Chemico-physical Characterization Research Articles

Microbiological, Functional, and Chemico-Physical Characterization of Artisanal Kombucha: An Interesting Reservoir of Microbial Diversity.

Kombucha is a trending tea fermented via a complex microflora of yeasts and acetic acid bacteria. It can be a valid low-calorie substitute for soft drinks due to its sour, naturally carbonated, and sweet taste. Despite increased interest, the microflora and functional properties of kombucha have not yet been fully understood. The aim of this work was to characterize, from a microbiological, chemico-physical, and functional point of view, three types of artisanal kombucha obtained by fermenting green tea containing sugar by means of different starter cultures. Metagenomic analysis revealed a predominance of yeasts compared to bacteria, regardless of the sample. In particular, Brettanomyces spp. was found to be the dominant yeast. Moreover, the different types of kombucha had different microbial patterns in terms of acetic acid bacteria and yeasts. Ethanol and acetic acid were the dominant volatile molecules of the kombucha volatilome; the samples differed from each other in terms of their content of alcohols, esters, and acids. All the samples showed a high antioxidant potential linked to the high content of phenols. This study confirmed the positive chemico-physical and functional properties of kombucha and indicated that the microflora responsible for the fermentation process can significantly affect the characteristics of the final product.

Efficient photoactivated hydrogen evolution promoted by CuxO-gCN-TiO2-Au (x = 1,2) nanoarchitectures.

In this work, we propose an original and potentially scalable synthetic route for the fabrication of CuxO-gCN-TiO2-Au (x = 1,2) nanoarchitectures, based on Cu foam anodization, graphitic carbon nitride liquid-phase deposition, and TiO2/Au sputtering. A thorough chemico-physical characterization by complementary analytical tools revealed the formation of nanoarchitectures featuring an intimate contact between the system components and a high dispersion of gold nanoparticles. Modulation of single component interplay yielded excellent functional performances in photoactivated hydrogen evolution, corresponding to a photocurrent of ≈-5.7 mA cm-2 at 0.0 V vs. the reversible hydrogen electrode (RHE). These features, along with the very good service life, represent a cornerstone for the conversion of natural resources, as water and largely available sunlight, into added-value solar fuels.

Wells-Dawson type polyoxometalate, [S2W18O62]4−-doped poly(3,4-ethylenedioxythiophene) films: Voltammetric behaviour and applications to selective bromate detection

Wells-Dawson type polyoxometalate (POM) [(n-C3H7)4N]4S2W18O62 (S2W18) was successfully immobilised with a conducting polymer, poly(3,4-ethylenedioxythiophene) (PEDOT), by chronocoulometry technique. The immobilised films with different surface thicknesses were characterised by various electrochemical techniques. The S2W18-doped PEDOT film gave four couples of redox waves, the first one corresponds to the redox process of the polymer itself and the other three couples are electron transfer at tungstate in the framework. The films exhibited inherent pH-dependent redox activity and stability of S2W18 in the thin layer up to 100 mV/s. Only slight changes were observed in the magnitude of peak currents after continuous redox cycling, indicating the relative stability of the S2W18 in the conducting PEDOT. The conductive behaviour of the film was investigated with electrochemical impedance spectroscopy. The study of electrochemical bromate ion sensing based on S2W18-doped PEDOT film employing chronoamperometric technique revealed that at an applied potential of -0.1 V, the S2W18-doped PEDOT film can detect bromate at concentrations between 100 μmol L−1 and 2000 μmol L−1. Moreover, the S2W18-doped PEDOT film shows a detection limit of 4 μmol L−1 without interference from other common ions present in the water. Hybrid films exhibit significant catalytic activity with high selectivity at a low reduction potential of -0.1 V. Chemico-physical characterization of the target systems was performed using atomic force microscopy, field emission scanning electron microscopy, energy dispersive X-ray spectroscopy and Raman spectroscopy.

Chemico-Physical Properties of Some 1,1'-Bis-alkyl-2,2'-hexane-1,6-diyl-bispyridinium Chlorides Hydrogenated and Partially Fluorinated for Gene Delivery.

The development of very efficient and safe non-viral vectors, constituted mainly by cationic lipids bearing multiple charges, is a landmark for in vivo gene-based medicine. To understand the effect of the hydrophobic chain's length, we here report the synthesis, and the chemico-physical and biological characterization, of a new term of the homologous series of hydrogenated gemini bispyridinium surfactants, the 1,1'-bis-dodecyl-2,2'-hexane-1,6-diyl-bispyridinium chloride (GP12_6). Moreover, we have collected and compared the thermodynamic micellization parameters (cmc, changes in enthalpy, free energy, and entropy of micellization) obtained by isothermal titration calorimetry (ITC) experiments for hydrogenated surfactants GP12_6 and GP16_6, and for the partially fluorinated ones, FGPn (where n is the spacer length). The data obtained for GP12_6 by EMSA, MTT, transient transfection assays, and AFM imaging show that in this class of compounds, the gene delivery ability strictly depends on the spacer length but barely on the hydrophobic tail length. CD spectra have been shown to be a useful tool to verify the formation of lipoplexes due to the presence of a "tail" in the 288-320 nm region attributed to a chiroptical feature named ψ-phase. Ellipsometric measurements suggest that FGP6 and FGP8 (showing a very interesting gene delivery activity, when formulated with DOPE) act in a very similar way, and dissimilar from FGP4, exactly as in the case of transfection, and confirm the hypothesis suggested by previously obtained thermodynamic data about the requirement of a proper length of the spacer to allow the molecule to form a sort of molecular tong able to intercalate DNA.

Development and Chemico-Physical Characterization of Ovine Milk-Based Ingredients for Infant Formulae

The great majority of infant formula (FM) for neonate’s nutrition are produced using ingredients from cow milk. Recently, some countries, such as China and New Zealand, are turning their attention to the use of ovine milk ingredients for FM production. In this study, a pilot plant process has been set up to produce infant formula ingredients from Sarda sheep milk. To meet the nutritional needs of neonates (0–6 and 6–12 months of age) two different liquid milk-derived formulations (IF1 and IF2, respectively) obtained mixing whole milk, skimmed milk, and whey milk ultrafiltration concentrate (retentate) were produced. Compositional analysis of milk, retentate, and the final IFs showed that the two formulations contain elements of nutritional interest, such as well-balanced content of high biological value proteins (casein:whey proteins ratio of 30:70 and 60:40 for IF1 and IF2, respectively), vitamin A, E and B5, cholesterol, minerals, nucleotides, free amino acids and essential fatty acids (n–6:n–3 ~1), compatible with the growth and development needs of neonates. Therefore, the obtained IF1 and IF2 can be proposed as valuable ovine dairy ingredients for FM manufacturing. Further studies will be necessary to verify the adaptability of the developed process from laboratory to industrial scale application.

Reactivity of soot emitted from different hydrocarbon fuels: Effect of nanostructure on oxidation kinetics

Soot oxidation kinetics is relevant for the exhaust pollutant reduction through processing in abatement systems based on filtering and oxidation as diesel particulate filters. Soot nanostructure impact on oxidation reactivity was studied by thermogravimetric analysis of soot produced in premixed laminar flames burning different hydrocarbon fuels, namely methane, ethylene and benzene, and characterized by spectroscopic and microscopic analysis. Soot oxidation kinetics was multistep and two activation energies, 180 and 240 kJ/mol, could be evaluated. Preexponential factors obtained upon data fitting of the Arrhenius plots with the two activation energies, showed an increasing trend going from aliphatic (methane, ethylene) toward benzene soot, consistently with the rise of the maximum oxidation temperature. The higher and lower activation energies were correlated, respectively, to amorphous carbon, coalesced on soot particles and present in form of tortuous and not-stacked lamellae inside the particle, and to the rest of the particle, characterized by a better nanoscale organization. Through a detailed chemico-physical characterization, the different propensity to be oxidized of soot samples was correlated to the nanostructural features of the most ordered part burning at 240 kJ/mol.

Chiral non-stoichiometric ternary silver indium sulfide quantum dots: investigation on the chirality transfer by cysteine.

Chiral semiconductor quantum dots have recently received broad attention due to their promising application in several fields such as sensing and photonics. The extensive work in the last few years was focused on the observation of the chiroptical properties in binary Cd based systems. Herein, we report on the first evidence of ligand-induced chirality in silver indium sulfide semiconductor quantum dots. Ternary disulfide quantum dots are of great interest due to their remarkable optical properties and low toxicity. Non-stoichiometric silver indium sulfide quantum dots were produced via a room temperature coprecipitation in water, in the presence of cysteine as a capping agent. The obtained nanocrystals show a notable photoluminescence quantum yield of 0.24 in water dispersions. Several critical aspects of the nanocrystal growth and chemico-physical characterization, and the optimisation of the surface passivation by the chiral ligand in order to optimize the nanoparticle chirality are thoroughly investigated. Optical spectroscopy methods such as circular dichroism and luminescence as well as nuclear magnetic resonance techniques are exploited to analyze the coordination processes leading to the formation of the ligand-nanocrystal chiral interface. This study highlights the dynamic nature of the interaction between the nanocrystal surface and the chiral ligand and clarifies some fundamental aspects for the transfer and optimization of the chiroptical properties.

Plasma-Assisted Synthesis of MnO2-Based Nanoarchitectures As Gas Sensors for Safety and Food Quality Monitoring

The efficient detection of chemical warfare agents (CWAs) for homeland defense and people safety has received a growing attention, due to their high toxicity and dangerous effects on human health even at low concentration levels. In this regard, sensing of acetonitrile, a simulant of cyanide CWAs known to be itself a poisonous gas at low levels in air, is of utmost importance to prevent health hazards. In recent years, efforts have also been devoted to monitor food quality and, in particular, fruit/vegetable ripening/degradation in horticultural industry, for which ethylene is an important marker. Indeed, this analyte is a colorless, odorless and flammable gas whose production by climacteric fruits/vegetables, even at concentrations as low as some ppm, is a tell-tale of their ripeness stage. As a consequence, its efficient monitoring in warehouses is of key importance to extend fruits/vegetables life cycle and suppress detrimental losses of these agricultural products.In this context, the development of low-cost and reliable gas sensing materials capable of detecting the above gases in their early stages is a key issue to be still properly addressed. Among the various devices for acetonitrile and ethylene detection, chemoresistive gas sensors based on metal oxides with tailored morphology offer manifold advantages, including robustness, stability, low cost, and ease of operation. Among metal oxides, MnO2, an n-type semiconductor, exists in various polymorphs (α-, β-, γ-, δ- and ε-types) among which rutile-type β-MnO2 is the most stable one. This structural flexibility has stimulated efforts toward MnO2 use for various applications, among which volt-amperometric sensors. In this context, an interesting option to improve functional performances is the introduction of F as a dopant into the metal oxide matrix, as previously demonstrated for F-doped Co3O4 and Fe2O3 nanosystems [1,2]. On this basis, in this contribution [3] we report for the first time on acetonitrile and ethylene gas sensing performances of supported β-MnO2-based nanosystems synthesized by plasma enhanced-chemical vapor deposition (PE-CVD). In particular, the attention has been devoted to: (i) the modulation of the system morphology and defectivity, taking advantage of the versatility and inherent benefits offered by the above technique for low-temperature processing of inorganic nanomaterials; (ii) the use of Mn(tfa)2•TMEDA (Htfa = 1,1,1-trifluoro-2,4-pentanedione; TMEDA = N,N,N′,N′-tetramethylethylenediamine) as a single-source molecular precursor for both manganese and fluorine, allowing an in-site material doping during growth process.After a thorough characterization of MnO2 systems grown at different oxygen partial pressures, the system sensing performances were tested in the detection of acetonitrile and ethylene gases, investigating the interplay between the system characteristics and gas sensing performances.The results highlight favorable responses already at low operating temperatures with an enhanced detection efficiency toward the target analytes, that could provide a baseline data set for the development of MnO2 sensors for safety and food industry applications outperforming the actual ones.Afterwards, our attention has been focused on a proof-of-concept on the possibility of enhancing performances in ethylene sensing by MnO2 systems basing on the nanoarchitectonics concept [4]. More specifically, we have exploited the system sensitization with noble metals (M = Ag, Au) to boost the resulting functional behavior thanks to the guest catalytic activity at the nanoscale and to the formation of metal-oxide interfaces, yielding an enhanced charge carrier separation. The target materials have been fabricated by an original two-step plasma-assisted route, consisting in the initial PE-CVD of MnO2 nanoarchitectures, followed by the introduction of silver and gold nanoaggregates by mild sputtering processes. Tailored low-dimensionality nanoarchitectures with controllable features and an even distribution of noble metal particles have been successfully prepared taking advantage of the unique versatility offered by plasma processing, resulting in material properties hardly attainable by means of conventional synthetic routes. Tests aimed at ethylene sensing have revealed enhanced responses and sensitivities at low temperatures, with performances directly dependent on the functionalizing guest agent, as discussed in the framework of a comparative material chemico-physical characterization.

Microbial, chemico-physical and volatile aromatic compounds characterization of Pitina PGI, a peculiar sausage-like product of North East Italy

Pitina is a fermented sausage-like produced in the mountainous area of the North-East Italy by artisanal plants without the use of both selected starters and casing (Slow Food Presidium). Originally, Pitina has been a way of preserving meat and it is manifactured by meat from ungulates mixed with pork lard, smoked, dryed and ripened.In this study, microbial ecology, physic-chemical parameters, and volatile aromatic compounds of Pitina SR and LR, which differ by the duration of ripening processes, were investigated. Results showed the good hygienic quality. Staphylococcus xylosus and Lactobacillus sakei were responsible for the ripening. Other Coagulase-negative Catalase-positive Cocci (CNCPC) and LAB species were identified: S. equorum, S. warneri, S. succinus and Carnobacterium divergens, Streptococcus equinus, Kocuria rhizophila. Giberella moniliformis and Penicillium turbatum were the only mould species isolated. Strain characterization demonstrated a high genetic variability. Raw meat, environment and ripening conditions seemed to affect strains distribution, which had an impact on the aromatic profile of the product.

Probing soot structure and electronic properties by optical spectroscopy

In this work, the physicochemical transformation of soot particles during the initial stages of formation and growth was investigated in a laminar premixed flame of ethylene and air. The selected flame condition allowed producing two classes of carbon nanoparticles, namely incipient and primary soot particles, on the basis of their size distribution. The two classes of particles have been selectively collected in well distinct flame zones for further chemico-physical characterization. The optical band gap decreases as particle size grows up. Particle medium range order and structure at molecular level have been investigated by Raman and fluorescence spectroscopy. Slight changes in particle composition were observed for incipient and primary soot. Both kinds of particles are made of a similar ensemble of fluorescence centers, which produce excitation dependent emission irrespective of particle sizes. In agreement with the Raman spectra, the molecular constituents of the particles are polyaromatic compounds with an average size of the order of ovalene molecules that only slightly increase from incipient to primary soot particles. These results suggest that the observed decrease of the optical band gap, as particle size increases, typical of a quantum-dot behavior, is not due to changes in particle composition at molecular level. Further investigations are needed to investigate possible evolution in supramolecular organization of the particles as they grow in flame and its effect on the optical band gap.

Chemico-physical characterization and evaluation of coating properties of two commercial organosilicons

Two commercial organosilicons, Hydrophase®, a monomeric dispersion, and Disboxan 450®, an oligomeric dispersion, were studied in pure form and applied on acrylic paint replicas. Their physico-chemical characteristics, coating properties, and interaction with acrylic paint replicas were evaluated by TG, DSC, FTIR, and contact angle measurements. Hydrophase® showed a higher interaction when used on the top of acrylic paint replicas than Disboxan 450®. No appreciable modification was detected after two years of natural ageing.

Innovative and green nanolime treatment tailored to consolidate the original mortar of the façade of a medieval building in L’aquila (Italy)

This paper presents an original, green and compatible treatment to consolidate the pointing lime plastering of the façade of a medieval Italian palace, subjected to detachments and pulverization phenomena. The cohesion between the mortar constituents was refurbished by an aqueous nanolime suspension, synthesized by a cheap, time/energy-saving and scalable method, here originally tested on historic mortars. The suspension showed a high reactivity, assuring a complete carbonation in few hours, “restoring” the binder fraction with a new-formed network of calcite nanoparticles. The treatment efficacy was evaluated by chemico-physical, mineralogical and mechanical characterization both on untreated and treated specimens.

Chitosan/glycosaminoglycan scaffolds for skin reparation

Burns and chronic wounds, often related to chronic diseases (as diabetes and cancer), are challenging lesions, difficult to heal. The prompt and full reconstitution of a functional skin is at the basis of the development of biopolymer-based scaffolds, representing a 3D substrate mimicking the dermal extracellular matrix. Aim of the work was to develop scaffolds intended for skin regeneration, according to: fabrication by electrospinning from aqueous polysaccharide solutions; prompt and easy treatment to obtain scaffolds insoluble in aqueous fluids; best performance in supporting wound healing. Three formulations were tested, based on chitosan (CH) and pullulan (P), associated with glycosaminoglycans (chondroitin sulfate - CS or hyaluronic acid – HA). A multidisciplinary approach has been used: chemico-physical characterization and preclinical evaluation allowed to obtain integrated information. This supports that CS gives distinctive properties and optimal features to the scaffold structure for promoting cell proliferation leading tissue reparation towards a complete skin restore.

Luminescent dinuclear rhenium(I)[sbnd]PNA conjugates for microRNA-21 targeting: Synthesis, chemico-physical and biological characterization

Two different luminescent rhenium complexes, having the general formula [Re2(μ-Cl)2(CO)6(μ-1,2-diazine)] and containing two different diazine ligands, namely 4-(pyridazin-4-yl)-butanoic acid (Re-1) and 8-(5-methylpyridazin-4-yl)-octanoic acid (Re-2), were prepared. Exploiting the presence of the carboxylic acid moieties, both complexes were further covalently linked to a 20-mer oligomer (PNA1), bearing a nucleobase sequence complementary to that of mature miR-21–5p (5′-TCAACATCAGTCTGATAAGCTA-3′), as well as to a 20-mer oligomer (PNA2) used as a negative control bearing the sequence 5′-GTGTAACACGTCCTATACGCC-3’. The resulting four Re-PNA conjugates were characterized and used to target miR-21 in the DU145 prostate cancer cell line. The conjugation with PNA did not perturb the photoluminescence behavior of the organometallic fragments: emission from 3MLCT excited states, centered in a range between 580 and 610 nm, was observed, with satisfactory photoluminescence quantum yields (Φ = ca. 0.03–0.01, in aerated water/acetonitrile solution 1/1). Experiments of cell uptake, performed with living prostate cancer cells showed that the length of the aliphatic linker between the rhenium complex and the PNA sequence, strongly affects the cellular localization.

Synthesis of Gold Nanoparticles for Gene Silencing.

Over the last decade, the capability of double-stranded RNAs to interfere with gene expression has driven new therapeutic approaches. Since small interfering RNAs (siRNAs, 21-base-pair double-stranded RNA) were shown able to elicit RNA interference (RNAi), efforts were directed toward the development of efficient delivery systems to preserve siRNA bioactivity throughout the delivery route, from administration site to the target cell. Starting from the synthesis of gold nanoparticle, here we describe comprehensive methodologies for functionalization with specific moieties (charged groups, peptides) and chemico-physical characterization. Moreover, we report two different strategies that can be used to bind siRNA molecules on the gold nanoparticle: a covalent approach, based on thiolated siRNA bound via a thiol bond to nanoparticle surface, and an ionic approach based on the electrostatic interaction between the negatively charged siRNA backbone and azide and quaternary ammonium groups positively charged anchored on the nanoparticle surface. Both methodologies were shown highly efficient for siRNA delivery, achieving specific gene silencing in in vitro and in vivo biological systems.

Controlled Growth of Supported ZnO Inverted Nanopyramids with Downward Pointing Tips

High purity porous ZnO nanopyramids with controllable properties are grown on their tips on Si(100) substrates by means of a catalyst-free vapor phase deposition route in a wet oxygen reaction environment. The system degree of preferential [001] orientation, as well as nanopyramid size, geometrical shape, and density distribution, can be finely tuned by varying the growth temperature between 300 and 400 °C, whereas higher temperatures lead to more compact systems with a three-dimensional (3D) morphology. A growth mechanism of the obtained ZnO nanostructures based on a self-catalytic vapor–solid (VS) mode is proposed, in order to explain the evolution of nanostructure morphologies as a function of the adopted process conditions. The results obtained by a thorough chemico-physical characterization enable us to get an improved control over the properties of ZnO nanopyramids grown by this technique. Taken together, they are of noticeable importance not only for fundamental research on ZnO nanomaterials with controlled nano-organization but also to tailor ZnO functionalities in view of various potential applications.

All-SPEEK flexible supercapacitor exploiting laser-induced graphenization

Flexible supercapacitors have emerged as one of the more promising and efficient space-saving energy storage system for portable and wearable electronics. Laser-induced graphenization has been recently proposed as a powerful and scalable method to directly convert a polymeric substrate into a 3D network of few layer graphene as high-performance supercapacitor electrode. Unfortunately this outstanding process has been reported to be feasible only for few thermoplastic polymers, strongly limiting its future developments. Here we show that laser induced graphenization of sulfonated poly(ether ether ketone) (SPEEK) can be obtained and the mechanism of this novel process is proposed. The resulting material can act at the same time as binder-free electrode and current collector. Moreover SPEEK is also used both as separator and polymeric electrolyte allowing the assembling of an all-SPEEK flexible supercapacitor. Chemico-physical characterization provides deep understanding of the laser-induced graphenization process, reported on this polymer for the first time, while the device performance studied by cyclic voltammetry, charging–discharging, and impedance spectroscopy prove the enormous potential of the proposed approach.

Iron–Titanium Oxide Nanocomposites Functionalized with Gold Particles: From Design to Solar Hydrogen Production

Hematite–titania nanocomposites, eventually functionalized with gold nanoparticles (NPs), are designed and developed by a plasma‐assisted strategy, consisting in: (i) the plasma enhanced‐chemical vapor deposition of α‐Fe2O3 on fluorine‐doped tin oxide substrates; the radio frequency‐sputtering of (ii) TiO2, and (iii) Au in controlled amounts. A detailed chemicophysical characterization, carried out through a multitechnique approach, reveals that the target materials are composed by interwoven α‐Fe2O3 dendritic structures, possessing a high porosity and active area. TiO2 introduction results in the formation of an ultrathin titania layer uniformly covering Fe2O3, whereas Au sputtering yields a homogeneous dispersion of low‐sized gold NPs. Due to the intimate and tailored interaction between the single constituents and their optical properties, the resulting composite materials are successfully exploited for solar‐driven applications. In particular, promising photocatalytic performances in H2 production by reforming of water–ethanol solutions under simulated solar illumination are obtained. The related insights, presented and discussed in this work, can yield useful guidelines to boost the performances of nanostructured photocatalysts for energy‐related applications.

Biophysical and biological characterization of a new line of hyaluronan-based dermal fillers: A scientific rationale to specific clinical indications

Chemico-physical and biological characterization of hyaluronan-based dermal fillers is of key importance to differentiate between numerous available products and to optimize their use. These studies on fillers are nowadays perceived as a reliable approach to predict their performance in vivo. The object of this paper is a recent line of hyaluronic acid (HA)-based dermal fillers, Aliaxin®, available in different formulations that claim a complete facial restoration. The aim of the study is to provide biophysical and biological data that may support the clinical indications and allow to predict performance possibly with respect to similar available products. Aliaxin® formulations were tested for their content in soluble HA, water uptake capacity, rheological behavior, stability to enzymatic degradation, and for in vitro capacity to stimulate extracellular matrix components production. The formulations were found to contain a low amount of soluble HA and were equivalent to each other regarding insoluble hydrogel concentration. The different crosslinking degree declared by the producer was consistent with the trend in water uptake capacity, rigidity, viscosity. No significant differences in stability to enzymatic hydrolysis were found. In vitro experiments, using a full thickness skin model, showed an increase in collagen production in the dermoepidermal junction.Results support the claims of different clinical indications, the classification of products regarding hydro-, lift-action and the specifically suggested needle gauge for the delivery. The biological outcomes also support products effectiveness in skin structure restoration. These data predicted a better performance regarding hydro-action, tissue integration, clinical management during delivery, and a high durability of the aesthetic effect when compared to data on marketed similar products.

Visible light driven mineralization of spiramycin over photostructured N-doped TiO2 on up conversion phosphors

A novel visible light-active photocatalyst formulation (NdT/OP) was obtained by supporting N-doped TiO2 (NdT) particles on up-conversion luminescent organic phosphors (OP). The photocatalytic activity of such catalysts was evaluated for the mineralization process of spiramycin in aqueous solution. The effect of NdT loading in the range 15–60wt.% on bulk and surface characteristics of NdT/OP catalysts was investigated by several chemico-physical characterization techniques. The photocatalytic performance of NdT/OP catalysts in the removal of spyramicin from aqueous solution was assessed through photocatalytic tests under visible light irradiation. Total organic carbon (TOC) of aqueous solution, and CO and CO2 gas concentrations evolved during the photodegradation were analyzed. A dramatic enhancement of photocatalytic activity of the photostructured visible active NdT/OP catalysts, compared to NdT catalyst, was observed. Only CO2 was detected in gas-phase during visible light irradiation, proving that the photocatalytic process is effective in the mineralization of spiramycin, reaching very high values of TOC removal. The photocatalyst NdT/OP at 30wt.% of NdT loading showed the highest photocatalytic activity (58% of TOC removed after 180min irradiation against only 31% removal after 300min of irradiation of NdT). We attribute this enhanced activity to the high effectiveness in the utilization of visible light through improved light harvesting and exploiting. OP particles act as “photoactive support”, able to be excited by the external visible light irradiation, and reissue luminescence of wavelength suitable to promote NdT photomineralization activity.