Your search keyword '"Conlisk D"' showing total 7 results

1. Facilitating the merge of operant behaviour and fiber photometry- focus on intravenous self-administration

Author

Conlisk, D., Ceau, M., Fiancette, J.F., Winke, N., Darmagnac, E., Herry, C., and Deroche-Gamonet, V.

Published

2022

2. Large-scale characterization of cocaine addiction-like behaviors reveals that escalation of intake, aversion-resistant responding, and breaking-points are highly correlated measures of the same construct.

Author

de Guglielmo G, Carrette L, Kallupi M, Brennan M, Boomhower B, Maturin L, Conlisk D, Sedighim S, Tieu L, Fannon MJ, Martinez AR, Velarde N, Othman D, Sichel B, Ramborger J, Lau J, Kononoff J, Kimbrough A, Simpson S, Smith LC, Shankar K, Bonnet-Zahedi S, Sneddon EA, Avelar A, Plasil SL, Mosquera J, Crook C, Chun L, Vang A, Milan KK, Schweitzer P, Lin B, Peng B, Chitre AS, Polesskaya O, Solberg Woods LC, Palmer AA, and George O

Subjects

Animals, Rats, Male, Female, Behavior, Animal drug effects, Disease Models, Animal, Behavior, Addictive, Drug-Seeking Behavior, Cocaine-Related Disorders, Self Administration, Cocaine administration & dosage

Abstract

Addiction is commonly characterized by escalation of drug intake, compulsive drug seeking, and continued use despite harmful consequences. However, the factors contributing to the transition from moderate drug use to these problematic patterns remain unclear, particularly regarding the role of sex. Many preclinical studies have been limited by small sample sizes, low genetic diversity, and restricted drug access, making it challenging to model significant levels of intoxication or dependence and translate findings to humans. To address these limitations, we characterized addiction-like behaviors in a large sample of >500 outbred heterogeneous stock (HS) rats using an extended cocaine self-administration paradigm (6 hr/daily). We analyzed individual differences in escalation of intake, progressive ratio (PR) responding, continued use despite adverse consequences (contingent foot shocks), and irritability-like behavior during withdrawal. Principal component analysis showed that escalation of intake, progressive ratio responding, and continued use despite adverse consequences loaded onto a single factor that was distinct from irritability-like behaviors. Categorizing rats into resilient, mild, moderate, and severe addiction-like phenotypes showed that females exhibited higher addiction-like behaviors, with a lower proportion of resilient individuals compared to males. These findings suggest that, in genetically diverse rats with extended drug access, escalation of intake, continued use despite adverse consequences, and PR responding are highly correlated measures of a shared underlying construct. Furthermore, our results highlight sex differences in resilience to addiction-like behaviors., Competing Interests: Gd, LC, MK, MB, BB, LM, DC, SS, LT, MF, AM, NV, DO, BS, JR, JL, JK, AK, SS, LS, KS, SB, ES, AA, SP, JM, CC, LC, AV, KM, PS, BL, BP, AC, OP, LS, AP, OG No competing interests declared, (© 2023, de Guglielmo, Carrette et al.)

Published

2024

3. Integrating operant behavior and fiber photometry with the open-source python library Pyfiber.

Author

Conlisk D, Ceau M, Fiancette JF, Winke N, Darmagnac E, Herry C, and Deroche-Gamonet V

Subjects

Humans, Neurons physiology, Conditioning, Operant physiology, Brain, Photometry methods

Abstract

Despite the popularity of fiber photometry (FP), its integration with operant behavior paradigms is progressing slowly. This can be attributed to the complex protocols in operant behavior - resulting in a combination of diverse non-predictable behavioral responses and scheduled events, thereby complicating data analysis. To overcome this, we developed Pyfiber, an open-source python library which facilitates the merge of FP with operant behavior by relating changes in fluorescent signals within a neuronal population to behavioral responses and events. Pyfiber helps to 1. Extract events and responses that occur in operant behavior, 2. Extract and process the FP signals, 3. Select events of interest and align them to the corresponding FP signals, 4. Apply appropriate signal normalization and analysis according to the type of events, 5. Run analysis on multiple individuals and sessions, 6. Collect results in an easily readable format. Pyfiber is suitable for use with many different fluorescent sensors and operant behavior protocols. It was developed using Doric lenses FP systems and Imetronic behavioral systems, but it possesses the capability to process data from alternative systems. This work sets a solid foundation for analyzing the relationship between different dimensions of complex behavioral paradigms with fluorescent signals from brain regions of interest., (© 2023. Springer Nature Limited.)

Published

2023

4. Voluntary and forced exposure to ethanol vapor produces similar escalation of alcohol drinking but differential recruitment of brain regions related to stress, habit, and reward in male rats.

Author

de Guglielmo G, Simpson S, Kimbrough A, Conlisk D, Baker R, Cantor M, Kallupi M, and George O

Subjects

Male, Animals, Rats, Ethanol, Reward, Alcohol Drinking, Habits, Blood Alcohol Content, Disease Models, Animal, Alcoholism, Central Amygdaloid Nucleus

Abstract

A major limitation of the most widely used current animal models of alcohol dependence is that they use forced exposure to ethanol including ethanol-containing liquid diet and chronic intermittent ethanol (CIE) vapor to produce clinically relevant blood alcohol levels (BAL) and addiction-like behaviors. We recently developed a novel animal model of voluntary induction of alcohol dependence using ethanol vapor self-administration (EVSA). However, it is unknown whether EVSA leads to an escalation of alcohol drinking per se, and whether such escalation is associated with neuroadaptations in brain regions related to stress, reward, and habit. To address these issues, we compared the levels of alcohol drinking during withdrawal between rats passively exposed to alcohol (CIE) or voluntarily exposed to EVSA and measured the number of Fos+ neurons during acute withdrawal (16 h) in key brain regions important for stress, reward, and habit-related processes. CIE and EVSA rats exhibited similar BAL and similar escalation of alcohol drinking and motivation for alcohol during withdrawal. Acute withdrawal from EVSA and CIE recruited a similar number of Fos+ neurons in the Central Amygdala (CeA), however, acute withdrawal from EVSA recruited a higher number of Fos+ neurons in every other brain region analyzed compared to acute withdrawal from CIE. In summary, while the behavioral measures of alcohol dependence between the voluntary (EVSA) and passive (CIE) model were similar, the recruitment of neuronal ensembles during acute withdrawal was very different. The EVSA model may be particularly useful to unveil the neuronal networks and pharmacology responsible for the voluntary induction and maintenance of alcohol dependence and may improve translational studies by providing preclinical researchers with an animal model that highlights the volitional aspects of alcohol use disorder., (Copyright © 2022 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

5. The Cocaine and Oxycodone Biobanks, Two Repositories from Genetically Diverse and Behaviorally Characterized Rats for the Study of Addiction.

Author

Carrette LLG, de Guglielmo G, Kallupi M, Maturin L, Brennan M, Boomhower B, Conlisk D, Sedighim S, Tieu L, Fannon MJ, Velarde N, Martinez AR, Kononoff J, Kimbrough A, Simpson S, Smith LC, Shankar K, Ramirez FJ, Chitre AS, Lin B, Polesskaya O, Solberg Woods LC, Palmer AA, and George O

Subjects

Animals, Biological Specimen Banks, Oxycodone therapeutic use, Rats, Rats, Sprague-Dawley, Self Administration, Behavior, Addictive, Cocaine, Cocaine-Related Disorders

Abstract

The rat oxycodone and cocaine biobanks contain samples that vary by genotypes (by using genetically diverse genotyped HS rats), phenotypes (by measuring addiction-like behaviors in an advanced SA model), timepoints (samples are collected longitudinally before, during, and after SA, and terminally at three different timepoints in the addiction cycle: intoxication, withdrawal, and abstinence or without exposure to drugs through age-matched naive rats), samples collected (organs, cells, biofluids, feces), preservation (paraformaldehyde-fixed, snap-frozen, or cryopreserved) and application (proteomics, transcriptomics, microbiomics, metabolomics, epigenetics, anatomy, circuitry analysis, biomarker discovery, etc.Substance use disorders (SUDs) are pervasive in our society and have substantial personal and socioeconomical costs. A critical hurdle in identifying biomarkers and novel targets for medication development is the lack of resources for obtaining biological samples with a detailed behavioral characterization of SUD. Moreover, it is nearly impossible to find longitudinal samples. As part of two ongoing large-scale behavioral genetic studies in heterogeneous stock (HS) rats, we have created two preclinical biobanks using well-validated long access (LgA) models of intravenous cocaine and oxycodone self-administration (SA) and comprehensive characterization of addiction-related behaviors. The genetic diversity in HS rats mimics diversity in the human population and includes individuals that are vulnerable or resilient to compulsive-like responding for cocaine or oxycodone. Longitudinal samples are collected throughout the experiment, before exposure to the drug, during intoxication, acute withdrawal, and protracted abstinence, and include naive, age-matched controls. Samples include, but are not limited to, blood plasma, feces and urine, whole brains, brain slices and punches, kidney, liver, spleen, ovary, testis, and adrenal glands. Three preservation methods (fixed in formaldehyde, snap-frozen, or cryopreserved) are used to facilitate diverse downstream applications such as proteomics, metabolomics, transcriptomics, epigenomics, microbiomics, neuroanatomy, biomarker discovery, and other cellular and molecular approaches. To date, >20,000 samples have been collected from over 1000 unique animals and made available free of charge to non-profit institutions through https://www.cocainebiobank.org/ and https://www.oxycodonebiobank.org/., (Copyright © 2021 Carrette et al.)

Published

2021

6. Oxycodone self-administration and withdrawal behaviors in male and female Wistar rats.

Author

Kimbrough A, Kononoff J, Simpson S, Kallupi M, Sedighim S, Palomino K, Conlisk D, Momper JD, de Guglielmo G, and George O

Subjects

Analgesics, Opioid adverse effects, Animals, Brain drug effects, Brain metabolism, Emotions drug effects, Emotions physiology, Female, Male, Oxycodone adverse effects, Pain Threshold physiology, Rats, Rats, Wistar, Self Administration, Substance Withdrawal Syndrome metabolism, Analgesics, Opioid administration & dosage, Oxycodone administration & dosage, Pain Threshold drug effects, Pain Threshold psychology, Sex Characteristics, Substance Withdrawal Syndrome psychology

Abstract

Rationale: Over the last decade, oxycodone has become one of the most widely abused drugs in the USA. Oxycodone use disorder (OUD) is a serious health problem that has prompted a need to develop animal models of OUD that have both face and predictive validity. Oxycodone use in humans is more prevalent in women and leads to pronounced hyperalgesia and irritability during withdrawal. However, unclear is whether current animal models of oxycodone self-administration recapitulate these characteristics in humans., Objectives: We assessed the face validity of a model of extended-access oxycodone self-administration in rats by examining the escalation of oxycodone intake and behavioral symptoms of withdrawal, including irritability-like behavior and mechanical nociception, in male and female Wistar rats., Results: Both male and female rats escalated their oxycodone intake over fourteen 12-h self-administration sessions. After escalation, female rats administered more drug than male rats. No differences in plasma oxycodone levels were identified, but males had a significantly higher level of oxycodone in the brain at 30 min. Extended access to oxycodone significantly decreased aggressive-like behavior and increased defensive-like behaviors when tested immediately after a 12-h self-administration session, followed by a rebound increase in aggressive-like behavior 12 h into withdrawal. Tests of mechanical nociception thresholds during withdrawal indicated pronounced hyperalgesia. No sex differences in irritability-like behavior or pain sensitivity were observed., Conclusions: The present study demonstrated the face validity of the extended access model of oxycodone self-administration by identifying sex differences in the escalation of oxycodone intake and pronounced changes in pain and affective states.

Published

2020

7. Systemic and Intra-Habenular Activation of the Orphan G Protein-Coupled Receptor GPR139 Decreases Compulsive-Like Alcohol Drinking and Hyperalgesia in Alcohol-Dependent Rats.

Author

Kononoff J, Kallupi M, Kimbrough A, Conlisk D, de Guglielmo G, and George O

Subjects

Animals, Habenula drug effects, Male, Nerve Tissue Proteins agonists, Pain Threshold, Rats, Wistar, Receptors, G-Protein-Coupled agonists, Substance Withdrawal Syndrome, Alcohol Drinking, Alcoholism physiopathology, Compulsive Behavior, Habenula physiology, Hyperalgesia physiopathology, Nerve Tissue Proteins physiology, Receptors, G-Protein-Coupled physiology

Abstract

GPR139 is an orphan G protein-coupled receptor (GPCR) that is expressed mainly in the brain, with the highest expression in the medial habenula. The modulation of GPR139 receptor function has been hypothesized to be beneficial in the treatment of some mental disorders, but behavioral studies have not yet provided causal evidence of the role of GPR139 in brain dysfunction. Because of the high expression of GPR139 in the habenula, a critical brain region in addiction, we hypothesized that GPR139 may play role in alcohol dependence. Thus, we tested the effect of GPR139 receptor activation using the selective, brain-penetrant receptor agonist JNJ-63533054 on addiction-like behaviors in alcohol-dependent male rats. Systemic administration of JNJ-63533054 (30 mg/kg but not 10 mg/kg, p.o.) reversed the escalation of alcohol self-administration in alcohol-dependent rats, without affecting water or saccharin intake in dependent rats or alcohol intake in nondependent rats. Moreover, systemic JNJ-63533054 administration decreased withdrawal-induced hyperalgesia, without affecting somatic signs of alcohol withdrawal. Further analysis demonstrated that JNJ-63533054 was effective only in a subgroup of dependent rats that exhibited compulsive-like alcohol drinking. Finally, site-specific microinjection of JNJ-63533054 in the habenula but not interpeduncular nucleus (IPN) reduced both alcohol self-administration and withdrawal-induced hyperalgesia in dependent rats. These results provide robust preclinical evidence that GPR139 receptor activation reverses key addiction-like behaviors in dependent animals, suggest that GPR139 may be a novel target for the treatment of alcohol use disorder, and demonstrate that GPR139 is functionally relevant in regulating mammalian behavior.

Published

2018