Nanochitosan derived from marine bacteria

Nanochitosans are polysaccharides produced by the alkalescent deacetylation of chitin and comprise a series of 2-deoxy-2 (acetylamino) glucose linked by ß-(1-4) glycosidic linkages. These are naturally formed from the deacetylation of shellfish shells and the exoskeleton of aquatic arthropods and crustaceans. Reports of chitosan production from unicellular marine bacteria inhabiting the sea, and possessing distinct animal- and plant-like characteristics abound. This capacity to synthesize chitosan from chitin arises from response to stress under extreme environmental conditions, as a means of survival. Consequently, the microencapsulation of these nanocarriers results in new and improved chitosan nanoparticles, nanochitosan. This nontoxic bioactive material which can serve as an antibacterial agent, gene delivery vector as well as carrier for protein and drug release as compared with chitosan, is limited by its nonspecific molecular weight and higher composition of deacetylated chitin. This chapter highlights the biology and diversity of nanochitosan-producing marine bacteria, including the factors influencing their activities, survival, and distribution. More so, the applications of marine bacterial nanochitosans in transfection and gene delivery; wound healing and drug delivery; feed supplement development and antimicrobial activity are discussed

Next Generation Nanochitosan Applications in Animal Husbandry, Aquaculture and Food Conservation

Studies have identified the properties of enzymes, functionalized molecules, and compounds in food industry applications as edible coatings and encapsulations, that assure prolonged food quality and standards. These molecules present benefits of longer shelf-life by delayed deterioration and inhibition of the proliferation of spoilage and mycotoxigenic microorganisms. However, challenges of reduced nutrient levels, miniaturized size, and low chemical stability remain concerning. Chitosan polymers naturally formed from the deacetylation of shellfish shells and exoskeletons of aquatic arthropods and crustaceans offer improved benefits when functionalized into nanoparticles as nanochitosans. These polysaccharides produced by the alkalescent deacetylation of chitin, comprise a series of 2-deoxy-2 (acetylamino) glucose linked by ß-(1- 4) glycosidic linkages. This chapter considers the health impacts and microbiological health hazards associated with animal feeds quality and the enzyme immobilization potentials of nanochitosans in animalbased food and feed packages. Thereafter, nanochitosan properties and benefits are compared against traditional preservatives from microbes and plants; with highlights on current challenges in the application of nanochitosan for enzyme immobilization

Chapter 21 - Utilization of nanochitosan in the sterilization of ponds and water treatment for aquaculture

Water pollution constitutes the leading cause of infant mortality, neonatal deformities, and shrinkage of man’s average life expectancy. Pollutants come from point and nonpoint sources; and water pollution arises from the discharge of wastewater containing undesirable impurities used for domestic, agricultural, and industrial purposes. More so, high nutrient and wastewater runoffs from fish production systems contribute to the fouling and eutrophication of recipient water bodies. Hence, aquaculture which is inextricably linked to the natural environment is challenged by the dearth of appropriate water quantity and quality, militating against fish, and fishery production. Nanochitosans as polysaccharides produced by the alkalescent deacetylation of chitin, comprise a series of 2-deoxy-2 (acetylamino) glucose linked by ß-(1-4) glycosidic linkages. They are naturally formed from the deacetylation of shellfish shells and exoskeletons of aquatic arthropods and crustaceans. The unique attributes of chitin confer a wide range of biotechnological applications on the polymer, observed in flocculation as a wastewater treatment and purification route initiated by chitosan. This chapter highlights nanochitosan properties of aquaculture relevance; and elucidates the purification potentials of nanochitosan, compared to inorganic coagulants and organic polymeric flocculants. Effects of chitosan on contaminants and microorganisms, as well as applications in fish pathogens detection, fish disease diagnosis, and control are discussed

Nanochitosan derived from marine bacteria

Nanochitosans are polysaccharides produced by the alkalescent deacetylation of chitin and comprise a series of 2‐deoxy‐2 (acetylamino) glucose linked by ß‐(1‐4) glycosidic linkages. These are naturally formed from the deacetylation of shellfish shells and the exoskeleton of aquatic arthropods and crustaceans. Reports of chitosan production from unicellular marine bacteria inhabiting the sea, and possessing distinct animal‐ and plant‐like characteristics abound. This capacity to synthesize chitosan from chitin arises from response to stress under extreme environmental conditions, as a means of survival. Consequently, the microencapsulation of these nanocarriers results in new and improved chitosan nanoparticles, nanochitosan. This nontoxic bioactive material which can serve as an antibacterial agent, gene delivery vector as well as carrier for protein and drug release as compared with chitosan, is limited by its nonspecific molecular weight and higher composition of deacetylated chitin. This chapter highlights the biology and diversity of nanochitosan‐producing marine bacteria, including the factors influencing their activities, survival, and distribution. More so, the applications of marine bacterial nanochitosans in transfection and gene delivery; wound healing and drug delivery; feed supplement development and antimicrobial activity are discussed

Prevalence of hypertension and obesity among non-academic staff in a Nigerian University : Hypertension and Obesity among Nigerian Staff

Background: The aim of achieving a healthy society has motivated and led many researchers to understand the prevalence of diseases to create awareness and assess interventions’ effectiveness. Objective: This study determines the prevalence of hypertension and obesity among the non-academic staff of the Federal University of Agriculture, Abeokuta. Methods: The study design was descriptive and cross-sectional. 300 Non-academic staff of the institution were randomly selected and data were obtained on their sociodemographic and socioeconomic characteristics, predisposing risk factors of hypertension, anthropometry, and blood pressure measurements using a structured self-administered questionnaire and standard procedures. Data were analyzed and presented using descriptive and inferential statistics. Statistical significance was established at p<0.05. Results: The mean age was 42±8.0years, there were more female respondents (56.0%) than male respondents (44.0%) and 76.0% of the respondents were married. Results further revealed a high prevalence of overweight and obesity (52%), pre-hypertension and hypertension (40%), and risk of abdominal obesity (84%). Conclusion: Non-academic staff are an essential component of the workforce and workplace intervention is essential to reduce the work nature risk factor of Obesity and Hypertension to prolong lives, and boost productivity and economic growth

Effects of cypermethrin as a model chemical on life cycle and biochemical responses of the tropical stingless bee Meliponula bocandei Spinola, 1853

The tropical stingless bee, Meliponula bocandei Spinola, 1853 is an important pollinator in West Africa but there is no study on the effect of pesticides on this species. This study assessed the effects of cypermethrin, a common pyrethroid on survival, taste (sucrose sensitivity), and biochemical responses of M. bocandei. The biochemical markers were superoxide dismutase [SOD], catalase [CAT], glutathione S-transferase (GST), reduced glutathione [GSH]), and acetylcholinesterase [AChE]) as well as glucose, trehalose and total protein concentrations. Test temperature was optimized by acclimatizing adult worker bees collected from a pristine natural colony to different temperature regimes in the laboratory and fed with sucrose solution. The optimized temperature (22°C) for survival and sucrose consumption was adopted for the toxicity test. The 24–48 h oral lethal dose (LD50) and 24–96 h indirect contact lethal concentration (LC50) of cypermethrin on the bees was in the range of 0.66–0.76 µg/ml and 92.24–223.69 µg/ml respectively. Also, the overall PER response reduced below 50% in bees that were orally exposed to high doses of cypermethrin. There was significant decrease in glucose, trehalose, total protein and GSH concentrations in bees when compared with the control. Also, significant alterations were observed in SOD, CAT, GST and AChE activity for both oral and contact exposure pathways. In conclusion, cypermethrin modulated the activities of biomarkers of oxidative stress and altered the level of energy metabolites in the bees