Plastic bottle feeding produces changes in biochemical parameters in human infants - A pilot study.

BACKGROUND: Plastic bottles are widely used by people to feed their infants when breastfeeding is not possible. Bisphenol A (BPA), an endocrine disruptor is widely used in the manufacturing of plastic wares and is leached out from these plastic wares on exposure to high temperature, changed pH, or cleaning the plastic wares by harsh detergents. PURPOSE: Feeding through plastic bottles over prolong duration is expected to expose the infants to leached BPA. Hence the present study was taken up to compare the effects of breastfeeding and plastic bottle feeding on biochemical parameters in infants and also detect for the presence of free BPA or its metabolite in the infants. METHODS: Biochemical tests like lipid profile, liver function tests, creatine-kinase-MB (CK-MB), serum urea, serum electrolytes were performed on blood samples obtained from infants who were breastfed and plastic bottle fed. Further, plasma and urine samples of the infants were subjected to Liquid chromatography-mass spectrometry analysis for detecting free BPA and BPA glucuronide. RESULTS: Biochemical changes in form of raised triglycerides, cholesterol, low-density lipoproteins, very low-density lipoproteins and increase in CK-MB, serum urea were observed in plastic bottle fed infants. BPA glucuronide was also detected in the urine of these infants. Free BPA was not detected in plasma or urine samples of the infants except in one plasma sample from bottle-fed group. CONCLUSION: Plastic bottle feeding may lead to toxic changes in the functioning of organs which manifest as altered biochemical parameters.

Effect of Exposure of Plastic Infant Feeding Bottle Leached Water on Biochemical, Morphological and Oxidative Stress Parameters in Rats.

Bisphenol A (BPA) is leached out from plastic infant feeding bottles that are filled with warm milk/water due to high temperatures, exposing the infants to BPA. The present study aims to understand the effects of ingestion of BPA leached from plastic infant feeding bottle and delineate the underlying mechanisms in rats. In this study, adult rats of Wistar strain were divided into 3 groups. In the first group, the rats consumed normal food and tap water ad libitum. In the second group, the rats ingested BPA (20 µg/kg bodyweight/day, orally). In the third group, the rats drank water leached from plastic infant feeding bottles. After 30days, tests involving biochemical parameters, histopathological examination, and oxidative stress enzyme markers were performed, and the levels of BPA in plastic-leached water were estimated by HPLC analysis. There were significant biochemical changes in the form of increased alkaline phosphatase (ALP), creatine kinase-muscle/brain (CK-MB), and lactate dehydrogenase (LDH) levels in both treated groups as compared to control group, accompanied by structural damage to the vital organs, and lipid peroxidation, glutathione reductase, and catalase activity were also high in the treated groups. Further, the BPA concentration in plastic leached water was estimated to be 0.1 ± 0.02 µg/mL.

Exploring Physiology Through Working Model Preparation by Undergraduate Students.

BACKGROUND: Physiology is a foundation for studying medicine. Student-centred learning methods are needed for a better understanding of the subject. Preparation of working models by students in Physiology is expected to provide better understanding of the subject since they learn by doing these themselves. The present study was designed to understand the effectiveness of a working model making activity for first-year undergraduate medical students. METHODS: The participants were 97 first-year medical undergraduate students. These students were divided into teams. The topics to prepare working models were chosen by the students according to their interests. The models were prepared by using clay, thermocol, batteries, motors, etc. by the students. These models were displayed in an exhibition organized by the department and marks were awarded to the students according to their performance. A feedback questionnaire form was provided to the students, which they had to complete individually. The questionnaires were analyzed to understand the perception of students regarding the activity. RESULTS: Of the students, 35% strongly agreed and 52% agreed that model making was a useful exercise and helped them in understanding Physiology. Of the students, 27% strongly agreed and 50% agreed that their understanding improved with this assignment and 32% of students strongly agreed and 58% agreed that this activity allowed them to analyze the topic and think logically. Of the students, 36% strongly agreed and 50% agreed that they gained confidence in the topic while they were preparing the model and seeing it functioning. Of the students, 37% strongly agreed and 46% agreed that they had the opportunity to work in a team. Of the students, 39% strongly agreed and 47% agreed that faculty had supported them appropriately. Most of the students agreed that they would recommend such activities to their friends studying in medical colleges elsewhere. CONCLUSION: The students found the activity not only interesting but useful and would encourage their friends studying elsewhere to participate in such activities.

Toxic Chemical from Plastics Attenuates Phenylbiguanide-induced Cardio-respiratory Reflexes in Anaesthetized Rats.

Bisphenol A (BPA) attenuated phenylbiguanide (PBG)-induced cardio-respiratory reflexes involving decreased vagal afferent activity. BPA leaches out from plastics thus it is expected that chronic exposure to plastic boiled (PBW) water will also produce similar changes. Therefore, the present study was undertaken to evaluate the effects of chronic ingestion of PBW on PBG evoked reflexes and were compared with BPA. Adult female rats were ingested BPA containing pellets (2 µg/kg body weight)/PBW/tap water (ad libitum) for 30 days. On day 30, the animals were anaesthetized and BP, ECG and respiratory excursions were recorded. Further, PBG was injected intravenously to evoke cardio-respiratory reflexes and at the end lungs were excised for histopathological examination. BPA concentration in PBW was 6.6 µg/ml estimated by HPLC. In rats receiving tap water, PBG produced bradycardia, hypotension and tachypnoea. In PBW/BPA treated groups, PBG-induced reflexes were attenuated significantly along with emphysematous and consolidative changes in lungs. The present results indicate that PBW attenuates the protective cardio-respiratory reflexes and also produces histopathological changes in lungs.

Bisphenol A attenuates phenylbiguanide-induced cardio-respiratory reflexes in anaesthetized rats.

Bisphenol A (BPA), a toxic chemical released from plastics, produces respiratory arrest and hypotension after a latency. The latency was similar to the reflex apnoea induced by the vagal C fibre stimulation. Therefore, the present study was undertaken to examine the effects of chronic and acute exposure to BPA on cardio-respiratory reflexes elicited by phenylbiguanide (PBG). Acute and chronic experiments were performed on adult female rats. In chronic experiments, the animals were ingested with pellets containing BPA (2 µg/kg body weight) or without BPA (time-matched control) for 30 days. Subsequently, the animals were anaesthetized and prepared for recording blood pressure, ECG and respiratory excursions. PBG was injected through jugular vein to evoke reflexes in these animals. In acute experiments, the PBG reflexes were obtained before and after injecting BPA/ethanol. Also vagal afferent activity was recorded in some rats. In time-matched control rats, PBG produced bradycardia, hypotension and tachypnoea over a period of time. The maximal changes were around 50-65%. In BPA treated group, the PBG-induced heart rate and respiratory frequency changes were attenuated significantly. Acute exposure of animals to BPA (35 mg/kg body weight) for 30 min also attenuated the PBG-induced responses significantly. The attenuation of the PBG reflex responses by BPA in acute experiments was associated with decreased vagal afferent activity. The present results indicate that BPA attenuates the protective cardio-respiratory reflexes due to decreased vagal afferent activity.