahrgenommen.In April 2019, the JKI was officially designated as the Natio­nal Reference Laboratory (NRL) for organisms harmful to plants by the Federal Ministry of Food and Agri­culture (BMEL). This function as NRL for Germany is associated with certain responsibilities and tasks, which are specified in the EU Regulation 2017/625 (EU, 2017). This also includes reference tests and the diagnosis of quarantine pests, respectively. The NRL represents a super­ordinate unit inside JKI. A total of 14 test laboratories from different JKI institutes, namely for Plant Protection in Field Crops and Grassland (A), for National and International Plant Health (AG), for Epidemiology and Pathogen Diagnostics (EP), Plant Protection in Horti­culture and Forests (GF), and for Plant Protection in Fruit Crops and Viticulture (OW) are in charge to carry out a reference function in the diagnosis of (quarantine) pests in the pathogen groups of bacteria, fungi (including oomycetes), insects, nematodes, phytoplasma und viruses

Carbenes and nascent hydrogen for reductive derivatisation of technical lignins

Motivation: Traditional pulp and paper processes as well as emerging biorefineries generating cellulosic ethanol from lignocellulosic agricultural waste material lead to large amounts of kraft lignin and side-stream straw lignin. Both types of technical lignins, i.e., organosolv lignins and kraft lignins, offer various amounts of different functional groups, mainly aliphatic and phenolic hydroxyl groups and double bonds. Whereas the hydroxyl groups are normally used for lignin functionalisation, a more versatile type of functionalisation is obtained when leaving the hydroxyl groups intact and creating carbon-carbon bonds. Design of experiment: Lignin modification was thus performed using nascent hydrogen, as well as carbenes of varying reactivity. Exploiting the possibilities for in situ production of the reactive species, various technical lignins were subjected to standardised reactions conditions. Re-isolated modified lignin samples were subjected to GPC analysis, FTIR analysis, quantitative 31P NMR after phosphitylation, as well as quantitative {13C-1H}-HSQC analyses. Results: Molar mass distribution effects were noted in the modified lignins. In case of carbenes, detection of new, unexpected cross-peaks in the HSQC spectra area specific for newly emerging C=C bonds were observed, while other ‘typical’ lignin signals in the aromatic region underwent drastic changes. Together with unexpectedly decreased amounts of the respective free phenolic OH groups in the modified lignins, quinone-formation involving G- and H-type aromatic rings of lignins through a Reimer-Tiemann mechanism8 is postulated, among other reactions and rearrangements. In case of treatment of lignins with nascent hydrogen, structural changes lead to yet different, ‘atypical’ lignins

Cellulose Nano Crystals (CNC) as Additive for a Bio-Based Waterborne Acrylic Wood Coating: Decay, Artificial Weathering, Physical and Chemical Tests

Wood coatings prolong the service life of wood-based products, but they are usually of synthetic origin. The aim of the present article is to reduce the fossil-based compounds in a commercial waterborne acrylic coating by CNC addition and to test its performance. The coatings were applied on European beech and Norway spruce wood in order to test durability against Gloeophyllum trabeum (brown wood rot) and Trametes versicolor (white wood rot). Artificial weathering and blue stain, contact angle, physical tests (adhesion, impact and scratch test), chemical (FTIR) and morpho-anatomical analysis (SEM) were carried out. CNC addition increased viscosity, limiting the spreading of the coating into wood pores as visible after SEM observation, which reduced coating adhesion on the substrate. CNC improved fungal resistance as seen by a reduced mass loss and FTIR spectroscopy thanks to crosslinks formation, which reduced water sorption as well. Color change was not significant, and, on the other hand, glossiness was reduced but resulted as more homogeneous than control. CNC addition gave good results also in blue stain protection. CNC improved scratch resistance, but no visible change to impact was registered. CNC has promising results in coatings depending on wood and fungal species and presence of further commercial additives (biocides)

Cellulose nano crystals (CNC) as additive for a bio-based waterborne acrylic wood coating

Wood coatings prolong the service life of wood-based products, but they are usually of synthetic origin. The aim of the present article is to reduce the fossil-based compounds in a commercial waterborne acrylic coating by CNC addition and to test its performance. The coatings were applied on European beech and Norway spruce wood in order to test durability against Gloeophyllum trabeum (brown wood rot) and Trametes versicolor (white wood rot). Artificial weathering and blue stain, contact angle, physical tests (adhesion, impact and scratch test), chemical (FTIR) and morpho-anatomical analysis (SEM) were carried out. CNC addition increased viscosity, limiting the spreading of the coating into wood pores as visible after SEM observation, which reduced coating adhesion on the substrate. CNC improved fungal resistance as seen by a reduced mass loss and FTIR spectroscopy thanks to crosslinks formation, which reduced water sorption as well. Color change was not significant, and, on the other hand, glossiness was reduced but resulted as more homogeneous than control. CNC addition gave good results also in blue stain protection. CNC improved scratch resistance, but no visible change to impact was registered. CNC has promising results in coatings depending on wood and fungal species and presence of further commercial additives (biocides)

Preparation of Lignin Nanoparticles from Wood Waste for Wood Surface Treatment

Lignin was isolated from wood wastes comprising Iroko sawdust (IR) and mixed sawdust from Iroko and Norway spruce (IRNS), furnished by a local wood houses producer. The respective acidolysis lignin fractions were structurally characterized using pyrolysis (Py)-GCMS, two-dimensional heteronuclear single quantum correlation nuclear magnetic resonance (2D HSQC NMR), Fourier-transform infrared FTIR and ultraviolet-visible (UV-VIS) spectroscopies, size exclusion chromatography, and standard wet-chemistry methods for Klason lignin and polysaccharides determination. The isolated lignin fractions were subsequently used for the preparation of lignin nanoparticles (LNPs) using a non-solvent method. LNPs were then used for wood surface treatment using a dip-coating technique. The coated wood samples were analyzed by colorimetry and scanning electron microscopy (SEM) before and after artificial weathering experiments in a UV chamber to investigate the UV protection potential of the LNPs coatings. Wood samples dip-coated with LNPs showed promising surface modifications resembling a sort of film of fused LNPs. Coatings made from IR-LNPs and IRNS-LNPs performed significantly better in artificial weathering experiments than uncoated reference samples.6s