This study aims to show that the Progressive-Ratio Computer-assisted Alcohol-Infusion System (CAIS) paradigm is a reliable and sensitive method that can be used to examine the motivating properties associated with alcohol self-administration in humans.
The Progressive Ratio (PR) self-administration paradigm is a common pre-clinical method used to examine the motivation for a drug attributed to a craving, reward, or the relief of negative affect. The Computer-assisted Alcohol Infusion System (CAIS) enables intravenous alcohol self-administration behavior in humans. This system provides the investigator with control over the trajectory of each incremental breath alcohol concentration (BrAC) reward and the maximum BrAC allowed in a session. This paradigm allows participants to earn these alcohol rewards using a sequence of button presses specified by the investigator. The system employs a physiologically-based pharmacokinetic model-based algorithm to achieve the same incremental BrAC exposure in every participant. Participants (n = 11) took part in two identical sessions to examine test-retest reliability, and an additional group (n = 73) completed a single session. Sessions began with a 25 min priming phase: participants were instructed to press a button an increasing number of times per reward, accumulating four standardized incremental BrAC trajectories. The second phase comprised an ad-lib, PR paradigm lasting 125 min. Each reward required an increasing number of button presses. Measures of self-administration included: average and peak BrAC, total rewards earned, total grams of ethanol consumed per unit of total body water, the total number of button presses, and the average rate of button pressing. Self-administration measures were highly correlated both between and within sessions, demonstrating test-retest reliability and internal consistency. Recent drinking history was strongly associated with self-administration measures; heavier drinkers chose greater alcohol self-administration. These results indicate the reliability and sensitivity of this progressive-ratio intravenous alcohol self-administration method for assessing the motivational properties of alcohol, with the potential for improved testing of the efficacy of new medications thought to reduce consumption of alcohol. This method can be used to understand the genetic and environmental determinants of alcohol self-administration in humans.
The addictive properties of drugs can be evaluated using self-administration paradigms. Self-administration paradigms have been used to study the development of alcohol dependence in animal models1,2,3, as well as the effectiveness of medications used to treat alcohol dependence by reducing drinking in individuals4,5,6. In order to assess the motivational properties of alcohol, a progressive ratio (PR) schedule paradigm was developed using intravenous alcohol. PR schedules require a pre-defined, increasing amount of work to obtain the next reward. The last completed level of work to obtain a reward (total rewards earned) is called the breaking point (BP). Thus, BP is a measure of the motivation for that reinforcer.
Pre-clinical investigations have used the PR schedule paradigm to assess a variety of factors involved in the motivation to work for ethanol, such as sigma receptors7,8, glucocorticoid receptor9, genetic determinants10, as well as screening for molecular targets for medication development11. Human studies have been less extensive in their use of the PR paradigm to characterize the motivation for seeking alcohol, although it has been used to study other drugs of abuse such as heroin and cocaine12,13.
Human alcohol studies employing a PR schedule have mostly used oral alcohol self-administration methods, examining the effect of naltrexone14, as well as the role of dopamine15 and nicotine16 in alcohol self-administration. In these studies, alcohol is typically administrated by ingestion of a mixture of alcohol at various concentrations in a variety of vehicles and is often conducted in a 'laboratory bar setting'. They offer either "standardized drinks" that contain fixed amounts of alcohol per drink or body weight-adjusted amounts of alcohol per drink4,5,6,17,18, generally setting a maximal exposure. The ingestion PR paradigms encounter several difficulties related to dosing. Substantial variability in the absorption and lesser amounts in the distribution and metabolism of alcohol across participants means that the incremental BrAC trajectory following consumption of each reward cannot be controlled or standardized. The amount of alcohol provided must be limited so that the cumulative BrAC of the fastest absorber does not exceed safe limits19. The motivation to seek alcohol is also subject to variation in the participants' expectations and experience regarding the beverage characteristics employed.
An alternative approach includes the intravenous (IV) administration of alcohol. The intravenous alcohol self-administration system method described here uses a physiologically-based pharmacokinetic (PBPK) model to continuously compute the precise rates of infusion required to produce a specified BrAC. The PBPK model's parameters are individualized, based on known values of age, sex, height, and weight. Compensation for individual differences in the pharmacokinetics of alcohol, and avoidance of the variability in absorption, enables the direct control of incremental exposure to alcohol rather secondarily through its dosing. This real-time adjustment provides the experimenter with control over the time course of a person's incremental BrAC to any desired rate, level, and duration of exposure20,21. The incremental exposures are the same for every participant, yielding a paradigm in which variation in the overall trajectory reflects variation in the participant's motivation rather than pharmacokinetic variations. Since this intravenous alcohol self-administration system computes the future time course of BrAC in real-time, initiation of a reward that would exceed a preset safety limit can be precluded22. Thus, every participant enjoys safe access to the entire range of exposure designed into the experiment. With IV administration, the participant also has no experience on which to base expectations of the consequence of drinking other than the effect of alcohol.
Prior intravenous alcohol self-administration studies using a free-access paradigm demonstrated high variability between individuals in self-administration behavior23 and high test-retest reliability in repeated sessions in healthy non-dependent drinkers24. Intravenous alcohol self-administration was used in a pilot study that employed an attentional task as the form of work required. The study concluded that the paradigm is effective for detecting an interaction between genotype and lorazepam treatment in the motivation for seeking alcohol25. Subsequent work identified sex differences in response to abstinence26. This model has shown to be a human translational parallel model for pre-clinical "wanting" behaviors27. Another study using this system demonstrated that those induced in a negative mood condition who exhibited greater negative urgency scores had a higher breakpoint and higher cumulative work with gender-specific effects28,29.
In the current study, BrAC rewards were delivered by infusing a 6% V/V ethanol solution through a vein in the ante-cubital fossa of the elbow30. Work was defined by the number of button presses necessary to receive an incremental increase in BrAC. The number of button presses increased for each subsequent reward. By the time the participant was working for their 10th reward, s/he was required to press the button 1,600 times, and for the 15th, almost 10,000 times. Each reward comprised a 7.5 mg/dL increase over the current BrAC, ascending at the rate of 3.0 mg/dL per minute for 2.5 min, then descending at the rate of -1.0 mg/dL per minute until the next reward was initiated. The first 25 min comprised four priming exposures prompted 2.5 min apart, i.e., receiving all four priming exposures within the first 10 min, resulting in a peak BrAC close to 30 mg/dL. This procedure allowed the participant to experience an alcohol reward as well as practice using the button. Then the participant rested for 15 min. Following this 25 min priming interval, an ad-lib PR period lasting 2 h began. Measures of self-administration included: average and peak BrAC, total rewards earned, total grams of EtOH consumed per unit of total body water, the total number of button presses, and the average rate of button pressing.
To date, there have been a small number of studies on PR schedules with alcohol in humans and fewer using IV alcohol. Therefore, the study aimed to develop a model with a PR schedule using a computer-assisted self-administration system that humans would respond to. The second aim was to evaluate the test-retest reliability of PR alcohol measures such as BrAC exposure resulting from alcohol self-administration behavior and response in non-dependent healthy participants. The third aim was to examine the influence of recent drinking history and sex on this alcohol self-administration behavior. Because the incremental BrAC exposure was the same across participants, the influence of these factors could be assessed, as well as individual responses to alcohol. Other factors of interest were personality and expectancy measures.
By demonstrating the repeatability of the individual's response to the PR schedule and its sensitivity to various determinants (such as recent drinking history), this paradigm can be qualified to evaluate the efficacy of medications on motivation for alcohol use disorder, as well as the role of genetics in alcohol use disorder. This laboratory approach would improve the understanding of both genetic and environmental determinants of alcohol self-administration behavior and motivation to consume alcohol.
This protocol follows the guidelines of the National Institutes of Health's human research ethics committee.
1. Initial nursing measures and set-up
2. Set up IV pump
3. Set up the laptop (Figure 1)
NOTE: The sections below are performed using the software and the accessories associated with the CAIS system.
4. Progressive Ratio (PR) self-administration session (Figure 2)
5. End of session
6. Drink button troubleshooting
Volunteers were pre-screened via telephone interview and brought in for an initial screening visit. A physical examination and medical history, blood tests for liver function and routine blood chemistry, and a urine screen for illegal drugs were conducted. Recent drinking history was assessed using the 90-day Timeline Followback (TLFB)31 and Alcohol Use Disorder Identification Test (AUDIT)32.
Participants were excluded if they have any clinically significant medical problems, use of prescription or over-the-counter (OTC) medication known to interact with alcohol in the past 2-4 weeks, lifetime or current diagnosis of substance or alcohol dependence; currently seeking treatment for alcohol use disorders; the presence of withdrawal symptoms that are clinically significant (a score >8 on the Clinical Institute Withdrawal Assessment (CIWA))33, or pregnancy in women. Other IV alcohol administration studies have included participants with a lifetime diagnosis of alcohol dependence, as well as current if the participant is non-treatment seeking.
To better understand the role of alcohol expectancies on motivation for alcohol rewards, the Alcohol Effects Questionnaire (AEFQ)34 was administered. Additionally, subjective response measures were collected at baseline and serially during the study session to examine the urge for alcohol using the CAIS Experience Questionnaire (CEQ), Alcohol Urge Questionnaire (AUQ)35 and the effects of alcohol using the Drug Effects Questionnaire (DEQ)36. Measures of progressive ratio work include the total number of button presses across all rewards, the total number of false button presses (an incomplete attempt to press the button/or pressing faster than the maximal rate), total reward time (the amount of time spent pressing the button for alcohol), average rate of button pressing, and false button press fraction. Other measures included: peak BrAC, average BrAC, total rewards earned, and total ethanol consumed. These measures do not include the priming portion of the session.
Data were analyzed using General Linear Model Univariate to compare IV-ASA measures for males and females (Table 1) and Low Responders and High Responders (Table 2). Pearson's r correlational analyses were conducted to compare session 1 and session 2 IV-ASA measures (Figure 3) and IV-ASA measures with recent drinking history measures (Figure 4). Finally, General Linear Model Univariate analyses were conducted to compare Low and High Responders on measures of alcohol expectancies (Figure 5) and subjective response measures during the priming phase (Figure 6) and for peak subjective response scores (Figure 7).
One hundred and fifteen healthy, non-alcohol-dependent participants were recruited for this study. Sixteen participants were excluded due to availability issues, eight due to system crashes during 2nd infusion visit, six due to medical reasons (i.e., low blood pressure, fainting, etc.), and one from not meeting inclusion criteria (i.e., alcohol dependence diagnosis). Therefore, a total of 84 participants were used in the final analysis. The sample was 54.8% male (n = 46) and 67.9% identified as White/Caucasian (n = 57). Table 3 summarizes the demographics of the analytical sample.
Effects of sex differences were assessed on both drinking history measures as well as the session outcomes (Table 1). Females and males were not significantly different on recent drinking history measures as reported by the AUDIT and TLFB 90 Days. As for session measures, the only statistically significant sex difference was the total amount of EtOH consumed. This significant difference was expected given that males have larger total body water volumes of alcohol distribution than females, and these pharmacokinetic differences are adjusted for by the program. Sex was a covariant in all further analyses.
A subset of participants (N = 11) completed two identical sessions. Pearson's r correlation coefficients were calculated comparing session 1 and session 2 self-administration variables of peak BrAC, total rewards earned, the total number of button presses, and the average rate of button pressing. Pearson's r ranged from 0.81 to 0.96 (P ≤ 0.002). There was a high test-retest reliability for the progressive ratio method for all self-administration measures (Figure 3). Correlation coefficients were also used to examine internal consistency among self-administration measures. Pearson's r ranged from 0.71 to 0.96 (p < 0.01). As expected, the total number of rewards was strongly correlated with peak BrAC, average BrAC, and total EtOH infused (data not shown).
As expected, there was substantial variability in self-administration behavior (Figure 8). By comparing session data with recent drinking history, we found that the number of drinking days during the past 90 days was closely associated with drinking behaviors in the lab (Figure 4). These associations include regular measures such as peak BrAC, average BrAC (not shown in the figure), and total EtOH. The system-specific measures such as average rate and false button presses fraction were also associated with recent drinking history measures. Pearson's r ranged from 0.257 to 0.314 (p ≤ 0.025).
To evaluate the relationship between alcohol-seeking behavior and subjective responses throughout the session, a median split (median = 5) was conducted on total rewards earned, yielding 2 groups labeled low responders and high responders. High responders had significantly higher drinking history measures of Total Drinks over the past 90 days and Number of Heavy Drinking Days over the past 90 days (Table 2). As expected, higher responders pressed a significantly greater number of times for infusions during the session than low responders and spent more time working for those rewards (all p's < 0.001). Subjective responses were analyzed by comparing group means at baseline during the PR priming phase as during the PR self-administration phase. Low responders reported more overall negative expectancies of alcohol (p = 0.023) at baseline, including expectations of cognitive and physical impairment (p = 0.022) (Figure 5).
During the priming phase, low and high responders were significantly different on both CEQ and DEQ measures (Figure 6). High responders would have been willing to pay more money for their next drink (p = 0.038). Low responders felt the alcohol more after priming (p = 0.001) and felt more intoxicated following priming (p < 0.001).
During the open bar PR phase, high and low responders were significantly different on DEQ measures of "liking" (p = 0.014) and "wanting" (p = 0.001) alcohol (Figure 7). High responders had a higher craving for alcohol, as seen in the AUQ total score (p = 0.003). They were also still willing to pay more for their next drink at the end of the open bar PR phase (p < 0.001).
Figure 1: Test session set-up of materials. Schematic of the set-up of IV pump, work button, laptop, and data entry screen from the software. Please click here to view a larger version of this figure.
Figure 2: Timeline of events. Timeline of the priming session, ad-lib session, and measures collected. Please click here to view a larger version of this figure.
Figure 3: Test-retest reliability in n = 11 subjects undertaking 2 identical sessions. Session 1 is on the x-axis, and session 2 is on the y-axis. There were statistically significant correlations between session 1 and session 2 drinking measures for: peak BrAC, total rewards earned, the total number of button presses, and average rate of button pressing. Please click here to view a larger version of this figure.
Figure 4: Recent drinking history and session measures. Graphical representation of the statistically significant relationship between past drinking history using the 90-day Timeline Followback (TLFB) and drinking measures during the self-administration session. Please click here to view a larger version of this figure.
Figure 5: Alcohol expectancies. Alcohol expectancies at baseline were significantly different between low versus high responders. Low responders expected more overall negative effects from alcohol at baseline and, specifically, greater cognitive and physical impairment as a result of alcohol. *p < 0.05 Please click here to view a larger version of this figure.
Figure 6: Subjective response following priming phase. Subjective response at the 20 min mark was significantly different between low versus high responders. High responders were willing to pay more for their next drink after priming, as indicated by the CEQ. Low responders felt the alcohol more directly after priming and felt more intoxicated, as indicated by the DEQ. *p < 0.05; **p < 0.01; ***p < 0.001 Please click here to view a larger version of this figure.
Figure 7: Subjective response during progressive-ratio open bar phase. Subjective response during the open bar phase was significantly different between low versus high responders. High responders reported higher peak scores for liking alcohol and wanting alcohol on the DEQ. They also reported higher peak craving or urge for alcohol on the AUQ. High responders were willing to pay more for their next drink at the end of the open-bar phase, as indicated by the CEQ. *p < 0.05; **p < 0.01; ***p < 0.001 Please click here to view a larger version of this figure.
Figure 8: BrAC trajectories. The graphs document the predicted BrAC trajectories during the entire session (including the priming phase). At the 10 min mark, most participants achieved a 30 mg/dL BrAC, which was the desired BrAC for the priming phase. The variability in the self-administration phase reflects the sensitivity of the paradigm to differences across participants. Please click here to view a larger version of this figure.
Females (N = 38) | Males (N = 46) | |
Drinking History: | ||
Total Drinks | 92.8 ± 120.7 | 93.9 ± 72.9 |
Drinking Days | 25.1 ± 12.9 | 27.7 ± 14.3 |
Drinks per Day | 3.3 ± 2.3 | 3.4 ± 1.6 |
Heavy Drinking Days | 8.9 ± 11.5 | 6.4 ± 9.1 |
Session Measures: | ||
Peak BrAC | 34.6 ± 17.7 | 37.9 ± 21.0 |
Average BrAC | 21.4 ± 15.6 | 23.3 ± 18.7 |
Total Rewards Earned | 5.4 ± 3.3 | 5.5 ± 3.8 |
Total EtOH consumed (grams) ** | 16.8 ± 7.6 | 25.6 ± 15.0 |
Number of Button Presses | 2035.2 ± 2657.1 | 2940.7 ± 5179.5 |
Number of False Button Presses | 445.7 ± 828.2 | 585.0 ± 1112.4 |
Total Reward Time | 1146.9 ± 1277.3 | 1460.0 ± 1643.3 |
Average Rate of Button Pressing | 1.9 ± 1.1 | 2.3 ± 1.6 |
False Button Presses Fraction | 0.12 ± 0.12 | 0.16 ± 0.14 |
False Button Presses Fraction | 0.12 ± 0.12 | 0.16 ± 0.14 |
Table 1: Sex differences in drinking measures. The first panel reports 90 Day Timeline Followback (TLFB) measures. Males and females were not significantly different (p > 0.05) on any drinking history measures, indicating that they drank similarly outside the lab. The second panel shows session consumption measures. Males and females were significantly different only on the total amount of ethanol consumed (**p = 0.005). This difference is commensurate with sex differences in total body water and likely reflects the difference in consumption needed to achieve comparable peak BrACs.
Low Responders (N = 45) | High Responders (N = 39) | |
Drinking History: | ||
Total Drinks* | 73.5 ± 48.4 | 116.4 ± 129.4 |
Drinking Days | 24.8 ± 13.6 | 28.7 ± 13.7 |
Drinks per Day | 3.2 ± 1.6 | 3.7 ± 2.3 |
Heavy Drinking Days* | 5.7 ± 7.4 | 9.6 ± 12.6 |
Session Measures: | ||
Peak BrAC** | 26.4 ± 12.4 | 47.9 ± 20.0 |
Average BrAC** | 12.6 ± 9.5 | 33.8 ± 17.4 |
Total Rewards Earned** | 2.5 ± 1.6 | 8.7 ± 1.9 |
Total EtOH consumed (g) ** | 15.2 ± 6.6 | 29.1 ± 14.4 |
Number of Button Presses** | 225.1 ± 242.1 | 5191.8 ± 5046.0 |
Number of False Button Presses** | 37.9 ± 75.3 | 1080.5 ± 1240.9 |
Total Reward Time (s)** | 386.4 ± 961.3 | 2393.7 ± 1246.9 |
Average Rate of Button Pressing** | 1.7 ± 1.4 | 2.6 ± 1.4 |
False Button Presses Fraction** | 0.09 ± 0.11 | 0.20 ± 0.13 |
Table 2: Low and high responder differences in drinking history measures. The table reports 90 Day Timeline Followback (TLFB) measures and intravenous self-administration measures (IV-ASA). Low Responders and High Responders were significantly different on Total Drinks and Number of Heavy Drinking Days (all p's < 0.05). These differences indicate that these participants have different drinking histories that were also reflected in their PR behavior in the laboratory. Low Responders had significantly lower IV-ASA measures than High Responders (all p's < 0.001).
Construct | Mean ± S.D. (Percentage) | |
Sex | Female | 38 (45.2%) |
Male | 46 (54.8%) | |
Race | White | 57 (67.9%) |
African American/Black | 12 (14.3%) | |
Asian | 9 (10.7%) | |
Mixed Race | 5 (6.0%) | |
Unknown | 1 (1.2%) | |
Age | 24.8 ± 3.0 | |
Years of Education | 15.9 ± 3.0 | |
Household Income | Median | $30,000–$39,999 |
Table 3: Demographics of the analytical sample. This table gives a breakdown of the characteristics of our sample.
This protocol provides evidence that a progressive-ratio intravenous alcohol self-administration procedure successfully measures motivation for alcohol consumption in humans. The methodology extends the original pre-clinical progressive-ratio model into humans37. Test-retest results indicate that this paradigm provides a reliable protocol to test motivation for seeking alcohol across repeated visits. This protocol is also sensitive to variability in alcohol consumption behavior during a session, measures that may have the potential to influence motivation for alcohol, such as alcohol expectancies, and to associate differences in recent drinking history and may reflect the within-session subjective responses to alcohol. Support for the effectiveness of this procedure has also been published elsewhere, showing greater subjective response in terms of desire for more alcohol27,28,29,38 and greater consumption of alcohol39.
Because intravenous administration of alcohol is coupled with individualized PBPK-based computations of the infusion rate, a significant improvement upon oral alcohol methods (which can have a 3-4-fold difference) is achieved19. CAIS significantly reduces these interindividual differences in the distribution and elimination of alcohol by bypassing gastrointestinal absorption. Using the afore-mentioned PBPK model-based algorithm20, the system then prescribes the incremental trajectory of BrAC, which can then be adjusted by the investigator for their specific protocol22,23,27.
This protocol provides a platform for alcohol consumption that is simple to modify to match the characteristics being studied in the participant group and can be adjusted to reflect the question of interest. For example, the inclusion of a priming phase was specific to this study; other options are to remove the priming phase or to provide a specific target level or exposure. Such modifications include adjustments to the reward properties, the work required to achieve a reward, the timing of alcohol delivery, the length of the study, safety cut-off, and the ability to include an alternative reward, commonly placebo (e.g., saline).
In experiments using ingestion of alcohol, attention to safety concerns limits the amount of alcohol available to the participant for delivery over the course of a study; the resulting peak BrAC is typically much lower than a participant would consume outside of the laboratory. Using intravenous infusion combined with individualized, real-time PBPK modeling of the future trajectory of BrAC, the system controls the exposure. A safety limit can be prescribed, and all participants have access to peak BrACs typical of binge drinking if they choose. Currently recommended safety limits are 120 mg/dL in moderate drinkers, 150 mg/dL in heavy drinkers, and 180 mg/dL in dependent drinkers. In the free access paradigm, some drinkers will still reach and maintain these limits. In the PR paradigm, the peak BrAC exposure can be limited by specifying the sequence of work set requirements, given the incremental reward exposure chosen. By using a progressive-ratio method, the outcome used to measure the desire for alcohol is the amount of work produced to receive an exposure to alcohol satisfying that desire. Additionally, the measure of false button presses may be a limitation. Other factors can influence the number of false button presses, such as fatigue, the type of button used (our button versus a click on a mouse), or alcohol intoxication. Variations of this approach as applied by Plawecki et al. have been used to overcome this limitation using a modified PR task called the Constant Attention Task (CAT)25,26.
The most important limitation is the lack of a naturalistic setting as this procedure is typically done in a hospital or laboratory setting and uses a method of alcohol administration outside of the participant's experience. More beneficially, by eliminating environmental cues for alcohol consumption, these constraints allow the experimenters the flexibility of introducing those elements back into the experiment. For example, the computer screen can be formatted to include a bar setting, the room where the experiment is conducted could be changed to appear more like a bar, olfactory cues of alcohol or visual cues of alcohol can be introduced as well.
The significance of this method is that it provides direct control of incremental BrAC exposure, yielding range and flexibility in terms of alcohol delivery that oral alcohol methods cannot provide. Importantly, this progressive-ratio intravenous alcohol self-administration paradigm translates work effort into exposures that are consistent within and across participants and produce easily measurable outcomes. The set-up file defining work sequences and incremental reward exposures is simple to modify and tailor for experiments. An alternative method for prescribing work that uses IV alcohol and progressive ratio includes an attention component25,26. This method requires the participant to work for the alcohol-based on performing a task that requires constant attention to perform successfully. This method adapts to compensate for both the effects of alcohol as well as fatigue.
One of the most important applications for this method is medications development in the laboratory setting. The application of this system to relevant clinical populations is a highly promising and important direction to determine the effectiveness of medications on motivation for alcohol rewards. Test-retest of this protocol supports the reliability of the measures, while progressive ratio eases the concern of heavier drinkers reaching the BrAC ceiling while maintaining a measure directly addressing motivation for seeking alcohol. Furthermore, the use of this protocol may provide a better opportunity to examine genetic and environmental determinants of alcohol seeking.
The authors have nothing to disclose.
This work was supported by the National Institute on Alcohol Abuse and Alcoholism Division of Clinical and Biological Research (Z1A AA 000466). The CAIS software was developed with support from Sean O'Connor, Martin Plawecki, James Hays, and Victor Vitvitskiy from the Indiana Alcohol Research Center (P60 AA 07611). Martin Plawecki is also supported by NIAAA R01 AA027236. CAIS-PR paradigms were developed with further support from Ulrich Zimmermann and Vijay Ramchandani. The authors thank Dr. Mary Lee, Dr. Nancy Diazgranados, Dr. David T. George, and Nurse Practitioner LaToya Sewell for medical support and the monitoring safety of the participants, as well as Dr. Reza Momenan for operational support. The authors also would like to thank the staff of the 5-SW day hospital and 1-HALC alcohol clinic at the NIH Clinical Center. The authors thank the research assistants for their operational support of the study, including Molly Zametkin, Jonathan Westman, Kristin Corey, Lauren Blau, and Courtney Vaughan. Finally, the authors are grateful and appreciative for the clinical oversight and guidance from the late Dr. Daniel Hommer.
Alcohol Infusate | AKORN Pharmaceuticals | https://www.akorn.com/ | 95% ethanol solution can be purchased and diluted to 6% V/V ethanol solution. Must contact company for a quote |
Breath Alcohol Meter Draeger models 6820 or 5820 | Draeger Safety Diagnostics | https://www.draeger.com/en-us_us/Applications/Products/Breath-Alcohol-and-Drug-Testing/Alcohol-Screening-Devices/Alcotest-6820; https://www.draeger.com/en-us_us/Applications/Products/Breath-Alcohol-and-Drug-Testing/Alcohol-Screening-Devices/Draeger-Alcotest-5820 | To collect breathalyzer readings |
Computer-assisted Alcohol Infusion System (CAIS) | Indiana University | To adapt CAIS for one's own research aims, contact the corresponding author Dr. Bethany Stangl and Dr. Martin Plawecki | |
Digital Refractometer | Atago | PR-32α (atago-usa.com) | To test the alcohol concentration of the infusate |
Griffin Powermate buttons | CDW Government Inc. | Item was discontinued 2018; currently working on a replacement | |
iMed Gemini PC-2TX Infusion Pump | Soma Technology, Inc. or DiaMedical USA | http://www.somatechnology.com/ OR https://diamedicalusa.com/medical-equipment/on-site-repairs-preventive-maintenance/infusion-pump-repair-service/alaris-infusion-pumps/alaris-imed-gemini-pc-2tx-infusion-pump-2/ | Infusion pump. Must contact company for a quote as product is not shown on the website. |
Laptop/Computer | CDW Government Inc. | https://www.cdwg.com/search/computers/laptops-2-in-1s/laptops/?w=CB2&filter=af_system_notebook _type_cb2_ss%3a(%22Notebook%22) |
OS, Windows 7 or newer (with updates installed); Administrative privileges; MS Office (including Excel); At least 3 usb ports on PC, and a port multiplier depending on actual experiment. |
Secure Dongle | SecuTech | https://esecutech.com/store/unikey/unikey-drive/unikey-drive-2gb | For CAIS software and data storage |
StarTech.com 1 Port USB to RS232 DB9 Serial Adapter Cable – M/M | CDW Government Inc. | StarTech.com 1 Port USB to RS232 DB9 Serial Adapter Cable – M/M – ICUSB232V2 – – (cdwg.com) | To connect laptop to IV pump |
StarTech.com 2 Port USB to RS-232 Serial DB9 Adapter Cable – Serial Adapter | CDW Government Inc. | StarTech.com 2 Port USB to RS-232 Serial DB9 Adapter Cable – Serial Adapter – ICUSB232C2 – – (cdwg.com) | To connect laptop to IV pump |
StarTech.com DB9 to RJ45 Modular Adapter F F serial adaptor | CDW Government Inc. | https://www.cdwg.com/shop/products/StarTech.com-DB9-to-RJ45-Modular-Serial-Adapter-Black/386543.aspx?pfm=srh | To connect laptop to IV pump |
StarTech.com DB9 to RJ45 Modular Adapter M F serial adaptor | CDW Government Inc. | https://www.cdwg.com/shop/products/StarTech.com-DB9-to-RJ45-Modular-Serial-Adapter-Black/386544.aspx?enkwrd=StarTech%20com%20DB9%20to%20RJ45%20Modular%20Adapter%20M%20F%20serial%20adapter&pfm=srh | To connect laptop to IV pump |
USB extension cable 12' | CDW Government Inc. | https://www.cdwg.com/shop/products/StarTech.com-10ft-USB-2.0-Extension-Cable-A-to-A-Cable-Black/2274398.aspx?pfm=srh | To connect and extend the button in reach of the participant |
VGA Cable 12' | BestBuy | https://www.bestbuy.com/site/insignia-12-vga-cable-black/5884115.p?skuId=5884115 | To connect monitor to laptop |