Caffeine intake during pregnancy and adverse outcomes: An integrative review

The Fetal Effect of Maternal Caffeine Consumption During Pregnancy-A Review

Caffeine is commonly used to excess by the general public, and most pregnant women drink caffeine on a daily basis, which can become a habit. Maternal caffeine intake during pregnancy is associated with severe gestational outcomes. Due to its lipophilic nature, caffeine can cross the blood-brain barrier, placental barrier, and even amniotic fluid. It can be found in substantive amounts in breast milk and semen. There has been a reported drop in neonatal anthropometric measurements with increased caffeine consumption in some cohort studies. This narrative review using literature titles and abstracts from the electronic databases of PubMed, Embase, and Scopus investigates the data linking maternal caffeine use to unfavorable pregnancy outcomes. It also evaluates the validity of the recommendations made by health professionals on caffeine consumption by mothers from the available literature. The results of our comprehensive literature search of case-control studies, cohort studies, randomized control trials, and meta-analyses, imply that caffeine use during pregnancy is linked to miscarriage, stillbirth, low birth weight, and babies that are small for gestational age. It was also found that there may be effects on the neurodevelopment of the child and links to obesity and acute leukemia. These effects can even be seen at doses well below the daily advised limit of 200 mg. The genetic variations in caffeine metabolism and epigenetic changes may play a role in the differential response to caffeine doses. It is crucial that women obtain solid, evidence-based guidance regarding the possible risks associated with caffeine.

Common Questions and Misconceptions About Energy Drinks: What Does the Scientific Evidence Really Show?

Energy drinks are a commonly consumed beverage, and studies suggest a possible performance-enhancing effect. A Google Scholar search using the keywords "energy drinks" and "exercise" yields numerous results, underscoring the voluminous research on this topic. However, there are questions regarding the effectiveness and safety of energy drinks. These questions include, but are not limited to: (1) What are the main active ingredients in energy drinks? (2) Do energy drinks assist in weight management? (3) Do energy drinks enhance aerobic performance? (4) Do energy drinks enhance athletic speed? (5) Do energy drinks improve reaction time? (6) Do energy drinks enhance lean tissue mass? (7) Can energy drinks improve cognitive performance? (8) Does the acute consumption of energy drinks elevate resting energy expenditure? (9) Is there any evidence to suggest that energy drinks are more effective than an identical serving of caffeine alone? (10) Are there sex differences in the response to energy drink consumption? (11) Do energy drinks affect sleep or sleepiness? (12) Should pregnant women avoid energy drinks? (13) Do energy drinks adversely affect cardiovascular function? (14) Does consuming energy drinks cause brain damage? (15) What are other safety considerations regarding energy drinks? (16) Is there any evidence to suggest that energy drinks are more effective than an identical serving of caffeine alone? (17) If caffeine is the main active ingredient in energy drinks and coffee, why is there a discrepancy in the adverse events reported for each? To address these questions, we performed an evidence-based scientific evaluation of the literature on energy drink supplementation.

Mitigation of caffeine micropollutants in wastewater through Ag-doped ZnO photocatalyst: mechanism and environmental impacts

Micropollutants, such as caffeine (M-CF), pose a significant threat to ecosystems and human health through water and food sources. The utilization of metal oxide-based photocatalysts has proven to be an effective treatment method for the removal of organic pollutants. This study explores the efficacy of Ag-doped ZnO (Ag/ZnO) for removing M-CF from wastewater. The characterization of Ag/ZnO underscores the crucial role of band gap energy in the photocatalytic degradation process. This parameter influences the separation of electrons and holes (e-/h+) and the generation of reactive radicals. Under solar light, Ag/ZnO demonstrated markedly superior photocatalytic activity, achieving an impressive degradation efficiency of approximately 93.4%, in stark contrast to the 53.2% occurred by ZnO. Moreover, Ag/ZnO exhibited a remarkable degradation efficiency of M-CF in wastewater, reaching 83.5%. A key advantage of Ag/ZnO lies in its potential for recovery and reuse in subsequent treatments, contributing to a reduction in operational costs for industrial wastewater treatment. Impressively, even after five cycles, Ag/ZnO maintained a noteworthy photodegradation rate of M-CF at 78.6%. These results strongly suggest that Ag/ZnO presents a promising solution for the removal of micropollutants in wastewater, with potential scalability for industrial and large-scale applications.