Tobacco Essay, Research Paper
Tobacco is one of the leading preventable causes of death in the United States. Nicotine, which is an alkaloid derived from the tobacco plant, is a potent chemical that has powerful effects on the human body, especially when administered rapidly or at high doses. Prenatal exposure to nicotine is associated with adverse reproductive outcomes, including altered neural structure and functioning, cognitive deficits, and behavior problems in the offspring (9). At least 20% – 30% of pregnant women are estimated to smoke cigarettes, although smoking is associated with low birth weight, prematurity and infant mortality. In the United States, smoking accounts annually for estimated fetal deaths ranging from 19,000 to 141,000, for 1,900 to 4,800 deaths during or immediately after parturition, and for 1,200 to 2,200 death from Sudden Infant Death Syndrome (7).
Maternal smoking has been implicated in long term deficits in infant mental development and adverse behavioral problems in children such as attention disorder. Nicotine crosses the human placenta and has direct effects on the developing fetus. Pre-clinical studies suggest that maternal smoking during pregnancy produces changes on the offspring’s neural functioning, including reductions in uptake of serotonin, alterations in dopaminergic systems, alterations in peripheral and central noradrenergic neurons, and changes in DNA and RNA synthesis in the brain (9). Children prenatally exposed to nicotine consistently score lower in the two subcategories of expressive language and conceptual comprehension.
Evidence from studies of human neonates suggests that maternal smoking during pregnancy is associated with increased rates of neurobehavioral difficulties. Several studies have linked maternal smoking during pregnancy with childhood inattention, impulsivity, and motor hyperactivity in offspring. Similarly, maternal smoking during pregnancy has been associated with parent-teacher ratings of conduct problems in children and a criminal record in young adults. A study by Yousef Tzabi suggested that cigarette smoking during pregnancy may be one of the causes of hyperactivity and learning deficits in children. In a laboratory study with Sprague-Dawley mice, it was shown that hyperactive male pups that were exposed to nicotine prenatally had significantly higher nicotinic receptor concentrations in the cortex than did the controlled pups (8). This study indicates that hyperactivity in male offspring induced by prenatal nicotine exposure is associated with an increase in neuronal nicotinic receptors in the cortex.
A similar study by Lauren S. Wakschlag, on maternal smoking during pregnancy and the risk of conduct disorder in boys, revealed that mothers who smoked more than half a pack of cigarettes daily during pregnancy were significantly more likely to have offspring who met DSM-III-R diagnostic criteria for Conduct Disorder during the preadolescent or adolescent years than women who did not smoke or smoked only occasionally during pregnancy. These findings support previous work showing that maternal smoking during pregnancy is associated with increased rates of preschool and school-age behavior problems and delinquency in the offspring.
The relationship between smoking and low birth weight, prematurity, and miscarriage has been well established. The effects of nicotine are seen in every trimester of pregnancy, from increased spontaneous abortions in the first trimester to increased premature delivery rates and decreased birth weights in the final trimester. In 1957, Simpson first noted in an observational study of 7,499 patients that the incidence of premature delivery, as defined by a birth weight less than 2,500g, was twice as great for the smoking mother as compared with the nonsmoking mother (5). A similar study by Walsh concluded that the smoking mother is at two-fold increased risk for delivering a low birth weight infant than her nonsmoking counterpart.
The birth weight of a baby is dependent on two factors: the gestational age of the fetus at the time of delivery, and the rate of fetal growth up until that point. Nicotine has been shown to affect both of these factors. The average birth weight of infants prenatally exposed to nicotine is 100 to 320g lighter than their nonexposed counterparts (5). Therefore, the rate of delivering a low birth weight or premature infant has remained consistently increased over the past four decades despite advances in prenatal and neonatal care.
There is an overall increase of 33% in perinatal and neonatal mortality when women smoke during their pregnancy. This increase in perinatal mortality is primarily a result of the increase in low birth weight and premature delivery rate seen with tobacco use in pregnancy. The risk of spontaneous abortions, as defined by fetal loss before 20 weeks of gestation, is also 33% higher in smokers compared with controls (5).
A study by T.A. Slotkin, on impaired cardiac function during postnatal hypoxia in rats exposed to nicotine, proposes that maternal smoking correlates highly with parturitional/neonatal death including Sudden Infant Death Syndrome (SIDS). Nicotine exposure of fetal rats reproduces the increased mortality when animals are tested postnatally with hypoxia. Rats exposed to nicotine prenatally show an impaired adrenomedullary response, as well as alterations in brain-stem noradrenergic mechanisms that are likely to participate in cardiorespiratory control (7). Prenatal nicotine exposure reduces cardiac reactivity to circulating catecholamines and to sympathetic neuronal stimulation and may promote cardiac cell damage affecting the reactivity to hypoxia.
The loss of neonatal hypoxia tolerance caused by fetal nicotine exposure results in part from interference with the maintenance of cardiac function. In nicotine-exposed rats, the initial tachycardia was absent and the decline in heart rate was much more rapid and profound. It was found that prenatal nicotine treatment may alter the differentiation and function of cardiac cells such that pacemaker diastolic depolarization is blunted during hypoxia. Nicotine can interfere with catecholamine actions which, when released by hypoxia, are essential to maintain neonatal heart rate. Prenatal nicotine exposure blunts the ability of the neonatal adrenal to secrete catecholamines in response to hypoxia. As the neonatal heart lacks functional sympathetic innervation, there is virtually complete dependence on circulating catecholamines derived from the adrenal medulla in order to maintain the heart rate response to hypoxia (7).
If comparable changes are seen in man, then the results provide a casual explanation for the increased perinatal morbidity and mortality seen in the offspring of smokers. The fetal environment is relatively hypoxic, and corresponding cardiac functional deficits would thus contribute to the high incidence of fetal mortality. Just as impaired cardiac function during hypoxia in neonatal rats can account for the increase in mortality with prolonged hypoxia, comparable effects in man would provide a mechanism for cardiovascular collapse and consequent brain damage or death during delivery.
The consequences of smoking during pregnancy are very dramatic. If clinicians are able to convince their patients to stop smoking early in their pregnancy, a major impact may be made on the incidence of low birth weight infants, perinatal morbidity and mortality, as well as cognitive deficits and behavioral problems in the offspring. A strong statement has to be made on the issue of tobacco exposure during pregnancy. This could be accomplished by informing women that their infants may not only be “smaller” than their nonsmoking counterparts, but their infants may also have transient or permanent changes in their lung and brain ultrastructure. A patient who is informed of these possible long-term effects of nicotine on her child may be more successful with her smoking cessation.