Impacts of Work Environment on Health Status of Traffic Compliance and Enforcement Corps Members in Ogun State. Nigeria

Background: Traffic Compliance and Enforcement (TRACE) Corps members in Nigeria are occupationally exposed to lots of environmental pollutants due to essential services that they render in the transport industry. Exposure to environmental pollutants has been shown to contribute to the pathogenesis and progression of cardiovascular diseases (CVD). Information about biochemical end points of CVD in Traffic Compliance and Enforcement (TRACE) Corps members who are occupationally exposed to environmental pollutants is lacking. This study therefore investigated the effects of these environmental pollutants on some indices of CVD. Methods: Before enrollment in the study, all subjects, including controls, were informed about the objectives and requirements of the study, as well as the risks and discomfort that might be involved in participating in the study. After this exercise, a total of 234 subjects consented to participate in the study. TRACE (n=195) in various zones in Ogun State. Staff and students at Federal University of Agriculture, Abeokuta (FUNAAB) served as control subjects (n=39). A careful history of their dietary habits and job experience, as well as a detailed history of their occupational habit, was taken. Anthropometric and clinical parameters were assessed using standard methods while biochemical indices of CVD were determined spectrophotometrically using commercial diagnostic kits. One-way analysis of variance (ANOVA) followed by Duncan test was used to analyze the results with p\u3c0.05 considered significant. The relationships between plasma lipids and the anthropometric parameters were also analyzed using Pearson correlations. Results: Results showed that the systolic blood pressure in both male and female TRACE subjects were significantly higher than the control subjects. The diastolic blood pressure remained the same in both the control and TRACE subjects. The pulse in the TRACE male subject was significantly lower than the control subject. The body mass index (BMI), waist circumference and hip circumference of the TRACE female were significantly higher than the control subjects. The umbilical cord circumference of the TRACE male and female subjects were significantly higher than their control counterpart. Plasma Cholesterol in TRACE male was higher than the control male while the plasma cholesterol was lower in TRACE female compared to the control female. Plasma triacylglycerol and phospholipid remain the same in all subjects. HDL cholesterol in the TRACE subjects were 65% and 71% of the control male and control female respectively. Plasma arylesterase in TRACE male and female subjects were both 1.39 times lower than their control counterparts. There was also a significant positive correlation between the plasma cholesterol and weight (r = 0.130; p = 0.047), plasma cholesterol and BMI (r = 0.157; p = 0.021), Plasma triacylglycerol and Pulse (r = 0.130; p = 0.048). The average traffic density was 37 vehicles/min in the sampled TRACE zones. Conclusion: Findings such as increase in systolic blood pressure, anthropometric parameters and lower HDL cholesterol, plasma arylesterase in the TRACE subjects compared to the control from this study indicates that environmental pollutant exposure may disrupt lipid homeostasis and predisposes the TRACE subjects to development of CVD

Chapter 31 - Application of nanochitosan in tagging and nano-barcoding of aquatic and animal meats

Nanochitosans obtained from crustacean shells are biodegradable and biocompatible offering valuable functional, nutritional, and binding properties. Their low toxicity favors diverse industrial applications in various research models and can enable their use in the tagging of commercially sold aquatic and animal meat, easily contaminated by microbial sources during packaging, storage, and transportation. In this capacity, nanochitosans have been applied in fingerprinting for tracking and identifying the manufacturing and expiry dates of commercially sold meats and fish, as well as delivery of antioxidants and antimicrobials in these food products without affecting product consistency, composition, and organoleptic property. This chapter reviews current research on chitosan-based nanoparticles as barcodes and biosensors in tagging and monitoring aquatic and animal meats; and highlights methods of fish tagging and coding, and the benefits as well as the properties of materials used as biosensors in nano-barcoding of fish and meat

Utilization of nanochitosan for enzyme immobilization of aquatic and animal-based food packages

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

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

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

Phyto-metals screening of selected anti-diabetic herbs and infused concoctions

Objective: To determine the levels of some selected heavy metals in both the selected anti-diabetic herbal plants and infused concoctions for diabetes treatment. Methods: Ten anti-diabetic plant samples: pawpaw leaves (Carica papaya), bitter melon leaves (Momordica charantia), holy basil leaves (Ocimum sanctum), bitter leaf (Vernonia amygdalina), ginger rhizome (Zingiber officinale), garlic (Allium sativum), African red pepper fruits (Capsicum frutescens), negro pepper grain (Xylopia aethiopica), cashew leaves (Anacardium occidentale) and onion bulb (Allium cepa) were evaluated for heavy metals. These were digested using standard methods and analyzed for manganese, copper, nickel, chromium, zinc, cadmium and lead using atomic absorption spectrophotometer. The infused concoctions (I and II) prepared from these medicinal herbs administered to diabetic patients were also analyzed for these heavy metals. Concoction I contained all the plants and honey with the exception of Momordica charantia and Ocimum sanctum which constituted concoction II with water only. The data obtained were subject to descriptive (mean and standard deviation) and inferential (ANOVA and DMRT) statistics. Results: Chromium and nickel levels were below detection limits in concoction I while manganese [(0.11 ± 0.01) μg/g] and zinc [(0.09 ± 0.01) μg/g] were detected in concoction II. Honey contained manganese [(0.10 ± 0.01) μg/g] and nickel [(0.70 ± 0.01) μg/g]. The anti-diabetic medicinal herbs and infused concoctions (I and II) were observed to contain heavy metals below the compared limits. Conclusions: The study thus shows that the herbs and concoctions are safe from the heavy metals considered. However, right dosage of the anti-diabetic concoctions should always be considered to prevent possible chronic side effects from bio-accumulation of heavy metals