Nicotine Dependence Clinical Trial
Official title:
Extended Duration Varenicline for Smoking Among Cancer Patients: A Clinical Trial
Upwards of 33-50% of cancer patients who smoked prior to diagnosis continue to smoke following diagnosis and treatment. With medical advances in cancer care yielding a growing constituency of cancer survivors, addressing nicotine dependence in this population is a priority. While PHS guidelines recommend acute treatment durations with approved medications for tobacco use, extending the duration of treatment beyond the standard treatment duration significantly increases quit rates, reduces the risk for a relapse, and promotes recovery to abstinence following a lapse. Varenicline may be particularly effective for cancer patients given the drug's beneficial effects on affect and cognition. In this trial, 374 cancer patients will be randomized to standard varenicline treatment (12 weeks active + 12 weeks placebo) or extended varenicline treatment (24 weeks active). The investigators hypothesize that 1) Extended varenicline therapy will increase 24- and 52-week biochemically-confirmed abstinence versus standard varenicline treatment, 2) Quality of life will be rated higher in the extended therapy group versus the standard therapy group, and there will be no significant differences between groups in terms of severe side effects, and 3) Improved affect and reduced cognitive impairment will mediate the effect of extended therapy on quit rates.
BACKGROUND
Prevalence of Smoking among Cancer Patients
The rate of smoking among individuals with cancer who are age 40 or under are substantially
higher (38-40%) than rates of smoking in the comparable age group in the general population
(~26%; Bellizzi et al., 2005; Coups & Ostroff, 2005). Studies with patients that have
traditional tobacco-related cancers show extremely high rates of smoking; upwards of 50% of
head and neck (Duffy et al., 2008) and lung (Cooley et al., 2009) cancer patients report
current smoking. However, high rates of smoking are not unique to such traditional
tobacco-related disease sites. Significant rates of current smoking have been reported among
testicular (19%; Shinn et al., 2007), prostate (16-17%; Gong et al., 2008; Pantarotto et al.,
2007), cervical (21%; Beesley et al., 2008), breast (19%; Li et al., 2009), bladder (18%;
Blanchard et al., 2008), esophageal (39%; Sundelof et al., 2008), colorectal (22%; Vincenzi
et al., 2009), and lymphoma (19%; Geyer et al., 2010) cancer patients. Overall, about
one-third to one-half of cancer patients who were smokers prior to their diagnosis continue
to smoke following diagnosis (Gritz et al., 2006).
Adverse Health Consequences of Smoking among Individuals with Cancer
Continued smoking by cancer patients has been associated with diminished QOL, reduced
survival probability and duration, and increased risk for disease recurrence and a second
primary tumor (Gritz et al., 2006; 2007). Continued smoking by cancer patients is associated
with greater treatment side effects or diminished QOL among head and neck (Duffy et al.,
2007; Zevallos et al., 2009), lung (Daniel et al., 2009), prostate (Ku et al., 2009), and a
heterogeneous group of (Schnoll et al., 2010a) cancer patients. A recent meta-analysis of
studies with lung cancer patients found that continued smoking was associated with an
increased risk of death, recurrence, and a second primary tumor (Parsons et al., 2010).
Likewise, studies with head and neck cancer patients have reported that patients who continue
to smoke following their diagnosis have a lower survival rate and an increased risk for a
recurrence and a second primary tumor (Browman et al., 2002; Hilgert et al., 2009; Fortin et
al., 2009; Leon et al., 2009). Continued smoking has also been associated with reduced
survival among breast (Aksoy et al., 2007), lymphoma (Geyer et al., 2010), esophageal
(Sundelof et al., 2008), prostate (Gong et al., 2008), cervical (Coker et al., 2009), and
bladder (Aveyard et al., 2002) cancer patients and with an increased risk of recurrence or a
second primary tumor among bladder (Fleshner et al., 1999), breast (Li et al., 2009),
lymphoma (Moser et al., 2006), and colorectal (Jacobson et al., 1994) cancer patients.
Continued smoking may worsen prognosis by reducing the effectiveness of chemotherapy (Duarte
et al., 2008; van der Bol et al., 2007; Vincenzi et al., 2009; Hotta et al., 2008) and
radiotherapy (Browman et al., 1993).
Nicotine Dependence Treatments for Those with Cancer
Very few smoking cessation trials have been conducted with this population (Gritz et al.,
2006; 2007) and many of these past trials have used small samples and relied on self-report
for smoking abstinence outcomes (de Moor et al., 2008). After nearly two decades of research
in this area, not a single smoking cessation randomized clinical trial has yielded
significant treatment effects (excluding Emmons et al., 2009, which studied adult survivors
of childhood cancer; de Moor et al., 2008). Nurse-led (Griebel et al., 1998; Stanislaw &
Wewers, 1994; Wewers et al., 1994), physician-led (Browning et al., 2000; Gritz et al., 1993;
Schnoll et al., 2003b), and behavioral (Schnoll et al., 2005; Wakefield et al., 2004) smoking
cessation trials have failed to yield treatment effects for cancer patients. Our recent
clinical trial with bupropion (Schnoll et al., 2010a) found no main effect for the
medication, but bupropion increased abstinence rates, reduced withdrawal symptoms, and
improved QOL more for patients with depression, vs. those without depression. Lastly, a very
recent varenicline study reported end-of-treatment quit rates of 34%, vs. 14% for the
comparison group (OR = 3.14), and a side effect profile that mirrored the general population
(Park et al., 2011). While these data are encouraging, as were reported feasibility data, the
study was under-powered (n = 49) and did not use a randomized design. Thus, there is
currently no empirically-based treatment model for addressing nicotine dependence in the
oncologic context. As such, a recent NCI meeting, with representatives from NCI cancer
centers, concluded that the evaluation of novel smoking cessation interventions for cancer
patients is a critical priority (Morgan et al., 2010).
A Novel Treatment for Cancer Patients who Smoke: Extended Duration Varenicline Thus, nicotine
dependence treatments for cancer patients may show greater efficacy if they adequately
address the patient's relatively high level of nicotine dependence, risk for psychological
distress and cognitive impairment, and delayed relapse process. We hypothesize that extended
duration varenicline (24-weeks) will address these barriers to cessation and significantly
increase quit rates, vs. standard varenicline treatment (12 weeks).
Our rationale for selecting varenicline is as follows. First, the high rate of nicotine
dependence among cancer patients underscores the need to include a pharmacotherapy as part of
treatment. Varenicline is currently the most efficacious FDA-approved medication for nicotine
dependence, yielding quit rates that significantly exceed those produced by bupropion
(Gonzales et al., 2006; Jorenby et al., 2006) and nicotine patch (Aubin et al., 2008; Biazzo
et al., 2010; Stapleton et al., 2008). Second, varenicline mitigates adverse psychological
effects and cognitive impairment associated with quitting smoking (Patterson et al., 2009;
Smith et al., 2009; Philip et al., 2009; Rollema et al., 2009; Sofuoglu et al., 2009). The
anti-depressant-like (Rollema et al., 2009) and cognitive enhancing (Loughead et al., 2010)
effects of varenicline is consistent with what we know about how varenicline works. As a
nicotinic acetylcholine receptor (nAChRs) partial agonist, varenicline binds to nAChRs and
blocks the entry of nicotine (from smoking) into the receptor and stimulates a moderate
release of dopamine. This reduces the rewarding effects of smoking and reduces withdrawal
symptoms (Rollema et al., 2009). Preclinical studies also indicate that α4β2 nAChRs subtypes
are critical for cognition (Levin et al., 2006) and stimulation of these receptors by
varenicline yields improved cognitive function (Loughead et al., 2010). Likewise, animal
studies indicate that the simultaneous activation and desensitization of nAChRs receptors
produced by nicotinic partial agonists like varenicline can yield antidepressant-like effects
(Mineur & Picciotto, 2010), which underlies current evaluations of varenicline as a treatment
for major depression. Third, varenicline is efficacious and safe for treating nicotine
dependence among various clinical populations, including: cardiovascular disease patients
(Rigotti et al., 2010), COPD patients (Tashkin et al., 2010), smokers with comorbid alcohol
(Hays et al., 2010) and cocaine (Poling et al., 2010) dependence, and smokers with comorbid
affective or psychotic disorders (McClure et al., 2010; Smith et al., 2009; Philip et al.,
2009). It has been shown to be safe when taken over 52 weeks (Williams et al., 2007).
Although there have been reports of adverse psychiatric events following varenicline use,
leading the FDA to mandate a boxed warning for varenicline, pooled data from controlled
efficacy trials (Cahill et al., 2009; Tonstad et al., 2010), effectiveness trials (McClure et
al., 2010), and large cohort studies (Gunnell et al., 2009; Kasliwal et al., 2009)
demonstrate that varenicline is safe for treating nicotine dependence, even among smokers
with psychiatric comorbidity, including depression (Stapleton et al., 2008; McClure et al.,
2010; Steinberg et al., 2010).
Our rationale for selecting an extended duration treatment is as follows. First, we have
shown, in a placebo-controlled randomized trial with general population smokers, that
24-weeks of transdermal nicotine, vs. the standard 8-weeks, increases 6-month quit rates by
an OR of 1.81 (32% vs. 20%; Schnoll et al., 2010b). Second, and importantly, extending
treatment with the nicotine patch to 24-weeks significantly helps smokers with high levels of
nicotine dependence and cognitive impairment, in particular, to overcome their liability to
relapse (see below). While extended therapy with transdermal nicotine did not offset the
effect of depression symptoms on relapse rates, the quit rate among depressed smokers in
extended treatment was almost 2-times higher than it was for depressed smokers in standard
treatment (see below). Third, we showed in our placebo-controlled randomized clinical trial
with general population smokers (Schnoll et al., 2010b) that extending treatment with
transdermal nicotine to 24-weeks (vs. 8-weeks) significantly reduced the probability that
smokers would experience a lapse and, importantly, increased the likelihood that smokers
would recover to abstinence following a lapse. Extended duration treatment offered smokers
who lapsed the opportunity to re-start their quit attempt and eventually achieve abstinence.
Thus, extended duration varenicline may be particularly efficacious at addressing the
barriers to cessation that are evident among cancer patients.
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