New eco-friendly trends to produce biofuel and bioenergy from microorganisms: An updated review

It is critical to ensure the safe disposal of organic residues, especially because the accumulation of organic wastes contributes to environmental contamination; spread of diseases, unpleasant odors; and the release of ammonia and other dangerous gases in the environment. Consequently, researchers are considering various direct organic waste applications, including biotechnological applications with ecological and economical benefits such as the limitation of fossil fuel usage, lowering harmful emissions, boosting the synthesis of cost-effective raw materials, and establishing a suitable platform for a diversity of microorganisms. Biotechnology has produced sustainable bioenergy (biogas, biodiesel, bioethanol, and biobutanol), which is an appealing solution for the disposal of organic materials. Carbohydrates are the main component of the organic fraction, and the bulk of these polymers are easily degradable by microorganisms. Taking random samples from soils exposed to organic wastes, purifying the microbial isolates, and evaluating the microbes’ capabilities to identify the most useful strain are all part of the isolation process. As a result, this current review focuses on isolated strains of various microorganisms that may use one or more types of organic wastes as the sole carbon source, and to manufacture biofuel as a product from various residues

Selenium nanoparticles from Lactobacillus paracasei HM1 capable of antagonizing animal pathogenic fungi as a new source from human breast milk

The current study was performed to develop a simple, safe, and cost-effective technique for the biosynthesis of selenium nanoparticles (SeNPs) from lactic acid bacteria (LAB) isolated from human breast milk with antifungal activity against animal pathogenic fungi. The LAB was selected based on their speed of transforming sodium selenite (Na2SeO3) to SeNPs. Out of the four identified LAB isolates, only one strain produced dark red color within 32 h of incubation, indicating that this isolate was the fastest in transforming Na2SeO3 to SeNPs; and was chosen for the biosynthesis of LAB-SeNPs. The superior isolate was further identified as Lactobacillus paracasei HM1 (MW390875) based on matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF MS) and phylogenetic tree analysis of 16S rRNA sequence alignments. The optimum experimental conditions for the biosynthesis of SeNPs by L. paracasei HM1 were found to be pH (6.0), temperature (35˚C), Na2SeO3 (4.0 mM), reaction time (32 h), and agitation speed (160 rpm). The ultraviolet absorbance of L. paracasei-SeNPs was detected at 300 nm, and the transmission electron microscopy (TEM) captured a diameter range between 3.0 and 50.0 nm. The energy-dispersive X-ray spectroscopy (EDX) and the Fourier-transform infrared spectroscopy (FTIR) provided a clear image of the active groups associated with the stability of L. paracasei-SeNPs. The size of L. paracasei-SeNPs using dynamic light scattering technique was 56.91 ± 1.8 nm, and zeta potential value was −20.1 ± 0.6 mV in one peak. The data also revealed that L. paracasei-SeNPs effectively inhibited the growth of Candida and Fusarium species, and this was further confirmed by scanning electron microscopy (SEM). The current study concluded that the SeNPs obtained from L. paracasei HM1 could be used to prepare biological antifungal formulations effective against major animal pathogenic fungi. The antifungal activity of the biologically synthesized SeNPs using L. paracasei HM1 outperforms the chemically produced SeNPs. In vivo studies showing the antagonistic effect of SeNPs on pathogenic fungi are underway to demonstrate the potential of a therapeutic agent to treat animals against major infectious fungal diseases

Nutritional aspects and health benefits of bioactive plant compounds against infectious diseases: A review

In the current century, the development of medicine and molecular biotechnology led to successful containment and even eradication of some human pathogens, especially in developed countries. However, some pathogens have evolved, resulting in the emergence of other infectious diseases in developed countries. Human socioeconomic activities and the advancement of technology and transportation have led to the quick movement of humans to different parts of the world. There is a significant concern that this movement enhances the distribution of pathogens, making it difficult to contain, as witnessed with the global spread of the 2009 influenza pandemic within only 3 months and the 2014 Ebola outbreak, which spread in various West African countries within 8 months. Natural products obtained from plant sources can be identified as the next-generation antibacterial and antiviral alternatives. In developed countries, 80% of the population depends on traditional medicine for their primary healthcare issues, according to the World Health Organization (WHO). Relatedly, India is one of the highest producing countries for medicinal herbs. It is considered an international botanical garden. Therefore, the focus of this current review was on the importance of using plants to treat bacterial and viral diseases due to the many advantages of these plants

The use of black pepper (Piper guineense) as an ecofriendly antimicrobial agent to fight foodborne microorganisms

Consumers demand clean-label food products, necessitating the search for new, natural antimicrobials to meet this demand while ensuring food safety. This review aimed at investigating the antimicrobial properties of black pepper (Piper guineense) against foodborne microorganisms. The existence of foodborne illness, food spoilage, food waste, the resulting negative economic impact of these issues, and consumer interests have all pushed the food industry to find alternative, safe, and natural antimicrobials to be used in foods and beverages. Consumers have also influenced the demand for novel antimicrobials due to the perceived association of current synthetic preservatives with diseases and adverse effects on children. They also have a desire for clean-label products. These combined concerns have prompted researchers at investigating plant extracts as potential sources for antimicrobials. Plants possess many antimicrobial properties; therefore, evaluating these plant extracts as a natural source of antimicrobials can lead to a preventative control method in reducing foodborne illness and food spoilage, inclusively meeting consumer needs. In most regions, P. guineense is commonly utilized due to its potent and effective medicinal properties against foodborne microorganisms