Smoking and Secondhand Smoke

Course #51784-


Study Points

  1. Describe the history of tobacco and its impact on society.
  2. Define the prevalence and economic impact of tobacco smoke exposure on public health.
  3. Differentiate between available tobacco products.
  4. Describe the neurophysiologic effects and addictive components of tobacco smoke.
  5. Describe the anatomy and physiology of smoke inhalation, and outline key points in learning of behavior.
  6. Define the psychologic and physiologic aspects of smoking dependence.
  7. List the common health complications related to smoke exposure.
  8. Identify the common comorbid conditions of tobacco users.
  9. Describe the developmental complications related to prenatal exposure to smoke.
  10. Define the effects of exposure to secondhand smoke for children and adults.
  11. Identify the methods of detecting and measuring tobacco smoke exposure.
  12. Define thirdhand smoke.
  13. Outline the methods of tobacco cessation interventions, including necessary considerations for non-English-proficient patients.
  14. Define the treatment modalities for tobacco addiction, including pharmacologic options.
  15. Identify strategies to reduce exposure to tobacco smoke.

    1 . Tobacco was originally marketed in Europe for many ailments, including
    A) insomnia.
    B) dental pain.
    C) rheumatism.
    D) acute appendicitis.

    HISTORY OF TOBACCO USE AND RESTRICTION

    Tobacco was the first export of the New World and was marketed in Europe as a remedy for stress, ulcers, headaches, asthma, and even rheumatism. Tobacco's botanical name, Nicotiana tabacum, is derived from Jean Nicot, a French ambassador to Portugal who, convinced of tobacco's medicinal value, sent the plant's seeds to the royal family in France [2].

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    2 . Early warnings of tobacco's detrimental effects can be traced to the publication of A Counterblaste to Tobacco, which was published by
    A) John Rolfe.
    B) Jean Nicot.
    C) King James I.
    D) Christopher Columbus.

    HISTORY OF TOBACCO USE AND RESTRICTION

    Tobacco product use has been discouraged in the United States and abroad for centuries. In 1586 the first recorded tobacco prohibition was issued by Pope Sixtus V, who declared it a sin "for any priest to use tobacco before celebrating or administering communion." In 1604, King James I published A Counterblaste to Tobacco, describing smoking tobacco as, "a custome lothsome to the eye, hatefull to the Nose, harmefull to the braine, [and] dangerous to the Lungs" [3]. Tobacco use and distribution saw further restrictions across the globe in the early 1600s. King James I levied heavy taxes on tobacco, the czar of Russia exiled tobacco users, and the Chinese executed persons caught selling tobacco [4].

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    3 . Which of the following statements about smoking prevalence is TRUE?
    A) Current use of any tobacco product is highest among Hispanics.
    B) Approximately 1.6 million Americans initiated cigarette smoking in 2019.
    C) More than 20% of the U.S. population 18 years of age or older are current smokers.
    D) Higher levels of education are correlated with an increased likelihood of having smoked cigarettes in the past month.

    PREVALENCE AND ECONOMIC IMPACT OF SMOKING

    Approximately 480,000 Americans die each year as a result of active and/or passive smoking-related health consequences [12]. Despite the seemingly well-known and highly publicized health consequences of smoking, 13.9% of the U.S. population 18 years of age or older are current cigarette smokers [460]. Former U.S. Assistant Secretary for Health Howard Koh asserted that although evidence-based tools were successful in substantially reducing smoking prevalence between 1997 and 2004, efforts were not applied to their full potential nationwide, limiting the efficacy of anti-smoking campaigns [14]. Other experts have attributed declines in cigarette smoking to anti-smoking advertisements, stigma, smoking bans, and increased taxation [460]. Evidence-based tools remain valuable, indicated by slow, steady downward prevalence trends since 1997. However, they are only useful if they reach an audience. These tools seem not to be preventing the initiation of new smokers, despite the overall reductions in use [14,15].

    Nearly 1.6 million Americans initiated cigarette smoking in 2019, continuing a downward trend noted since 2006 (down from approximately 2.5 million); 34% of these were 12 to 17 years of age [13]. About one-third of new smokers will ultimately die from a smoking-related illness [16]. Higher levels of education are correlated with a lower likelihood of having smoked cigarettes in the past month [13]. The number of first-time cigar users is slowly declining, from 3.4 million in 2006 to 2.1 million in 2019 [13]. In 2019, use in the past year of any tobacco product was highest among American Indians/Alaska Natives (39.8%) followed by persons of two or more races (35.2%), White Americans (28.6%), Black Americans (27.2%), Hispanics (19.5%), and Asians (13.2%) [13].

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    4 . All of the following are TRUE about bidis, EXCEPT:
    A) Bidis are filled with sun-dried tobacco.
    B) Bidis can be vanilla or cherry flavored.
    C) Bidis contain more ammonia than a regular cigarette.
    D) Bidis are rolled into air-cured and fermented tobacco wrappers.

    TOBACCO AND NICOTINE PRODUCTS

    Bidis consist of sun-dried tobacco, finely ground and rolled into a leaf of the Diospyros melanoxylon plant native to India. They contain concentrated tobacco, with an average 21.2 mg/g of nicotine compared with 16.3 mg/g of nicotine in filtered and 13.5 mg/g in unfiltered cigarettes, but have less total nicotine because they are shorter [35]. Nonetheless, an unfiltered bidi can release three to five times more tar and nicotine and contain more ammonia and carbon monoxide (CO) than a regular cigarette. Bidis look similar to small cigars or marijuana cigarettes and are available filtered or unfiltered in many flavors, including vanilla, chocolate, strawberry, cherry, and menthol [36]. Bidis are not commonly used in the United States, and sale and distribution is banned in some states (e.g., Illinois, Vermont, West Virginia). However, these products are available on the Internet [37].

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    5 . Kreteks, or clove cigarettes, are composed of approximately what percentage of tobacco?
    A) 5% to 15%
    B) 20% to 40%
    C) 40% to 60%
    D) 60% to 80%

    TOBACCO AND NICOTINE PRODUCTS

    Kreteks, or clove cigarettes, are composed of a mixture of tobacco (60% to 80%) and ground clove buds (20% to 40%), available with or without filters [38]. A popular, representative kretek brand contains less nicotine than popular cigarettes (7.39 mg), but smokers extract equal amounts of nicotine by altering smoking behavior [39]. For example, clove cigarettes can be smoked slower, using more puffs. Overall, smokers will do whatever is necessary to achieve plasma levels of nicotine comparable to their usual brand of cigarette.

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    6 . Mainstream smoke is
    A) smoke inhaled by the smoker.
    B) smoke exhaled by the smoker.
    C) the main component of secondhand smoke.
    D) smoke emitted by the burning end of a cigarette.

    CIGARETTE SMOKE

    Cigarette smoke is a complex mixture of more than 7,000 components, including nicotine, aromatic hydrocarbons, sterols and oxygenated isoprenoid compounds, aldehydes, nitriles, cyclic ethers, and sulfur compounds [62,63,134]. At least 70 of these components are known to cause cancer [134]. Firsthand smoke is defined as the smoke that the smoker inhales. Smoking tobacco products also generates environmental tobacco smoke, also known as SHS and passive smoke, which consists of both exhaled mainstream and sidestream smoke. These two forms of smoke differ in chemical composition and have different temperatures and oxygen levels during generation. The burning end of a cigarette produces sidestream smoke, which in turn is the main component of SHS. Some known toxins of the thousands of chemical constituents in tobacco smoke are also present in SHS, including benzene, cadmium, ethylbenzene, formaldehyde, hydrazine, lead, limonene, methylamine, methylene chloride, nicotine, pyridine, toluene, and radioactive polonium-210 [64,65,66]. One study identified indoor air pollution from SHS as 10 times greater than diesel car exhaust [67].

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    7 . Though it varies between smokers, the breathing pattern of a smoker is different from normal tidal breathing because it is
    A) deeper and slower.
    B) shallower and slower.
    C) deeper and more rapid.
    D) shallower and more rapid.

    ANATOMY AND PHYSIOLOGY OF SMOKE INHALATION

    Administration of any drug via smoking is a highly efficient route, allowing rapid delivery to the brain. This act involves inhalation of a small volume of smoke (an average of about 35 mL for cigarettes) into the mouth from which it is drawn into the lungs [75]. The breathing pattern employed is different from normal tidal breathing in that a smoker's inhalation is deeper and more rapid, drawing the smoke in as a bolus at the beginning of inhalation [76]. However, this pattern varies greatly between smokers and during the course of consuming a single cigarette [77]. Uptake of smoke ingredients is determined by many factors, including chemical composition, smoker's inhalation behavior, lung morphology, and physiologic parameters such as tidal volume, vital capacity, rate of breathing, and rate of lung clearance [78]. Individual differences in size, metabolism, and genetics may also play a role. One hypothesis suggests that stimulation of nicotine-sensitive receptors in the upper airway by various elements of smoke governs the amount inhaled. Indeed, application of a topical anesthetic to the upper airway reduces the quantity of smoke inhaled [79].

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    8 . After the commencement of smoking, nicotine from cigarette smoke reaches peak plasma concentrations in
    A) 20 to 30 seconds.
    B) 1.5 to 3 minutes.
    C) 20 to 30 minutes.
    D) one to three hours.

    ANATOMY AND PHYSIOLOGY OF SMOKE INHALATION

    Cigarettes deliver nicotine in a pulsatile manner, with plasma concentrations reaching their peak within 1.5 to 3 minutes of the commencement of smoking and gradually returning toward baseline within two to three hours [82]. Thus, nicotine levels rise and fall throughout the day with each cigarette smoked, declining to minimum amounts found in nonsmokers in the morning after the extended abstinence period of sleep. Such continuous flux in blood nicotine levels locks the user into an endless cycle of ups and downs and is thought to lead to the commonly held notion that smoking has a positive effect on mood. Considering smokers begin to experience withdrawal symptoms within hours of their last cigarette, and because these unpleasant effects are almost completely alleviated by smoking, this perception is hardly surprising. Daily repetition of this process links these perceived positive health benefits to the act of smoking in the smoker's mind and often results in the false identification of cigarettes as an effective form of self-medication [83].

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    9 . Which of the following is NOT a risk factor for the development of a smoking habit?
    A) Affiliation with smoking peers
    B) Comorbid psychiatric disorders
    C) Disinterest in body image in girls
    D) Presence of a smoker in the household

    LEARNING OF BEHAVIOR

    Much research has been dedicated to uncovering reasons for the development of a smoking habit. Risk factors include [86]:

    • Presence of a smoker in the household

    • Single parent home and/or strained relationship with parent

    • Comorbid psychiatric disorders

    • Low level of expressed self-esteem and self-worth

    • Poor academic performance

    • In boys, high levels of aggression and rebelliousness

    • In girls, preoccupation with weight and body image

    • Increased adolescent perception of parental approval of smoking

    • Affiliation with smoking peers

    • Availability of cigarettes

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    10 . Cigarette smoke affects many organ systems, but the one with the most clinical importance in developing dependence is the
    A) skeletal system.
    B) circulatory system.
    C) respiratory system.
    D) central nervous system.

    SMOKING DEPENDENCE

    Active components of cigarette smoke affect many organ systems, but the effects on the CNS may be of most clinical importance due to its mediating role in dependence. Central effects of nicotine include electroencephalogram (EEG) desynchronization, with a shift toward higher frequency [110]. Studies have demonstrated that nicotine from cigarette smoke reduces global cerebral blood flow (gCBF), most markedly in the right hemisphere, and increases regional cerebral blood flow (rCBF) by more than 10% in the cerebellum, occipital cortex, and insula. Decreases in rCBF have been observed in such subcortical structures as the hippocampus, anterior cingulate, amygdala, and nucleus accumbens [111]. Positron emission tomography (PET) studies show that nasal nicotine administration increases cerebral glucose metabolism in the left inferior frontal gyrus, left posterior cingulate gyrus, left lateral occipitotemporal gyrus, left and right cuneus, and right thalamus, while it decreases glucose metabolism in the left insula and the right inferior occipital gyrus [112].

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    11 . Studies have shown that nicotine from cigarette smoke reduces global cerebral blood flow most markedly in the
    A) insula.
    B) cerebellum.
    C) occipital cortex.
    D) right hemisphere.

    SMOKING DEPENDENCE

    Active components of cigarette smoke affect many organ systems, but the effects on the CNS may be of most clinical importance due to its mediating role in dependence. Central effects of nicotine include electroencephalogram (EEG) desynchronization, with a shift toward higher frequency [110]. Studies have demonstrated that nicotine from cigarette smoke reduces global cerebral blood flow (gCBF), most markedly in the right hemisphere, and increases regional cerebral blood flow (rCBF) by more than 10% in the cerebellum, occipital cortex, and insula. Decreases in rCBF have been observed in such subcortical structures as the hippocampus, anterior cingulate, amygdala, and nucleus accumbens [111]. Positron emission tomography (PET) studies show that nasal nicotine administration increases cerebral glucose metabolism in the left inferior frontal gyrus, left posterior cingulate gyrus, left lateral occipitotemporal gyrus, left and right cuneus, and right thalamus, while it decreases glucose metabolism in the left insula and the right inferior occipital gyrus [112].

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    12 . Neurons located in the ventral tegmental area become more active with nicotine administration, leading to
    A) an increase of hunger.
    B) a stimulation of dysphoria.
    C) an increase in dopamine release.
    D) a reduction in self-administered nicotine.

    SMOKING DEPENDENCE

    Further, the physiology of nicotine dependence has been characterized as biphasic; it stimulates the pleasure response in the brain and creates a relaxed state. As with cocaine, amphetamines, and morphine, addiction to nicotine is believed to result from increased release of dopamine in the nucleus accumbens. Nicotinic acetylcholine receptors are located throughout the CNS. Neurons located in the ventral tegmental area become more active with nicotine administration, leading to an increase in dopamine release into the nucleus accumbens [113]. Indeed, lesions to these pathways reduce rates of self-administered nicotine [114].

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    13 . Which of the following statements about the psychologic effects of smoking is TRUE?
    A) Smoking decreases stress.
    B) Smoking increases concentration.
    C) Smoking gives a true sense of pleasure and release.
    D) Smoking causes a decline in cognitive functioning.

    SMOKING DEPENDENCE

    Many smokers believe that smoking improves concentration, treats stress, and gives pleasure. These beliefs are false. The light-headed feeling that may accompany the act of smoking gives the smoker a false sense of pleasure or release. However, smoking actually causes a decline in physical and cognitive functioning. Additionally, a study by Ota et al. showed that nurses in Japan indulged in smoking as a result of the psychologic demands of their jobs, and this psychologic job demand was positively correlated with their Tobacco Dependence Screener score. The nurses associated stressful tasks with dysphoria, insomnia, anxiety, and other symptoms similar to that of nicotine withdrawal. To alleviate these symptoms, the nurses would smoke and become increasingly psychologically dependent on nicotine with each demanding occupational event [115].

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    14 . What percentage of smokers develop COPD?
    A) Less than 5%
    B) 15% to 20%
    C) 20% to 30%
    D) More than 35%

    HEALTH COMPLICATIONS RELATED TO SMOKING

    Smoking is the main cause of COPD, which encompasses both chronic bronchitis and emphysema. Between 20% and 30% of smokers (or about 1 in 4) will develop COPD, and risk is determined largely based on genetic susceptibility coupled with age at smoking initiation [117,118]. It is very rare in nonsmokers; at least 80% of deaths from this disease can be attributed to cigarette smoking. The risk of death from COPD rises concurrently with the number of cigarettes smoked. If smokers with COPD quit smoking while they are still young, an improvement in lung function can be expected. However, such improvement is not possible in older people, although after cessation further deterioration will run parallel to that of nonsmokers.

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    15 . Cigarette smoking
    A) decreases thrombosis.
    B) decreases inflammation.
    C) impacts endothelial function.
    D) decreases oxidation of low-density lipoprotein cholesterol.

    HEALTH COMPLICATIONS RELATED TO SMOKING

    Cardiovascular disease, defined as acute myocardial infarction (MI) and stroke, is strongly related to smoking and comprises 34% of smoking-related mortality; conversely, smoking yields 16% of cardiovascular-related mortality [62]. The relative risk of MI for smokers has been estimated at 2.88 for men and 3.85 for women, and the relative risk of stroke for smokers is estimated at 2.80. These estimates do not include the effects of passive smoking. Low-tar cigarettes and smokeless tobacco have similarly been shown to increase the risk of cardiovascular events among users in comparison to nonsmokers [127]. Cigarette smoking impacts all phases of atherosclerosis, from endothelial dysfunction to acute clinical events. Both active and passive cigarette smoke exposure predispose to cardiovascular events. The exact toxic components of cigarette smoke and the mechanisms involved in smoking that are related to cardiovascular dysfunction are largely unknown, but smoking increases inflammation, thrombosis, and oxidation of low-density lipoprotein cholesterol (LDL-C). Experimental and clinical data support the hypothesis that increased oxidative exposure may be a potential mechanism for initiating cardiovascular dysfunction. Research also suggests that small doses of toxic materials from tobacco smoke cause a nonlinear dose-response effect on cardiovascular function [128]. The risk for cardiovascular disease declines rapidly after smoking is ceased [129].

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    16 . What percentage of persons with alcohol use disorder also smoke cigarettes?
    A) 25% to 40%
    B) 40% to 65%
    C) 65% to 80%
    D) 80% to 95%

    COMORBID CONDITIONS

    There is a strong comorbidity between alcohol consumption and tobacco use. Drinkers are more likely to smoke than nondrinkers, and smokers are more likely to drink than nonsmokers [149]. In fact, smokers are 30% more likely to consume alcohol and 10 times more likely to develop alcoholism than nonsmokers. Between 80% and 95% of all persons with alcohol use disorder also smoke cigarettes, and 70% are heavy smokers who consume more than one pack per day [150]. A study examining an association between alcohol and tobacco, using a combination of short-term (1-year) and long-term (15-year) follow-up intervals, found that past-year alcohol and tobacco use disorders were associated not only cross-sectionally, but also prospectively. These associations were present even after controlling for age, gender, and race. Year 1 tobacco dependence prospectively predicted diagnosis with an alcohol use disorder (AUD) at year 2, and a baseline diagnosis of AUD increased the likelihood of diagnosis with tobacco dependence 15 years later. Having been diagnosed with tobacco dependence at year 1 predicted AUD persistence, and vice versa. These findings demonstrate the complex association between tobacco dependence and AUDs [151]. Similarly, a study examining the natural course of AUDs from adolescence to early adulthood found that daily smoking predicted future AUD when adolescent AUD and other disorders were controlled. It is possible that chronic smoking may contribute to alcohol tolerance, increasing alcohol consumption and metabolism [152].

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    17 . Smoking is highly comorbid with
    A) schizophrenia.
    B) panic disorder.
    C) major depression.
    D) All of the above

    COMORBID CONDITIONS

    Smoking is shown to be highly comorbid with such psychiatric disorders as major depression, panic disorder, and schizophrenia. Cigarette smoke has other psychoactive properties apart from nicotinic receptor stimulation. For example, it inhibits MAO, which is the enzyme responsible for breaking down the biogenic amine neurotransmitters norepinephrine, serotonin, and dopamine in the brain [155,156]. Not surprisingly, the association between smoking and major depression is well established [157,158,159]. Reports of severe major depressive episodes after smoking cessation are also common, with the onset of depressive symptoms ranging from two days to six weeks after the initial abstinence from smoking [160,161]. In some cases, depression was alleviated with the use of NRT or antidepressants; in others, depressive symptoms went away after a relapse to smoking [160,162]. In a trial of smoking cessation using fluoxetine (30 mg), 7% of participants with a previous history of major depressive disorder (MDD) were diagnosed with major depressive episodes after a 10-week treatment, suggesting that a subset of smokers may be particularly at risk for developing MDD after smoking cessation [163].

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    18 . Fetal nicotine exposure
    A) elicits only a short-term alteration in brain cells.
    B) stimulates an increase in arousal responsiveness to hypoxia.
    C) has no adverse effect on eventual programming of synaptic competence.
    D) results in permanent abnormalities of the dopaminergic regulation of the brain.

    FETAL EXPOSURE

    Fetal nicotine exposure can result in permanent abnormalities of the dopaminergic regulation of the brain [198]. These effects can occur even at low nicotine doses and lead to a greater nicotine dependence [182]. Unlike in mature organisms, where stimulation of a target cell elicits only a short-term response, receptor stimulation in the developing systems interacts with the genes controlling cell differentiation, permanently altering the cells' responsiveness. Nicotine exposure to the prenatal brain may also prematurely stimulate the shift from proliferation to differentiation; thus, nicotine may act as a cholinergic signal, mimicking trophic effects of acetylcholine. Because of the close regulatory association of cholinergic and catecholaminergic systems, adverse effects of nicotine involve multiple transmitter pathways and influence not only the immediate developmental events in the fetal brain but also the eventual programming of synaptic competence. Therefore, defects may appear after a prolonged period of apparent normality, leading to cognitive and learning defects that appear in childhood or adolescence. Similar modifications occur in peripheral autonomic pathways, leading to increased susceptibility to hypoxia-induced brain damage and perinatal mortality [199]. These changes are especially prominent in tissues rich in nicotinic cholinergic receptors, such as the brainstem [200].

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    19 . On average, fetuses of mothers who smoke
    A) have altered cardiac cell differentiation.
    B) are less likely to develop ventricular arrhythmias.
    C) have an increased number of cardiac ß-adrenergic receptors.
    D) manifest a decrease in cardiac volume growth between 23 and 27 weeks' gestation.

    FETAL EXPOSURE

    Maternal smoking during pregnancy poses severe risks to the developing fetal heart. Nicotine alters cardiac cell differentiation to increase the cellular injury caused by hypoxia [210]. Prenatal nicotine exposure interferes with the ability of neonatal adrenal glands to secrete catecholamines in response to hypoxia [200]. Given that the neonatal heart lacks functional sympathetic innervation, there is virtually a complete dependence on circulating catecholamines secreted by the adrenal medulla to maintain heart rate response to hypoxia. Nicotine exposure reduces the number of cardiac ß-adrenergic receptors, magnifying functional consequences of impaired catecholamine release [211]. The resultant impaired cardiac function can lead to cardiovascular collapse, subsequent brain damage, and/or death during delivery [212,213].

    Adenosine diphosphate (ADP) is a major factor in determining electrical stability of myocytes, because the longer the action potential, the higher the likelihood of abnormal cardiac activity [214]. It is possible that a component in smoke temporarily disables electrical properties of ventricular myocytes, rendering the ventricular muscle more susceptible to developing arrhythmias [215].

    Fetuses exposed to smoke also manifest an increase in cardiac volume growth between 23 and 27 weeks' gestation [216,217]. This could be attributed to either an exaggeration of normal cardiac growth patterns or a compensatory response to an increase in upper body growth at the time.

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    20 . Which of the following statements about the effects of pediatric exposure to SHS is TRUE?
    A) Nicotine exposure elicits an increase in physical fitness.
    B) Young children have lower ventilation rates and therefore lower levels of SHS exposure.
    C) Parental smoking is negatively correlated to their offspring's smoking as adolescents and adults.
    D) SHS exposure during childhood is potentially more dangerous to neurodevelopment than in utero exposure.

    PASSIVE SMOKING EFFECTS ON CHILDREN

    It is possible that SHS exposure during childhood may be potentially more hazardous to neurodevelopment than in utero exposure to maternal smoking. Young children have higher ventilation rates, meaning they receive higher levels of SHS for the same duration and level of external exposure [244]. Passive smoking is believed to increase the prevalence of sudden infant death syndrome (SIDS); exacerbate asthma symptoms; interfere with cognition and behavior; increase cancer risk; and cause respiratory tract illness [226,245,246]. Breastfed infants with a smoking or snuff-taking mother are exposed to nicotine in breast milk, with a mean intake of nicotine of 7 mcg/kg per day [247]. Older children experience decreased physical fitness and are susceptible to tobacco-related illnesses just as adult smokers are.

    Aside from adverse health effects due to SHS exposure, parental smoking is also positively correlated to their offspring's smoking as adolescents and adults. Counseling parents on the adverse health effects of SHS on children has been shown to dramatically reduce their children's subsequent cigarette smoke exposure [6,246]. Smokers should be encouraged to smoke outside their homes and minimize SHS exposure to their children [248]. However, studies have shown that, though smoking outdoors decreases SHS exposure, children of parents who smoke outdoors still have higher prevalence of ear infections and respiratory symptoms than children of nonsmokers [249].

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    21 . Active and passive smoking are known to
    A) decrease incidences of thrombosis.
    B) decrease occurrences of atherosclerosis.
    C) increase incidences of cardiac arrhythmias.
    D) promote the oxygen-carrying capacity of blood.

    PASSIVE SMOKING EFFECTS ON ADULTS

    A strong association between active smoking and coronary heart disease has been well established, and one study found a 50% to 60% increase in risk for coronary heart disease development in passive smokers [308,309]. Active and passive smoking are known to [310]:

    • Increase the incidence and frequency to cardiac arrhythmias

    • Decrease the oxygen-carrying capacity of blood

    • Increase the incidence of coronary artery spasm

    • Promote atherosclerosis, thereby increasing the risk of cardiovascular disease

    • Increase the incidence and tendency for thrombosis

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    22 . Adult exposure to SHS is associated with
    A) asthma.
    B) decreased bronchial responsiveness.
    C) a dramatic impairment of lung function.
    D) All of the above

    PASSIVE SMOKING EFFECTS ON ADULTS

    Environmental tobacco smoke exposure is associated with respiratory symptoms, asthma, a slight impairment of lung function, and increased bronchial responsiveness [322]. A Swiss study on air pollution and lung diseases with a sample of 4,197 nonsmoking adults, showed that SHS was associated with increased risk of asthma, wheezing, bronchitis, and dyspnea [323]. Greater levels of cumulative exposure to tobacco smoke in the home and workplace are also associated with an increased risk of COPD [324]. In 2005, it was estimated that a (hypothetical) elimination of SHS in home and work environments would decrease COPD diagnoses in the United States by 18% (or 11% and 7%, respectively).

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    23 . Cotinine can be found in all of the following, EXCEPT:
    A) Hair
    B) Urine
    C) Blood
    D) Breath

    MEASURING SECONDHAND SMOKE EXPOSURE

    Cotinine can be measured in hair, nails, blood, saliva, or urine samples. Although other biomarkers for environmental tobacco smoke exposure exist, cotinine is currently the most sensitive and specific. Such objective quantification is especially important in studies concerning passive smoke exposure in children, as parental assessment of smoke exposure is frequently unreliable [65,69,277,355,356]. SHS exposure can also be assessed through CO breath analysis, measurement of certain carcinogens (e.g., NNAL can be found in urine, blood, and nails) or benzene, or measurement of respirable suspended particulates in the air [355].

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    24 . The most sensitive biomarker used to confirm the extent of SHS exposure to nonsmokers is
    A) cotinine.
    B) nicotine.
    C) benzine.
    D) albumin.

    MEASURING SECONDHAND SMOKE EXPOSURE

    Cotinine can be measured in hair, nails, blood, saliva, or urine samples. Although other biomarkers for environmental tobacco smoke exposure exist, cotinine is currently the most sensitive and specific. Such objective quantification is especially important in studies concerning passive smoke exposure in children, as parental assessment of smoke exposure is frequently unreliable [65,69,277,355,356]. SHS exposure can also be assessed through CO breath analysis, measurement of certain carcinogens (e.g., NNAL can be found in urine, blood, and nails) or benzene, or measurement of respirable suspended particulates in the air [355].

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    25 . "Thirdhand" smoke is
    A) tobacco smoke contamination of dust.
    B) air in a room where smoking previously occurred.
    C) residual tobacco smoke contamination on surfaces.
    D) All of the above

    THIRDHAND SMOKE

    The term "thirdhand smoke," or "environmental tobacco smoke," has been and is often used synonymously with SHS, but it can be more accurately described as any airborne particulate matter originating from burning tobacco. It is comprised of both active mainstream smoke (tobacco smoke exhaled by active smokers) and sidestream smoke (smoke from the burning end of a cigarette) that is inhaled by nonsmokers, and evidence shows the possibility of harm for a significant period of time after the cigarette/tobacco product has been extinguished.

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    26 . Brief interventions offer
    A) self-help leaflets or videos.
    B) extensive professional input.
    C) nicotine-replacement therapy.
    D) sustained-release bupropion treatment.

    INTERVENTIONS FOR SMOKING CESSATION

    Brief intervention training allows healthcare professionals to offer basic support, ensuring that all smokers who come into contact with these health professionals are able to receive help as appropriate. Brief intervention offers short-term professional input, self-help leaflets and videos, and complementary therapies. This type of information can be applicable for smokers at any level. Milch et al. compared the effects of two brief interventions against treatment as usual. The minimal intervention consisted of a smoking status vital sign stamp, which documents the patient's smoking status. The enhanced intervention consisted of a five-question form that assessed the patient's level of cessation readiness and provided cessation counseling prompts for clinicians. Medical record documentation of screening for smoking and cessation advice and self-reported patient smoking cessation rates were collected 8 to 10 months after implementation. Self-reported patient smoking cessation was higher in the enhanced intervention group (12%) compared with the minimal intervention (2%) and control (4%) groups. This demonstrated that even a short questionnaire that assessed readiness to quit and provided documentation of cessation advice improved rates of clinician cessation advice and patient smoking cessation compared with no intervention [382]. In a study by Smith and Burgess of patients admitted to the hospital with diagnoses of coronary artery disease, a minimal intervention (i.e., advice from physicians and nurses and two pamphlets) resulted in 35% of the group confirmed abstinent at 12 months [383].

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    27 . The Clinical Practice Guideline recommends the 5 A's approach for intervening with a patient who smokes. After the practitioner establishes that a patient smokes by asking about his or her smoking status, the second of the five steps is to
    A) advise the patient to quit.
    B) arrange for follow-up contacts.
    C) assess the patient's willingness to quit.
    D) assist the patient to use problem-solving methods.

    INTERVENTIONS FOR SMOKING CESSATION

    The U.S. Public Health Service Clinical Practice Guideline was updated in 2018, but continues to recommend the 5 A's approach for intervening with the patient who smokes [384,470]:

    • Ask about smoking status

    • Advise to quit

    • Assess willingness to quit

    • Assist by suggesting and encouraging the use of problem-solving methods for cessation

    • Arrange for follow-up contacts and relapse prevention

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    28 . Nicotine-replacement therapy is available in all of the following forms, EXCEPT:
    A) Patches
    B) Shots and implants
    C) Nasal spray and inhalers
    D) Gum, lozenges, and sublingual tablets

    INTERVENTIONS FOR SMOKING CESSATION

    The first-line pharmacologic interventions for smoking cessation are NRT, bupropion, and varenicline [381,403]. However, no pharmacotherapy has been approved for use among pregnant or nursing women. The five forms of NRT available are the patch, gum, lozenge, nasal spray, and inhaler. A Cochrane review found that all commercially available forms of NRT increased the quit rate by 50% to 70%, independent of the intensity of additional support provided to the individual. Although support is beneficial, it does not appear to be essential to the success of NRT [404].

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    29 . The suggested dosage of bupropion for smoking cessation is
    A) 50 mg per day.
    B) 150 mg per day.
    C) 200 mg per day.
    D) 300 mg per day.

    INTERVENTIONS FOR SMOKING CESSATION

    Bupropion is an atypical antidepressant that has both dopaminergic and adrenergic actions [426]. In 1998, the slow-release preparation of bupropion became available as a prescription item specifically for smoking cessation, with the trade name Zyban. This treatment could be appropriate for smokers who do not wish to use an NRT or for those whose treatment with NRT has failed. Unlike NRT, smokers begin bupropion treatment one week prior to cessation. The suggested dosage is 300 mg/day, and the duration of treatment is 7 to 12 weeks [427]. A double-blind, placebo-controlled trial randomized patients to placebo or sustained-released bupropion (50 mg twice a day, 150 mg once a day, or 150 mg twice a day) and treated them for six weeks. Smokers with active depression were excluded, though smokers with a history of depression were not. The cessation rates at the end of therapy were 10.5%, 13.7%, 18.3%, and 24.4%, respectively. Follow-up at one year suggested a continued benefit of bupropion therapy [428]. Data from a study of bupropion combined with transdermal nicotine showed high long-term quit rates with the combination therapy [429]. Discontinuation of treatment may be appropriate for individuals unable to achieve significant progress after seven weeks, as success after this point is unlikely [430].

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    30 . It is estimated that the 2009 tax increase on tobacco products will result in
    A) no change in national smoking patterns.
    B) a decreased level of support for smoking restrictions.
    C) 1.2 million children alive today never becoming smokers.
    D) $4 million in healthcare savings from fewer smoking-related strokes and myocardial infarctions.

    REDUCING TOBACCO SMOKE EXPOSURE

    Effective behavioral and pharmacologic treatments exist and can work if they are affordable, widely available, and used properly in clinics and communities. Smoking cessation group programs have been found to be more effective than minimal treatment programs, although less intensive treatment approaches, when combined with high participation rates, can still influence larger groups. Tobacco policies have reduced cigarette consumption at work and worksite tobacco smoke exposure [454]. Innovative partnerships with public- and population-based organizations to reach smokers and reduce exposure to tobacco have been initiated. There is a high level of support for smoking restrictions in public places to protect nonsmokers from tobacco smoke [455,473]. Due to the 2009 federal tax increase, several health benefits and cost savings were projected, including an increase in the number of children alive today who will not become smokers (1.2 million) and $51.9 billion in long-term healthcare savings from fewer adult and youth smokers over the lifetimes of the adults who quit and kids who never start [451,473].

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