Positive Allosteric Modulators (PAMS) of Strychnine-Sensitive Glycine Receptors - A New Concept in Treating Chronic Pain
Lead Research Organisation:
University of Liverpool
Department Name: Institute of Translational Medicine
Abstract
The Problem/Background:
Our project addresses the longstanding urgent, unmet medical need of chronic pain. This debilitating condition affects about 20% of adults in Europe and in the USA, i.e. more than 8 million adult patients in the UK alone, wrecking individual lives and causing huge economical damage, predominantly in terms of lost working days. One key issue is the fact that the symptomatic medication currently available is effective only in about 40% of chronic pain sufferers and even these patients struggle to maintain the balance between adequate pain relief and their ability to cope with the substantive drug-induced adverse effects. This creates a vicious cycle of insufficient analgesia and unbearable side effects ultimately leading to discontinuation of treatment. Despite these problems growth in the neuropathic pain market alone is forecasted to rise to over $6.3 billion by 2017.
The Concept:
As regards understanding the pathophysiology of chronic pain there is evidence that loss of inhibitory neuronal transmission within the spinal cord plays a key role. This reduced capacity to inhibit nerve activity, comparable to defective dampers inside a piano, contributes to a functional dysequilibrium state of the central nervous system referred to as central pain sensitisation. The loss involves a particular type of cell membrane-spanning protein channels operated by distinct messenger molecules, mainly glycine. Thus, enhancement of glycinergic neurotransmission should compensate for this loss.
Our Proposal/Solution - A First-In-Kind Causal Treatment:
Consequently, we propose to develop a novel class of compounds which do enhance glycinergic neurotransmission effectively and selectively at the spinal cord level, thereby achieving the intended effect while avoiding unwanted and dangerous side effects, e.g. deep sedation/loss of consciousness. By the end of this project we should to be ready for development into a drug that will be taken orally for a limited period of time in order to reset the proper equilibrium state of the patient's central nervous system. Our ultimate aim is allowing chronic pain patients to regain a dramatically improved quality of life.
What has been achieved so far: We have successfully progressed to the discovery/synthesis of a novel class of compounds with selective enhancing effects at strychnine-sensitive glycine receptors, which do not mediate sedative effects. We are confident that this feature makes our development program highly competitive, viable and significant and have protected the Intellectual Property by filing a composition of matter patent. Moreover, we have obtained proof-of-concept for one key compound in a rat model of neuropathic pain.
Work Plan: The project is currently in the hit-to-lead stage development stage, i.e., we do already know that our concept works but we need to further improve chemistry features of our compounds in preparation for our ultimate aim, i.e. generating drugs which are safe/effective and can be taken orally, e.g. 3 times/day. We plan to achieve such optimised leads within two years.
Impact:
In view of the huge numbers of patients worldwide whose lives are wrecked by chronic pain, the fact that current treatment options are clearly insufficient and the dramatic toll on economies caused by millions of lost working hours, it is safe to say that our first-in-kind causal treatment option has the potential to have a dramatic beneficial impact on individuals and societies.
Our Solution Has Potential To Be A Platform-Technology:
We are confident, that our proposal can provide a platform technology addressing further medical conditions, e.g., opioid-withdrawal, alcoholism and anxiety.
Planned Route-to-Market/Exit Strategy:
Two pharmaceutical companies, Grunenthal and B.Braun have confirmed their desire to collaborate with our group, and each other, in the event of a successful completion of this programme.
Our project addresses the longstanding urgent, unmet medical need of chronic pain. This debilitating condition affects about 20% of adults in Europe and in the USA, i.e. more than 8 million adult patients in the UK alone, wrecking individual lives and causing huge economical damage, predominantly in terms of lost working days. One key issue is the fact that the symptomatic medication currently available is effective only in about 40% of chronic pain sufferers and even these patients struggle to maintain the balance between adequate pain relief and their ability to cope with the substantive drug-induced adverse effects. This creates a vicious cycle of insufficient analgesia and unbearable side effects ultimately leading to discontinuation of treatment. Despite these problems growth in the neuropathic pain market alone is forecasted to rise to over $6.3 billion by 2017.
The Concept:
As regards understanding the pathophysiology of chronic pain there is evidence that loss of inhibitory neuronal transmission within the spinal cord plays a key role. This reduced capacity to inhibit nerve activity, comparable to defective dampers inside a piano, contributes to a functional dysequilibrium state of the central nervous system referred to as central pain sensitisation. The loss involves a particular type of cell membrane-spanning protein channels operated by distinct messenger molecules, mainly glycine. Thus, enhancement of glycinergic neurotransmission should compensate for this loss.
Our Proposal/Solution - A First-In-Kind Causal Treatment:
Consequently, we propose to develop a novel class of compounds which do enhance glycinergic neurotransmission effectively and selectively at the spinal cord level, thereby achieving the intended effect while avoiding unwanted and dangerous side effects, e.g. deep sedation/loss of consciousness. By the end of this project we should to be ready for development into a drug that will be taken orally for a limited period of time in order to reset the proper equilibrium state of the patient's central nervous system. Our ultimate aim is allowing chronic pain patients to regain a dramatically improved quality of life.
What has been achieved so far: We have successfully progressed to the discovery/synthesis of a novel class of compounds with selective enhancing effects at strychnine-sensitive glycine receptors, which do not mediate sedative effects. We are confident that this feature makes our development program highly competitive, viable and significant and have protected the Intellectual Property by filing a composition of matter patent. Moreover, we have obtained proof-of-concept for one key compound in a rat model of neuropathic pain.
Work Plan: The project is currently in the hit-to-lead stage development stage, i.e., we do already know that our concept works but we need to further improve chemistry features of our compounds in preparation for our ultimate aim, i.e. generating drugs which are safe/effective and can be taken orally, e.g. 3 times/day. We plan to achieve such optimised leads within two years.
Impact:
In view of the huge numbers of patients worldwide whose lives are wrecked by chronic pain, the fact that current treatment options are clearly insufficient and the dramatic toll on economies caused by millions of lost working hours, it is safe to say that our first-in-kind causal treatment option has the potential to have a dramatic beneficial impact on individuals and societies.
Our Solution Has Potential To Be A Platform-Technology:
We are confident, that our proposal can provide a platform technology addressing further medical conditions, e.g., opioid-withdrawal, alcoholism and anxiety.
Planned Route-to-Market/Exit Strategy:
Two pharmaceutical companies, Grunenthal and B.Braun have confirmed their desire to collaborate with our group, and each other, in the event of a successful completion of this programme.
Technical Summary
Our project addresses the longstanding unmet need of chronic pain. This debilitating condition affects about 20% of adults in Europe and in the USA, one key issue being the fact that patients struggle to maintain the balance between adequate pain relief and their ability to cope with the substantive side effects caused by the symptomatic medication available. We have successfully progressed from target validation/hit identification to the discovery of a novel class of compounds with low nM positive allosteric modulating activity at alpha1 glycine receptors. Such an action compensates for the loss of inhibitory synaptic transmission within the dorsal horn of the spinal cord, which plays a key role in central pain sensitisation.
Here we propose to advance these early leads through lead development/optimisation to realise a quality lead molecule appropriate for further exploitation, aiming at a causal treatment for chronic pain.
Significant progress has been made so far funded by NESTech and the EPSRC/KTA leading to the filing of a composition of matter patent. For the first generation of compounds we have obtained successful proof-of-efficacy/selectivity in neuronal network models and proof-of-concept in vivo in a neuropathic pain rat model (intrathecal as well as oral administration). Moreover we have generated further hits while synthesising new optimised compounds.
As our main objective is an optimised lead series we will:
1) sequentially and systematically remove chemical liabilities
2) run SAR analysis and ligand-based design to create new analogues with improved potency, specificity and physico-chemical characteristics
3) evaluate the most promising leads with appropriate in vivo and ex vivo screens and derisk them by standard pharmacokinetic and toxicology experiments.
Two pharmaceutical companies, Grunenthal and B.Braun have confirmed their desire to collaborate with our group, and each other, in the event of a successful completion of this programme
Here we propose to advance these early leads through lead development/optimisation to realise a quality lead molecule appropriate for further exploitation, aiming at a causal treatment for chronic pain.
Significant progress has been made so far funded by NESTech and the EPSRC/KTA leading to the filing of a composition of matter patent. For the first generation of compounds we have obtained successful proof-of-efficacy/selectivity in neuronal network models and proof-of-concept in vivo in a neuropathic pain rat model (intrathecal as well as oral administration). Moreover we have generated further hits while synthesising new optimised compounds.
As our main objective is an optimised lead series we will:
1) sequentially and systematically remove chemical liabilities
2) run SAR analysis and ligand-based design to create new analogues with improved potency, specificity and physico-chemical characteristics
3) evaluate the most promising leads with appropriate in vivo and ex vivo screens and derisk them by standard pharmacokinetic and toxicology experiments.
Two pharmaceutical companies, Grunenthal and B.Braun have confirmed their desire to collaborate with our group, and each other, in the event of a successful completion of this programme
Planned Impact
Who will benefit
Patients (Worldwide)
Our project addresses the longstanding urgent, unmet medical need of chronic pain. This debilitating condition affects about 20% of adults in Europe and in the USA, i.e. more than 8 million patients in the UK alone, wrecking individual lives and causing huge economical damage, predominantly in terms of lost working days. One key issue is the fact that the symptomatic medication currently available is effective only in about 40% of chronic pain sufferers and even these patients struggle to maintain the balance between adequate pain relief and their ability to cope with the substantive drug-induced adverse effects. This creates a vicious cycle of insufficient analgesia and unbearable side effects ultimately leading to discontinuation of treatment.
Consequently, our project - by providing a first-in-kind causal treatment of chronic pain - will have a huge impact on patients' quality of life.
Commercial/Private Sector
Despite the current lack of efficient, reliable and tolerable treatment options for chronic pain growth in the neuropathic pain market alone is forecasted to rise to over $6.3 billion by 2017.
The industrial beneficiaries will be pharmaceutical companies with a focus on analgesics (in the context of this project we have engaged initially with Grunenthal and B.Braun).
Contribution to the Nation's Health/Wealth
In the best-case-scenario our proposed solution, which would provide a first-in-kind causal treatment, would dramatically reduce incidence and prevalence of chronic pain worldwide, thereby removing the cause for millions of lost working hours/year and vastly reducing the economic burden on societies.
Our solution has the potential to benefit about 8 million adult patients in the UK alone. As all these estimates refer exclusively to adult chronic pain patients it is safe to assume that the number of beneficiaries including e.g. adolescent chronic back pain patients will actually be even bigger.
Moreover, society, in particular the NHS will benefit from the trained personnel emerging from the programme equipped to contribute to UK industry in a high-tech sector. Longer term benefits will arise from the scientific advances enabling the development of new drugs for the treatment/prevention of chronic pain with associated health and environmental benefits which will give the UK economy a strong competitive edge in this field.
Individual Staff Working on the Project
The skills and contact network of the members of our research group, in particular, the project RAs will be strongly enhanced by close experiment/theory co-working in a cutting-edge translational science area, and engagement with pharmaceutical companies active in this field.
Patients (Worldwide)
Our project addresses the longstanding urgent, unmet medical need of chronic pain. This debilitating condition affects about 20% of adults in Europe and in the USA, i.e. more than 8 million patients in the UK alone, wrecking individual lives and causing huge economical damage, predominantly in terms of lost working days. One key issue is the fact that the symptomatic medication currently available is effective only in about 40% of chronic pain sufferers and even these patients struggle to maintain the balance between adequate pain relief and their ability to cope with the substantive drug-induced adverse effects. This creates a vicious cycle of insufficient analgesia and unbearable side effects ultimately leading to discontinuation of treatment.
Consequently, our project - by providing a first-in-kind causal treatment of chronic pain - will have a huge impact on patients' quality of life.
Commercial/Private Sector
Despite the current lack of efficient, reliable and tolerable treatment options for chronic pain growth in the neuropathic pain market alone is forecasted to rise to over $6.3 billion by 2017.
The industrial beneficiaries will be pharmaceutical companies with a focus on analgesics (in the context of this project we have engaged initially with Grunenthal and B.Braun).
Contribution to the Nation's Health/Wealth
In the best-case-scenario our proposed solution, which would provide a first-in-kind causal treatment, would dramatically reduce incidence and prevalence of chronic pain worldwide, thereby removing the cause for millions of lost working hours/year and vastly reducing the economic burden on societies.
Our solution has the potential to benefit about 8 million adult patients in the UK alone. As all these estimates refer exclusively to adult chronic pain patients it is safe to assume that the number of beneficiaries including e.g. adolescent chronic back pain patients will actually be even bigger.
Moreover, society, in particular the NHS will benefit from the trained personnel emerging from the programme equipped to contribute to UK industry in a high-tech sector. Longer term benefits will arise from the scientific advances enabling the development of new drugs for the treatment/prevention of chronic pain with associated health and environmental benefits which will give the UK economy a strong competitive edge in this field.
Individual Staff Working on the Project
The skills and contact network of the members of our research group, in particular, the project RAs will be strongly enhanced by close experiment/theory co-working in a cutting-edge translational science area, and engagement with pharmaceutical companies active in this field.
Publications
Eckle VS
(2014)
4-bromopropofol decreases action potential generation in spinal neurons by inducing a glycine receptor-mediated tonic conductance.
in British journal of pharmacology
De La Roche J
(2012)
4-Chloropropofol enhances chloride currents in human hyperekplexic and artificial mutated glycine receptors.
in BMC neurology
| Description | PAMS |
| Organisation | Eberhard Karls University of Tübingen |
| Department | Experimental Anaesthesiology |
| Country | Germany |
| Sector | Academic/University |
| PI Contribution | Invention/synthesis of compounds for prevention/treatment of central pain sensitisation |
| Collaborator Contribution | Efficacy/selectivity in neuronal network models |
| Impact | N/A |
| Start Year | 2013 |
| Description | PAMS |
| Organisation | King's College London |
| Department | Pain and Neurorestoration |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Invention/synthesis of compounds for prevention/treatment of central pain sensitisation |
| Collaborator Contribution | In-vivo proof-of-concept experiments |
| Impact | Preliminary proof-of-concept |
| Start Year | 2013 |
| Description | PAMS |
| Organisation | Technical University of Darmstadt |
| Department | Neurophysiology |
| Country | Germany |
| Sector | Academic/University |
| PI Contribution | Invention/synthesis of compounds for prevention/treatment of central pain sensitisation |
| Collaborator Contribution | In-vitro efficacy/selectivity |
| Impact | Confirmation of hits |
| Start Year | 2012 |
| Title | Analgesia |
| Description | Protection of a novel class of positive allosteric modulators of strychnine-sensitive glycine receptors aiming at prevention/treatment of chronic pain |
| IP Reference | AWE/P210534GB |
| Protection | Patent application published |
| Year Protection Granted | 2015 |
| Licensed | No |
| Impact | We are currently in negotiations with potential investors. |
| Title | PHARMACOLOGICALLY ACTIVE COMPOUNDS |
| Description | 'Composition-of-matter' protection for PAMS (morpholino-derivatives of di-isopropylphenol), a first-in-class family of compounds aiming at preventing/treating chronic pain |
| IP Reference | EP3087055 |
| Protection | Patent granted |
| Year Protection Granted | 2016 |
| Licensed | No |
| Impact | 'Composition-of-matter' protection for PAMS (morpholino-derivatives of di-isopropylphenol), leading to a collaboration contract with NIH/NINDS with regard to investigating PAMS' potential as anti-epileptic drugs |
| Title | PHARMACOLOGICALLY ACTIVE COMPOUNDS |
| Description | wherein Q is as defined herein. The compounds of formula I act as selective positive allosteric modulators of strychnine-sensitive alpha 1-glycine receptors. The present invention further relates to the use of these compounds as therapeutic agents for the treatment and/or prevention of diseases or conditions in which strychnine-sensitive alpha 1-glycine receptor activity is implicated (such as, for example, chronic pain. The present invention also relates to processes for the preparation of these compounds and to pharmaceutical compositions comprising them. |
| IP Reference | US2016318947 |
| Protection | Patent granted |
| Year Protection Granted | 2016 |
| Licensed | No |
| Impact | Led to a collaboration contract with NIH/NINDS on investigating PAMS' potential as novel anti-epileptic drugs (2018) |
| Description | Involving RCoA/NIAA/Patient Representatives |
| Form Of Engagement Activity | A formal working group, expert panel or dialogue |
| Part Of Official Scheme? | Yes |
| Type Of Presentation | Paper Presentation |
| Geographic Reach | National |
| Primary Audience | Participants in your research and patient groups |
| Results and Impact | Discussion with the Research Council of the NIAA involving patient representatives leading to a formal letter of support attached to the MRC DPFS full application Formal letter of support submitted with the full application to MRC DPFS |
| Year(s) Of Engagement Activity | 2012 |
| Description | Symposium 'Molecular Mechanisms of Anaesthesia', MAC 2015, Bonn, Germany |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Professional Practitioners |
| Results and Impact | Invited organisation of a Symposium ('Transmitter-gated CNS chloride channels - New targets for emerging drugs combating chronic pain'). About 250 international researchers attended. The presentations were well received and sparked a prolific debate leading to new collaborations. |
| Year(s) Of Engagement Activity | 2015 |