Optimizing drug combinations against multiple myeloma using a quadratic phenotypic optimization platform (QPOP)

Rashid, Masturah Bte Mohd Abdul; Toh, Tan Boon; Hooi, Lissa; Silva, Aleidy; Zhang, Yanzhou; Tan, Pei Fang; Teh, Ai Ling; Karnani, Neerja; Jha, Sudhakar; Ho, Chih‐Ming; Chng, Wee Joo; Ho, Dean; Chow, Edward Kai‐Hua

doi:10.1126/scitranslmed.aan0941

Cited by 89 publications

(80 citation statements)

References 61 publications

(76 reference statements)

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“…Adenosine A 2A and glutamate mGlu 5 cascades use overlapping molecules, including mitogenactivated protein kinase and cAMP response element binding protein . It will be important to understand which pathways are beneficial to drug response and may allow advancements in drug cocktail design that show promise in other fields like cancer drug development (Rashid et al, 2018). Pharmacokinetic and pharmacodynamic analyses of this triple drug cocktail are also imperative.…”

Section: Discussionmentioning

confidence: 99%

Targeting Dopamine D₂, Adenosine A_2A, and Glutamate mGlu₅ Receptors to Reduce Repetitive Behaviors in Deer Mice

Lewis

Primiani

Muehlmann

2019

J Pharmacol Exp Ther

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Repetitive behaviors are seemingly purposeless patterns of behavior that vary little in form and are characteristic of many neurodevelopmental, psychiatric, and neurologic disorders. Our work has identified an association between hypofunctioning of the indirect basal ganglia pathway and the expression of repetitive behavior in the deer mouse model. In this study, we targeted indirect pathway cells of the striatum with single drugs and drug combinations that bind to dopamine D 2 , adenosine A 2A , and glutamate mGlu 5 receptors. These receptors function both individually and as receptor heteromers. We found that only the triple drug cocktail (L-741,6261CGS216801CDPPB) that was designed to increase striatal indirect basal ganglia pathway cell function reduced repetitive behavior in adult male deer mice. No single drug or double drug combinations were effective at selectively reducing repetitive behavior. We found this triple drug cocktail reduced repetitive behavior in both short-acting and long-acting formulations and was effective throughout 7 days of daily administration. Conversely, another triple drug cocktail (quinpirole1SCH582611MTEP) that was designed to further reduce striatal indirect basal ganglia pathway cell function caused a significant increase in repetitive behavior. Significant and behaviorally selective effects on repetitive behavior were only achieved with the triple drug cocktails that included doses of L-741,626 and quinpirole that have off-target effects (e.g., dopamine D 3 receptors). These data further a role for decreased indirect basal ganglia pathway activation in repetitive behavior and suggest that targeting these receptors and/or heteromeric complexes on the indirect pathway neurons of the striatum may offer pharmacotherapeutic benefit for individuals with repetitive behavior disorders.

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Section: Discussionmentioning

confidence: 99%

Targeting Dopamine D₂, Adenosine A_2A, and Glutamate mGlu₅ Receptors to Reduce Repetitive Behaviors in Deer Mice

Lewis

Primiani

Muehlmann

2019

J Pharmacol Exp Ther

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“…Importantly, the platforms that have served as foundations for the development of Project IDentif.AI have shown prior clinical successes in indications ranging from oncology to infectious diseases. Specifically, positive treatment outcomes were observed in direct ex vivo to clinical validation studies for hematologic cancer (Quadratic Phenotypic Optimization Platform [QPOP]), and the key role of dynamic clinical dosing on efficacy was further validated on an advanced solid cancer patient (CURATE.AI) . In the area of infectious diseases, low‐dose treatment for human immunodeficiency virus (HIV) was shown to mediate undetectable viral loads while opening the doors to possible downstream reductions in treatment complications arising from side effects of high‐dose therapy (CURATE.AI) …”

Section: Accelerating Combination Therapy Development and Optimizatiomentioning

confidence: 99%

Addressing COVID‐19 Drug Development with Artificial Intelligence

2020

Advanced Intelligent Systems

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The emergence of severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2), the virus that led to the COVID‐19 (Coronavirus Disease 2019) pandemic, has resulted in substantial overburdening of healthcare systems as well as an economic crisis on a global scale. This has in turn resulted in widespread efforts to identify suitable therapies to address this aggressive pathogen. Therapeutic antibody and vaccine development are being actively explored, and a phase I clinical trial of mRNA‐1273 which is developed in collaboration between the National Institute of Allergy and Infectious Diseases and Moderna, Inc. is currently underway. Timelines for the broad deployment of a vaccine and antibody therapies have been estimated to be 12–18 months or longer. These are promising approaches that may lead to sustained efficacy in treating COVID‐19. However, its emergence has also led to a large number of clinical trials evaluating drug combinations composed of repurposed therapies. As study results of these combinations continue to be evaluated, there is a need to move beyond traditional drug screening and repurposing by harnessing artificial intelligence (AI) to optimize combination therapy design. This may lead to the rapid identification of regimens that mediate unexpected and markedly enhanced treatment outcomes.

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“…The AI‐PRS approach is a new paradigm for identifying highly synergistic drug regimens for the treatment of disease based upon the observation that drug‐dose inputs are correlated with phenotypic outputs (e.g., amelioration of a disease state) in numerous biological systems by a parabolic response surface; such a surface is described by a quadratic algebraic equation . The AI‐PRS approach, which is output driven and hence agnostic to drug mechanism, has been applied to identify synergistic drug combinations to address a large variety of medical problems including treatment of cancer (hepatocellular, breast, ovarian, colon, renal, and bladder carcinoma; multiple myeloma; acute lymphoblastic leukemia) and infectious diseases (herpes simplex virus‐1 infection; parasitic nematode infection) and suppression of rejection in liver transplantation …”

Section: Introductionmentioning

confidence: 99%

AI‐Enabled Parabolic Response Surface Approach Identifies Ultra Short‐Course Near‐Universal TB Drug Regimens

Horwitz

Clemens

Lee

2019

Advanced Therapeutics

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Tuberculosis (TB) is a major health problem that causes more deaths worldwide than any other single infectious disease. Current multidrug therapy for tuberculosis is exceedingly lengthy, leading to poor drug adherence, and consequently the emergence of drug resistance. Hence, much more rapid treatments are needed. Experimentally identifying the most synergistic drug combinations among available drugs is complicated by the astronomical number of possible drug-dose combinations. This problem is dealt with by the use of an artificial-intelligence-enabled parabolic response surface platform in conjunction with an in vitro Mycobacterium tuberculosis-infected macrophage cell culture assay amenable to high-throughput screening. This strategy allows rapid identification of the most effective drug-dose combinations by testing only a small fraction of the total drug-dose efficacy response surface. The same platform is then used to optimize the in vivo doses of each drug in the most potent regimens. Thus, regimens are identified that are dramatically more effective than the Standard Regimen in treating TB in a mouse model-a model broadly predictive of drug efficacy in humans. The most effective regimens reported herein shorten the duration of treatment required to achieve relapse-free cure by 80% and are suitable for treating both drug-sensitive and most drug-resistant cases of tuberculosis.

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Optimizing drug combinations against multiple myeloma using a quadratic phenotypic optimization platform (QPOP)

Cited by 89 publications

References 61 publications

Targeting Dopamine D₂, Adenosine A_2A, and Glutamate mGlu₅ Receptors to Reduce Repetitive Behaviors in Deer Mice

Targeting Dopamine D₂, Adenosine A_2A, and Glutamate mGlu₅ Receptors to Reduce Repetitive Behaviors in Deer Mice

Addressing COVID‐19 Drug Development with Artificial Intelligence

AI‐Enabled Parabolic Response Surface Approach Identifies Ultra Short‐Course Near‐Universal TB Drug Regimens

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Optimizing drug combinations against multiple myeloma using a quadratic phenotypic optimization platform (QPOP)

Cited by 89 publications

References 61 publications

Targeting Dopamine D2, Adenosine A2A, and Glutamate mGlu5 Receptors to Reduce Repetitive Behaviors in Deer Mice

Targeting Dopamine D2, Adenosine A2A, and Glutamate mGlu5 Receptors to Reduce Repetitive Behaviors in Deer Mice

Addressing COVID‐19 Drug Development with Artificial Intelligence

AI‐Enabled Parabolic Response Surface Approach Identifies Ultra Short‐Course Near‐Universal TB Drug Regimens

Contact Info

Product

Resources

About

Targeting Dopamine D₂, Adenosine A_2A, and Glutamate mGlu₅ Receptors to Reduce Repetitive Behaviors in Deer Mice

Targeting Dopamine D₂, Adenosine A_2A, and Glutamate mGlu₅ Receptors to Reduce Repetitive Behaviors in Deer Mice