Bacteria as biofactory of pigments: Evolution beyond therapeutics and biotechnological advancements.

Bacterial pigments are the wonder molecules of nature that have attracted the attention of industries in recent years. To date, various synthetic pigments have been in use in food, cosmetics, and textile industries that have not only shown a notoriously toxic nature but also posed threat to the ecosystem. Moreover, nutraceuticals, fisheries, and animal husbandry were highly dependent on plant sources for products that aid in disease prevention and improve stock health. In this context, the use of bacterial pigments as new-generation colorants, food fortifiers, and supplements can hold great prospects as low-cost, healthy, and eco-friendly alternatives. The majority of studies on these compounds were restricted to antimicrobial, antioxidant, and anticancer potentials to date. Each of these can be highly beneficial for the development of new-generation drugs, but their other potential niche in various industries that pose health and environmental risks needs to be explored. Recent advances in novel strategies of metabolic engineering, advancements in optimization tools for the fermentation process, and the design of appropriate delivery systems will greatly expand the market of bacterial pigments in industries. This review summarizes the current technologies for enhancing production, recovery, stability, and appreciable use of bacterial pigments in industries apart from therapeutics with proper financial aspects. The toxicity perspectives have been focused to emphasize that these wonder molecules are the need of the hour and their future prospects have been highlighted. Extensive literature has been studied to include the challenges of bacterial pigments from environmental and health risk perspectives.

Challenges in developing strategies for the valorization of lignin-a major pollutant of the paper mill industry.

Apart from protecting the environment from undesired waste impacts, wastewater treatment is a crucial platform for recovery. The exploitation of suitable technology to transform the wastes from pulp and paper industries (PPI) to value-added products is vital from an environmental and socio-economic point of view that will impact everyday life. As the volume and complexity of wastewater increase in a rapidly urbanizing world, the challenge of maintaining efficient wastewater treatment in a cost-effective and environmentally friendly manner must be met. In addition to producing treated water, the wastewater treatment plant (WWTP) has a large amount of paper mill sludge (PMS) daily. Sludge management and disposal are significant problems associated with wastewater treatment plants. Applying the biorefinery concept is necessary for PPI from an environmental point of view and because of the piles of valuables contained therein in the form of waste. This will provide a renewable source for producing valuables and bio-energy and aid in making the overall process more economical and environmentally sustainable. Therefore, it is compulsory to continue inquiry on different applications of wastes, with proper justification of the environmental and economic factors. This review discusses current trends and challenges in wastewater management and the bio-valorization of paper mills. Lignin has been highlighted as a critical component for generating valuables, and its recovery prospects from solid and liquid PPI waste have been suggested.

Chitosan based micro and nano-particulate delivery systems for bacterial prodigiosin: Optimization and toxicity in animal model system.

Prodigiosin, a red bacterial pigment is a compound with promising therapeutic properties. Major hindrance in applying prodigiosin in pharmaceutics is the insolubility in water and lack of bioavailability. This study aims to optimize two different types of chitosan based delivery systems, microspheres and nanoparticles for prodigiosin derived from Serratia marcescens NITDPER1 through Taguchi method and determine toxicity perspectives. The results revealed 0.5 % chitosan, 1 % sodium-alginate and 5 % CaCl2 optimum for microsphere and 0.1 % chitosan, 1.5 % TPP and 1.5 % acetic acid for nanoparticle with the entrapment efficiency and maximum release of 89.27 ± 1.2 % and 87.42 ± 1.9 % for microspheres and 96.36 ± 1.7 % and 91.58 ± 2.1 % for nanoparticles. Particle size was 93.03 ± 0.3 µm and 75.1 ± 1.4 nm for micro and nanoformulations. Kinetic parameters of release fitted best with Korsmeyer-Peppas model. Swelling index of microsphere and nanoparticles in pH 6.8 was 799 ± 7.1 % and 35.3 ± 2.1 % respectively. FESEM, FT-IR and XRD revealed spherical morphology, preservation of prodigiosin functional groups and amorphous nature of the formulations. Anticancer IC50 values were (µg mL-1) 11.7 ± 1.2, 10.8 ± 1.4 and 9.4 ± 0.8 for free prodigiosin, microsphere and nanoparticles respectively. Toxicity studies on HEK-293 cell line, Daphnia magna and zebrafish model determined non-toxic nature of the bacterial prodigiosin and its formulations revealing suitability of animal system application.

Comparative performance evaluation of chitosan based polymeric microspheres and nanoparticles as delivery system for bacterial ß-carotene derived from Planococcus sp. TRC1.

ß-carotene is a natural compound with immense healthcare benefits. To overcome insolubility and lack of stability which restricts its application, in this study, ß-carotene from Planococcus sp. TRC1 was entrapped into formulations of chitosan­sodium alginate microspheres (MF1, MF2 and MF3) and chitosan nanoparticles (NF1, NF2 and NF3). The maximum entrapment efficiency (%) and loading capacity (%) were 80.6 ± 4.28 and 26 ± 3.05 (MF2) and 92.1 ± 3.44 and 41.86 ± 4.65 (NF2) respectively. Korsmeyer-Peppas model showed best fit with release, revealing non-Fickian diffusion. Thermal and UV treatment exhibited higher activation energy (kJ/mol), 17.76 and 15.57 (MF2) and 37.03 and 19.33 (NF2) compared to free ß-carotene (3.7 and 3.9), uncovering enhanced stability. MF2 and NF2 revealed swelling index (%) 721 ± 1.7 and 18.1 ± 1.5 (pH 6.8) and particle size 69.5 ± 3.2 µm and 92 ± 2.5 nm respectively. FESEM, FT-IR, XRD and DSC depicted spherical morphology, intactness of functional groups and masking of crystallinity. The IC50 (µg ml-1) values for antioxidant and anticancer (A-549) activities were 33.1 ± 1.7, 45.1 ± 2.8, 39.3 ± 2.9 and 31.3 ± 1.7, 27.9 ± 2.4, 25.3 ± 2.2 for ß-carotene, MF2 and NF2 respectively with no significant cytotoxicity on HEK-293 cells and RBCs (p > 0.05). This comparative study of microspheres and nanoparticles may allow the diverse applications of an unconventional bacterial ß-carotene with promising stability and efficacies.