PAINS and Prejudice

PAINS (pan assay interference compounds) filters have exerted a hold over the drug discovery community ever since the BH2010 study appeared over 15 years ago. Initially I didn’t take much notice of PAINS filters and, in any case, I’d already moved on from analysis of high-throughput screening (HTS) output by that point (I might add ‘thankfully’ because looking at too much HTS output is a sure-fire route to the funny farm). I started analysing HTS output from about 1993 at what was then Zeneca. I used the Daylight toolkit to create the Struct_Anal SMARTS-based chemical structure profiler in 1995 and, at that time, we were already using in house software named Flush (even at that stage it was clear that much of the HTS output being generated was going to disappear round the S-bend and our friends at what was then Rhône-Poulenc Rorer developed HARPick to ensure that nothing remained stuck to the porcelain).

Photo from 2011 at 'The Black Hole' (Los Alamos NM)

Something that had always worried me was that it was very easy to opine that a compound looked nasty but it was much more difficult to demonstrate objectively that the compound was indeed nasty. Late in 2014 a blog post, which fell well short of the standards that the drug discovery community has come to expect from Practical Fragments, prompted me to take a more forensic look at PAINS filters. What I found was that PAINS filters were based on the output from screening compounds in just six AlphaSceen assays (if a panel of six assays that all use the same read-out strikes you as suboptimal design of an experiment to detect pan-assay interference then you’re not alone). After blogging periodically about PAINS filters for a couple of years I wrote a Perspective on the topic (as noted in this blog post: from time to time, every blogger should write a journal article “pour encourager les autres”).

Nevertheless, doubts about the correctness of my position started to creep in when I was denounced for being insufficiently thoughtful in my published comments on PAINS by the authors, one of whom is a former colleague, of the seminal, insightful and Nobel-worthy ‘Seven Year Itch’ article (BN2017) which oozes wisdom and penetrating insight. Although stung by the criticism and wracked by self-doubt to the extent that I considered therapy, it was a recent study led by the world-renowned expert on tetrodotoxin pharmacology, Prof. Angelique Bouchard-Duvalier of the Port-au-Prince Institute of Biogerontology, working in collaboration with the Budapest Enthalpomics Group (BEG), that removed any lingering doubts about the sublime elegance and extreme predictivity of PAINS filters. The manuscript has not yet been made publicly available although I was able to access it with the help of my associate ‘Anastasia Nikolaeva’ (not sure exactly what she’s doing these days although I understand that she’s currently visiting Port-au-Prince for a medication review with Prof. Bouchard-Duvalier). There is no doubt that this genuinely disruptive study will comprehensively reshape the predictive biochemistry landscape, enabling drug discovery scientists to accurately, meaningfully and robustly predict assay interference using only chemical structures as input for the very first time.

Prof. Bouchard-Duvalier’s seminal study clearly demonstrates that singlet oxygen quenching is actually a conserved feature for all known and unknown mechanisms of interference with assay read-outs and that PAINS filters dramatically outperform all other methods for prediction of assay interference. The math is truly formidable (the rudimentary nature of my understanding of Haitian patois didn’t help either) and involves first projecting the atomic isothermal compressibility matrix into the quadrupole-normalized polarizability tensor before applying the Barron-Samedy transformation, followed by hepatic eigenvalue extraction using a the elegant algorithm devised by E. V. Tooms (a reclusive Baltimore resident and connoisseur of liver pâté whose illustrious thought leadership of the analytic topology field unravelled almost 32 years ago after he failed to comply with the safety instructions for an escalator). The incisive analysis of Prof. Bouchard-Duvalier shows without a shadow of doubt that singlet oxygen quenching as quantified by the AlphaScreen assay read-out is a fundamental principle in biomolecular assay science. Furthermore, ‘Anastasia Nikolaeva’ was also able to ‘liberate’ a prepared press release in which the grinning BEG director Prof. Kígyó Olaj explains: 

Possibilities are limitless now that we can accurately and robustly predict the assay interference that compounds will exhibit directly from their chemical structures and we can safely consign experimental biochemical assays to the dustbin of history. Surely the Journal of Medicinal Chemistry Editors will now finally recognize the colossal impact that PAINS filters have made on real world drug discovery and development when they make their FIFA Prize nominations later this year.

 

Hit to Lead best practice?

I'm now in Trinidad and I'll share a 180° panorama from Paramin where I walk for exercise. This district in Trinidad's Northern Range is renowned for its agriculture and the most excellent produce is grown in 'gardens' on steep hillsides. My walk would take about two and a quarter hours if I just walked but it usually takes rather longer because I like to take photos and often stop on the ridge to gaze at corbeaux 'surfing' the updrafts. Most of all I enjoy catching up with friends in Paramin and not so long ago one of them was telling me about the sound made by douens (which have terrified me since childhood because I was never baptised). Some years ago I was struggling along the ridge with a hacking cough that I'd brought with me from the UK three days previously when I heard a familiar voice (one of my friends was visiting his sister). The conversation turned to my cough and he instructed his sister to bring some medicine. She produced a bottle of a liquid that looked like fluorescein and, as she decanted some into a shot glass my friend exclaimed "dat too much yuh go kill he". The liquid appeared to have a puncheon base and my friend's sister also gave me some bush to make tea. My cough was history after three days.             

I’ll be taking a look at The European Federation for Medicinal Chemistry and Chemical Biology (EFMC) Best Practice Initiative: Hit to Lead (Q2025) in this post. I have a number of criticisms of this work and it really shouldn’t need saying that you do raise the bar for yourself when you present your work as defining best practices. As is customary for blog posts here at Molecular Design I’ve used Q2025 reference numbers when referring to literature studies and quoted text is indented with my comments in red italics. This will be a long tedious post and strong coffee is recommended.

Best practices are, in essence, recommended ways of doing things and it’s actually very difficult to demonstrate objectively that one way of doing things is better (or worse) than another way. My general view of Q2025 is of a poorly organized article that at times lacks clarity and coherence. Some of the advice offered on how best to do Hit to Lead (H2L) work is unsound and the Authors also make a number of significant errors. Although the abstract refers to “contemporary drug discovery” the recommended best practices do, in my view, appear to be firmly rooted in the past given that that fragment-based design (FBD) is not covered and there is no mention of important 'new' modalities such as irreversible covalent inhibition and targeted protein degradation. It’s worth mentioning that biological activity for some new modalities cannot be meaningful quantified as a single parameter such as an IC₅₀ value and this complicates the use of ligand efficiency metrics (a post on covalent ligand efficiency will give you an idea of the tangles you can get yourself into) which the Authors seem to consider important in H2L work. I consider the quantity of literature cited in  Q2025 to be excessive, especially given that some of the cited articles have minimal relevance to H2L work (the failure of the Authors to cite R2009 is also noteworthy). In some cases the cited literature does not support assertions made by the Authors. In my view Figures 1, 5 and 8 are redundant.

While I see plenty wrong with Q2025 it’s worth flagging up points on which the Authors and I appear to be in agreement. I think that they put it well with the following statement: 

Leads have line of sight to a development candidate and bring an understanding of what priorities Lead Optimisation should address.

I used this football analogy in an earlier post:

The screening phase is followed by the hit-to-lead phase and it can be helpful to draw an analogy between drug discovery and what is called football outside the USA. It’s not generally possible to design a drug from screening output alone and to attempt to do so would be the equivalent of taking a shot at goal from the centre spot. Just as the midfielders try move the ball closer to the opposition goal, the hit-to-lead team use the screening hits as starting points for design of higher affinity compounds. The main objective in the hit-to-lead phase is to generate information that can be used for design and mapping structure-activity relationships for the more interesting hits is a common activity in hit-to-lead work.

I certainly agree that it is important to establish structure-activity relationships (SARs) for structural series of interest although I have no idea what the Authors mean by “dynamic SAR”. I also agree that consideration of physicochemical properties, especially lipophilicity, is very important in H2L work (just as it is in optimisation of the leads) although the case for a Nobel Prize made in a 2024 JMC Editorial does, in my view, appear to have been overcooked.

I argue that drug discovery should be seen in a Design of Experiments framework (generate the information that you need as efficiently as possible) rather than as the prediction exercise that many who tout machine learning (ML) as a panacea for the ills of Pharma & Biotech would have you believe. Regardless of which view prevails it’s abundantly clear that generation and analysis of data are very important in contemporary drug discovery and are likely to become even more important in the future). However, if you’re going to base decisions on trends in data then it’s important that you know how strong the trends are because this tells you how much weight to give to the trends when making your decisions. Most drug discovery scientists will have encountered analyses of relationships between predictors of ADME (absorption, distribution, metabolism, and excretion) and physicochemical and chemical structure descriptors and we observed in the KM2013 perspective that:

The wide acceptance of Ro5 provided other researchers with an incentive to publish analyses of their own data and those who have followed the drug discovery literature over the last decade or so will have become aware of a publication genre that can be described as ‘retrospective data analysis of large proprietary data sets’ or, more succinctly, as ‘Ro5 envy’.

In some cases trends observed in data are presented in ways that make them appear to be stronger than they actually are (this is typically achieved by categorizing continuous-valued data prior to analysis) and [13a], [24] and [26] were criticised in this context in KM2013. When reading articles on drug-likeness and compound quality it is also important to be aware that correlation does not imply causation.  One should be particularly wary of of studies such as [20c] which present analyses of proprietary data as "facts" or claim that such analyses have revealed "principles". I see the weakness of these trends partly as a reflection of chemical structure diversity in datasets and would expect the corresponding trends to be stronger within structural series (I offer the following advice in NoLE):

Drug designers should not automatically assume that conclusions drawn from analysis of large, structurally-diverse data sets are necessarily relevant to the specific drug design projects on which they are working.

I see erosion of critical thinking skills as a significant problem in contemporary drug discovery and some leaders in the field appear to have lost the ability to distinguish what they know from what they believe. As I observed in a review of a 2024 JMC Editorial (Property-Based Drug Design Merits a Nobel Prize) the Rule of 5 (Ro5) is not actually supported by data in the form that it was stated. The wide acceptance of Ro5 as a definition of drug-likeness propagates what I consider to be a misleading view that drugs occupy a contiguous and distinct region of chemical space. Some of the claims made in the JMC Editorial (“a compound is more likely to be clinically developable when LipE > 5”, “a discovery compound is more likely to become a drug when Fsp3 > 0.40” and “a compound is more likely to have good developability when PFI < 7”) do not appear to be based on data. I remain sceptical that developability and likelihood of clinical success of a compound can be meaningfully assessed even when one knows that the compound actually exhibits exploitable activity against the target(s) of interest. In my view the suggestion that simple drug discovery guidelines are worthy of a Nobel Prize does a huge disservice to drug discovery scientists by trivializing the very significant challenges that they face.   

Like many in the drug discovery field, I consider lipophilicity to be the single most important physicochemical property in drug discovery and I would generally anticipate that a surfeit of lipophilicity will end in tears. That said, I don't consider lipophilicity to be usefully predictive of physicochemical properties such as permeability and aqueous solubility that are more relevant than lipophilicity from the perspective of oral absorption. When I assert that lipophilicity is not "usefully predictive" I'm certainly not denying that trends in data exist. However, I must stress that the trends are not so strong that having solubility values that have been predicted from lipophilicity means that you no longer need to measure aqueous solubility.    

In drug discovery projects I generally recommend examination of the response of potency (expressed as a logarithm) to increased lipophilicity. In the ideal situation the correlation of potency with lipophilicity will be weak, indicating that potency is driven by factors other than lipophilicity. If the correlation of potency with lipophilicity is strong then you need the response (the slope for a linear correlation) to be relatively steep. I consider it to be generally helpful to plot potency against lipophilicity with reference lines corresponding to different LipE values (see R2009 which is a lot more relevant to H2L work than much of the literature cited in the Q2025 study) and I would also suggest modelling the response and using the residuals to quantify the extent that individual potency measurements beat (or are beaten by) the trend in the data (the approach is outlined in the "Alternatives to ligand efficiency for normalization of affinity" section of NoLE).

In drug discovery lipophilicity is usually quantified by the logarithm of the octanol/water partition coefficient (log P) or distribution coefficient (log D). The choice of octanol/water for quantification of lipophilicity is arbitrary and some, including me, consider saturated hydrocarbons such as cyclohexane or hexadecane to be physically more realistic than octanol as a model for the core of a lipid bilayer. It is the distribution coefficient (D) rather than the partition coefficient (P) that is measured for lipophilicity assessment although the two quantities are equivalent when ionization can be safely neglected. Values of logP for ionizable compounds can be derived from the response of log D to pH although this is not generally done routinely in in drug discovery. Alternatively, you can make the assumption that only neutral forms of compounds partition into the organic phase and use (1) in the H2L best practices post graphic (see also K2013) to convert log D values to log P values (to do this you’ll also need a reliable estimate for pKa in order to calculate the neutral fraction). When log D (as opposed to log P) is used to assess the ‘quality’ of compounds you can make compounds better simply by increasing the extent to which they are ionized and I hope you can see that going down this path is likely to end as well as things did for the Sixth Army at Stalingrad.

In drug discovery log P values are typically calculated and it can often be quite difficult when reading the literature to know which method has been used for the calculations (sometimes the term ‘cLogP’ appears to have been used simply to denote that log P values have been calculated).  For example, it is stated in [13a] that “Physical property data were obtained from AstraZeneca’s C-Lab tool, incorporating standard packages for LogP calculations (cLogP, ACDLogP), and an in-house algorithm for the distribution coefficient (1-octanol–water LogD at pH 7.4)”. In general, different prediction methods will give different log P values for the same compound (for example the Ro5 lipophilicity threshold is 5 when ClogP is used but 4.15 when MlogP is used). That said, choice of method for predicting log P and whether you use measured log D or predicted log P become less important issues when working within structural series because hydrogen bond donors and acceptors, and ionizable groups tend to be relatively conserved under this scenario.

That log D and log P are different quantities in the context of drug design is one of a number of things that the Authors of [34a] (Molecular Property Design: Does Everyone Get It?) just don’t seem to ‘get’ and I’ll point you toward a blog post in which this point is discussed in a bit more detail. Let’s examine Figure 2 (Impact of hydrophobicity on developability assays and the profile of marketed oral drugs) of [34a] and I’d like you to look at the upper panel (a). You’ll notice that the visualization for some of the ‘developability’ assays is based on PFI (derived from log D measured chromatographically at pH 7.4). However, the visualization for hERG (+1 charge) and promiscuity is based on iPFI (derived from ‘Chrom logP’ and it is not clear how this quantity was defined or generated). I would also argue that the activity criterion (pIC₅₀ > 5) used in the promiscuity analysis is too permissive to be physiologically relevant (this is a common issue in the promiscuity literature). As an aside, I am unconvinced that log D values were actually measured chromatographically at pH 7.4 for all the drugs that form the basis of the analysis shown in the lower panel (b) of Figure 2.        

After a long preamble it’s time to start my review of Q2025 and comments will follow the order of the article. I see the citation of [2] and [3] as gratuitous while [4] does not appear to present evidence in support of the claim that “ensuring high quality of lead series is a large cost and time saver in the overall process of drug discovery” (it must be stressed that I certainly don’t deny the value of high quality lead series and am merely pointing out that the chosen reference does not actually demonstrate that higher quality of lead series result in cost and time savings in drug discovery).

In my view neither Figure 1 nor its caption (see below) makes any sense.

Figure 1. Illustration of the multi-objective characterisation necessary in the journey from a hit to a drug. All these necessary characteristics, described by illustrative principal components, are influenced by the physicochemical properties of the molecules.

You’ll frequently encounter graphics like Figure 1 that show low-dimensional chemical spaces in the drug discovery literature (for example, a 2-dimemsional space might be specified in terms of lipophilicity and molecular size). While it’s very easy to generate graphics like these the relevance of the chemical spaces to drug design is often unclear. There are ways in which you can demonstrate the relevance of a chemical space to drug design and, for example, you might build usefully predictive models for quantities such as IC₅₀, aqueous solubility or permeability using only the dimensions of the particular chemical space as descriptors. Alternatively, you could show that compounds in mutually exclusive categories such as ‘progressed to phase 2’ and ‘failed to progress to phase 2’ occupy different regions of the chemical space (note that it’s not sufficient to show that a single class of compounds such as ‘approved drugs’ occupies a particular region within the chemical space and this is the essence of a general criticism that I make of Ro5 and QED). It is common to depict the different categories as ellipses that enclose a given fraction of the data points corresponding to each category and the orientation of each ellipse with respect to the axes indicates the degree to which the descriptors that define the chemical space are correlated for each category. One problem with Figure 1 is that the meaning of the ellipses is unclear and I would challenge the assertion made by the Authors that “the journey of a drug discovery campaign is characterized in Figure 1, showing how the active hit needs to be modified to address the requirements impacting the efficacy and safety of the molecule”.

Potency optimisation alone is not a viable strategy towards the discovery of efficacious and safe drugs, or even high-quality leads. Concurrent optimisation of the physicochemical properties of a molecule is the most important facet of drug discovery, as these properties influence its behaviours, disposition and efficacy [12a | 12b]. [While I certainly agree that there is a lot more to drug design than maximisation of potency I would argue that controlling exposure is a more important objective than optimization of physicochemical properties (on the subject of exposure I recommend that all drug discovery scientists take a look at the SM2019 article). It's also worth bearing in mind that you can't compensate for inadequate potency with increased compound quality. I don't consider either reference as evidence that "concurrent optimisation of the physicochemical properties of a molecule is the most important facet of drug discovery" and it is not accurate to describe metabolic stability, active efflux and  affinity for anti-targets as "physicochemical properties".  I think the Authors need to say more about which physicochemical properties they recommend to be optimized and be clearer about exactly what constitutes optimization. Lipophilicity alone is not usefully predictive of properties such as bioavailability, distribution and clearance that determine the effects of drugs in vivo.] Together these outcomes define the quality of the molecule, indicative of its chances of success in the clinic, as evidenced in numerous studies [13a | 13b]. [Neither of these articles appears to provide convincing evidence of a causal relationship between “the quality of a molecule” and probability of success in the clinic.  Much of the 'analysis' in [13a] consists of plots of median values without any indication of the spreads in the corresponding distributions and to see it cited in connection with "evidenced" rings alarm bells for me. As explained in KM2013 presenting data in this manner exaggerates trends and I consider it unwise to base decisions on data that have been presented in this manner. Quite aside from from the issue of hidden variation I do not consider the relationship between promiscuity and median cLogP reported (Figure 3a) in [13a] to be indicative of probability of success in the clinic, given that the criterion for 'activity' ( > 30% inhibition at 10 µM) is far too permissive to be physiologically relevant (this is a common issue in the promiscuity literature).]

While the optimal lipophilicity range has been suggested as a log D_7.4 between 1 and 3, [15] this is highly dependent on the chemical series. [The focus of the analysis was permeability and the range was actually defined in terms of AZlogD (calculated using proprietary in-house software) as opposed to log D measured at 7.4. The correlation between the logarithm of the A to B permeability and AZlogD is actually very weak (r² = 0.16) which would imply a high degree of uncertainty in threshold values used to specify the optimal lipophilicity range. While I remain sceptical about the feasibility of meaningfully defining optimal property ranges the assertion that the proposed range in AZlogD of 1 to 3 “is highly dependent on the chemical series” is pure speculation and is not based on data.] Best practice would be to generate data for a diverse set of compounds in a series, if measuring it for all analogues is not possible, and determine the lipophilicity range that leads to the most balanced properties and potency [3 | 16]. [It is not clear what the Authors mean by “most balanced properties and potency” nor is it clear how one is actually supposed to use lipophilicity measurements to objectively “determine the lipophilicity range that leads to the most balanced properties and potency”. My view is that to demonstrate "balanced properties and potency" would require measurements of properties such as aqueous solubility and permeability that are more predictive than lipophilicity of exposure in vivo. I do not consider either [3] or [16] to support the assertions being made by the Authors.]  Lipophilicity and pKa prediction models can then guide further designs and synthesis of analogues along the optimisation pathway (Figure 3 [17]). but measurements are advised, particularly by chromatographic methods, such as Chrom log D_7.4, in [18] contemporary practice. [In general, it is very difficult to convincingly demonstrate that one measure of lipophilicity is superior to another. Chromatographic measurement of log D is higher in throughput than the shake flask method used traditionally but it is unclear as to which solvent system the measurement corresponds.  Furthermore, the high surface area to volume area of the stationary phase means that an ionized species can interact to a significant extent with the non-polar stationary phase while keeping the ionized group in contact with the polar stationary phase and one should anticipate that the contribution of ionization to log D values might be lower in magnitude than for a shake flask measurement.]

As noted earlier in the post I consider it helpful to plot (as is done in Figure 3 which also serves as the graphical abstract) potency against lipophilicity with reference lines corresponding to different LLE (LipE) values (see R2009 which really should have been cited) to be a good way for H2L project teams to visualize potency measurements for their project compounds. That said, I consider view of the discovery process implied by Figure 3 to be neither accurate nor of any practical value for scientists working on H2L projects. It is relatively easy to define optimization of potency and measurements in an vitro assay are typically relevant to target engagement in vivo (uncertainty in the concentration of the drug in the target compartment, and of the species with which it competes, is likely to be the bigger issue when trying to understand why in vitro potency fails to translate to beneficial effects in vivo). One specific criticism that I will make of the Figure 3 is that it appears to imply that it doesn't matter whether you use log P or log D (when you use log D you can reduce lipophilicity to acceptable levels simply by increasing the extent to which compounds are ionized).    

However, there is quite a bit more to optimization of properties such as permeability, aqueous solubility, metabolic stability and pharmacological promiscuity that are believed to be predictive of ADME and toxicity, and my view is that defining optimization in terms of determining "the lipophilicity range that leads to the most balanced properties and potency" to be hopelessly naive. The principal objective in H2L work (and in lead optimization) is to identify compounds for which potency and properties related to ADME and toxicity are all acceptable. Defining meaningful acceptability criteria is non-trivial and H2L teams also typically need to make decisions as to how criteria can be relaxed with a minimum of risk. It's important to be aware that you can't compensate for inadequate potency by making the other properties better and those who argue that drug discovery scientists should focus on lipophilic efficiency rather than potency are missing this point.

While plotting potency against lipophilicity with reference lines corresponding to different LLE (LipE) values is often a helpful way to visualise project data in H2L (and in lead optimization) I don't consider Figure 3 to provide an accurate or useful view of the typical H2L process. Figure 3 presents a view that a hit maps to a lead which in turn maps to a drug candidate. In reality the screening phase of a discovery project will identify multiple hits and the resulting leads are not single compounds but structural series. It is important to be aware that the practical (as opposed to conceptual) utility of a graphic such as Figure 3 is limited by the extent to which the chosen measure of lipophilicity is predictive of properties such as aqueous solubility, permeability and metabolic stability.  

Although Q2025 claims to define H2L best practices the Authors don't appear to demonstrate much awareness of the nature of the H2L process. The first step in the H2L process is to follow up hits from the initial screen by assaying potential compounds of interest (summarised in Figure 2) although and in some cases some follow up might have already been done in the hit generation phase. Hits tend to group into structural families and the H2L chemists then synthesise compounds (in some organizations synthesis is outsourced) with a view to identifying compounds that are more potent that the hits. Decisions as to which compounds are to be made are typically hypothesis-based (see P2012) although in some cases genuinely predictive models might be available to the H2L team. Design hypotheses are typically based on information available to H2L teams, such as SARs derived from the hits or relevant target structures, and predictive models might be based on free energy calculations (see ASC2025). As the H2L teams generate more information design hypotheses become more specific and models based on project data become more predictive.

I would argue that establishing (and exploiting) SARs and structure-property relationships (SPRs) constitutes a basis for design in H2L work.  Certain features of SARs are especially relevant to H2L work and an observation that a reduction in log P leads to increased potency (or at least a minimal decrease in potency) is information that project teams can make good use of. Other SAR features that I would advise H2L scientists to look for are activity cliffs (relatively small changes in structure result in relatively large changes in potency) and superadditivity (effect on potency of simultaneously making two structural modifications is greater than what would be expected from the effects of making each structural modification individually).  

I see managing the 'assay budget' as a critical activity (especially when running assays is outsourced). For example, differences in lipophilicity between structurally related compounds are typically easy to predict and measuring large numbers of log D values is likely to be wasteful of resources. H2L teams need to use their assay budgets to identify and address issues efficiently and I don't consider the suggestion that H2L teams use a generic tiering approach such as the one shown in Figure 9 to be especially helpful. Something that I do suggest H2L teams consider is to try to assess responses of properties such as aqueous solubility and permeability to lipophilicity (this means making measurements for less potent compounds).                     

Figure 3. There are numerous routes to climb a mountain, as there are to discover a drug, but a measured approach to lipophilicity will guide an optimal path, [The Authors need to articulate what they mean by “a measured approach to lipophilicity” (which does come across as arm-waving) and provide evidence to support their claim that it “will guide an optimal path”.] where the outcome is usually driven by a balance of activity and lipophilicity [This appears to be a statement of belief and the Authors do need to provide evidence to support their claim. The Authors also need to say more about how the “balance of activity and lipophilicity” can be objectively assessed.] (The parallel lines represent LLE, i.e. pIC₅₀ - log P). [This way of visualizing data was introduced in the R2009 study which, in my view, should have been cited.]

Thus the Distribution Coefficient, (log D at a given pH) is a highly influential physical property governing ADMET profiles [20a | 20b | 20c] such as on- and off-target potency, solubility, permeability, metabolism and plasma protein binding (Figure 4) [14b]. [I recommend that the term ‘ADMET’ not be used in drug discovery because ADME (Absorption, Distribution, Metabolism, and Excretion) and T (Toxicity) are completely different issues that need to be addressed differently in design. I would argue that the ADME profile of a drug is actually defined by its in vivo characteristics such as fraction absorbed (which may vary with dose and formulation), volume of distribution and clearance (the Authors appear to be confusing ADME with in vitro predictors of ADME) and I would also argue that toxicity is an in vivo phenomenon. In order to support the claim that log D “is a highly influential physical property governing ADMET profiles” it would be necessary to show that log D is usefully predictive of what happens to drugs in vivo. My view is that the cited literature does not support the claim that log D “is a highly influential physical property governing ADMET profiles” given that  [20a] does not even mention log D and neither [20b] nor [20c] provides any evidence that log D is usefully predictive of in vivo behaviour of drugs.]

Figure 4. The impact of increasing lipophilicity on various developability outcomes [14b] [It is unclear as to whether lipophilicity is defined for this graphic in terms of log P or log D. It would be necessary to show more than just the ‘sense’ of trends for the term “impact” to be appropriate in this context. I do not consider the use of the term “developability outcomes” to be either accurate or helpful.]

Aqueous solubility is certainly an important consideration in H2L work although I think that the Authors could have articulated the relevant physical chemistry rather more clearly than they have done. You can think of the process of dissolution as occurring in two steps (sublimation of the solid followed by transfer from the gas phase to water). Lipophilicity usually features in models for prediction of aqueous solubility although I consider wet octanol to be a thoroughly unconvincing model for the gas phase. We generally assume that aqueous solubility is limited by the solubility of the neutral form (which is why ionization tends to be beneficial) but when this assumption breaks down the solubility that you measure will depend on both the nature and concentration of the counter-ion. As I note in HBD3 optimization of intrinsic aqueous solubility (the solubility of the neutral form of the compound) is still a valid objective for ionizable compounds because we're typically assuming that only neutral species can cross the cell membrane by passive permeation.

Some general advice that I would offer to drug discovery scientists encountering solubility issues is that they should try to think about molecular structures from the perspectives of molecular interactions in the solid state and crystal packing. I would expect the left hand 'Reduce crystal packing' structure in Figure 6 to be able to easily adopt a conformation in which the planes corresponding to the aromatic rings and amide are all mutually coplanar (this is a scenario in which a non-aromatic replacement for an aromatic ring might be expected to have a relatively large impact). In HBD3 I suggest that deleterious effects of aromatic rings on aqueous solubility might be due to molecular interactions of the aromatic rings rather than their planarity. I also suggest in HBD3 that elimination of non-essential hydrogen bond donors be considered as a tactic for improving aqueous solubility because it tends to increase the imbalance between hydrogen bond donors and acceptors while minimizing the resulting increase lipophilicity.      

Rational [this use of "rational" is tautological] reasons for poor solubility were succinctly described by Bergstrom, who coined "Brick Dust and Greaseballs" as two limiting phenomena in drug discovery [22] which are in line with the empirical findings that led to General Solubility Equation [23] (Figure 5). [I don’t consider the General Solubility Equation to have any relevance to H2L work because it has not been shown to be usefully predictive of aqueous solubility for compounds of interest to medicinal chemists and the inclusion of Figure 5, which merely shows how predicted solubility values map on to an arbitrary categorisation scheme, appears to be gratuitous.] Succinctly, three factors influence solubility: lipophilicity, solid state interactions and ionisation. [It is solvation energy as opposed to lipophilicity that influences solubility and wet octanol is a poor model for the gas phase.] Determining which are the strongest drivers of low solubility will guide the optimisation (Figure 6). Using the analysis in Figure 5 the Solubility Forecast Index emerged, using the principle that an aromatic ring is detrimental to solubility, roughly equivalent to an extra log unit of lipophilicity for each aromatic ring (Thus SFI = clog D_7.4 + #Ar) [24]. [I consider the use of the term “principle” in this context to to be inaccurate given that that the basis for SFI is subjective interpretation of a graphic generated from proprietary aqueous solubility data and I direct readers to the criticism of SFI in KM2023.] Minimising aromatic ring count is an important and statistically significant metric to consider [25] [The importance of minimizing aromatic ring count is debatable and it is meaningless to describe metrics as “statistically significant”.] - consistent with the "escape from flatland" concept [26] that focusses on increasing the sp³ (versus sp²) ratio in molecules, [The focus in the “escape from flatland” study is actually on the fraction of carbon atoms that are sp3 (Fsp3) and not on “the sp³ (versus sp²) ratio”.] even though no significant trends are apparent in detailed analyses of sp³ fractions [27]. [The “analyses of sp³ fractions” in [27] consist of comparisons of drug - target medians for the periods 1939-1989, 1990-2009 and 2010-2020 and all appear to be statistically significant (although I don't consider these analyses to have any relevance to H2L work). I consider the citation of [27] in this context to be gratuitous and this blog post might be of interest.]

An important factor in hit selection is to prioritise compounds with higher ligand efficiency. Ligand efficiency, defined as activity [LE is actually defined in terms of Gibbs free energy of binding and not activity.] per heavy atom (LE=1.37 * pKi/Heavy Atom Count, Figure 7a), is commonly considered in discovery programmes as a quality metric [33]. [LE (Equation 3 in the H2L best practices post graphic) is actually defined as the Gibbs free energy of binding, ΔG° (Equation 2 in H2L best practices post graphic), divided by the number of non-hydrogen atoms, N_nH (this is identical to heavy atom count although I consider the term to be less confusing), but the quantity is physically (and thermodynamically) meaningless because perception of efficiency varies with the arbitrary concentration, C°, that defines the standard state (see Table 1 in NoLE). Using a standard concentration enables us to calculate changes in free energy that result from changes in composition and, while the convention of  using C° = 1 M when reporting ΔG° values. is certainly useful, it would be no less (or more) correct to report ΔG° values for  C° = 1 µM. Put another way the widely held belief that 1 M is a 'privileged' standard concentration is thermodynamic nonsense (Equation 2 in the H2L best practices post graphic shows you how to interconvert ΔG° values between different standard concentrations). Given the serious deficiencies of LE as a drug design metric, I suggest modelling the response of affinity to molecular size and using the residuals to quantify the extent that individual potency measurements beat (or are beaten by) the trend in the data (the approach is outlined in the 'Alternatives to ligand efficiency for normalization of affinity' section of NoLE). There are two errors in the expression that the Authors have used for LE (the molar energy units are missing and the expression is written in terms of K_i rather than K_D). The factor of 1.37 in the expression for LE  comes from the conversion of affinity (or potency) to ΔG° at a temperature of 300 K, as recommended in [35], although biochemical assays are typically are typically run at human body temperature (310 K). My view is that it is pointless to include the factor of 1.37 given that this entails dropping the molar energy units and using a temperature other than that at which the assay was run. Dropping the factor of 1.37 would also bring LE into line with LLE (LipE).] Various analyses suggest that, on average, this value barely change over the course of an optimisation process [20b | 27 | 34a | 34b] - so it is important to consider maintenance of any figure during any early SAR studies. [I disagree with this recommendation. These analyses are completely meaningless because the variation of LE over the course of an optimization itself varies with the concentration unit in which affinity (or potency) is expressed (Table 1 of NoLE illustrates this for three ligands of that differ in molecular size and potency). In [34a] the start and finish values values of LE were averaged over the different optimizations without showing variance and it is therefore not accurate to state that the study supports the assertion that LE values "barely change over the course of an optimisation process".] Lipophilic Ligand Efficiency (activity minus lipophilicity typically pKi -log P, Figure 7b), which is widely recognised as the key principle in successful drug optimisation, comes into play both for hit prioritization and optimisation. [LLE is a simple mathematical expression and I don’t consider it accurate to describe it as a “principle” let alone “the key principle in successful drug optimisation”. LLE can be thought of as quantifying the energetic cost of transferring a ligand from octanol to its target binding site although this interpretation is only valid when the ligand is predominantly neutral at physiological pH and binds in its neutral form. LLE is just one of a number of ways to normalize potency with respect to lipophilicity and I don't think that anybody has actually demonstrated that (pIC₅₀ – log P) is any better (or worse) as a drug design principle than pIC₅₀ – 0.9 × log P. When drug discovery scientists report that they have used LLE it often means that they have plotted their project data in a similar manner to Figure 3 as opposed to staring at a table of LLE values for their compounds. As an alternative to LLE (LipE) for normalization of affinity (or potency) with respect to lipophilicity I suggest modelling the response and using the residuals to quantify the extent that individual potency measurements beat (or are beaten by) the trend in the data (the approach is outlined in the 'Alternatives to ligand efficiency for normalization of affinity' section of NoLE).] Improving this value reflects producing potent compounds without adding excessive lipophilicity. Taken together, it has been shown that for any given target, the drugs mostly lie towards the leading "nose" [?] where LE and LLE are both towards higher values [20b | 35]. [This perhaps not the penetrating an insight that the Authors consider it to be, given that drugs are usually more potent than the leads and hits from which they have been derived.] However, setting aspirational targets for either metric is unwise, as analysis of outcomes indicates that the values are target dependant [20b]. [I consider target dependency to be a complete red herring in this context and a more important issue is that you can’t compensate for inadequate potency by reducing molecular size or lipophilicity.]  Focusing on increasing LLE to the maximum range possible and prioritizing series with higher average values is the recommended strategy [27 | 36]. [It is not clear what is meant by “increasing LLE to the maximum range possible” and I consider it very poor advice indeed to recommend “prioritizing series with higher average values” (my view is that you actually need to be comparing the compounds from different series that have a realistic chance of matching the desired lead profile. The Authors of Q2025 appear to be misrepresenting [36] given that the study does not actually recommend “prioritizing series with higher average values”. This blog post on [27] might be relevant.]

One can summarize this section with a simple but critical best practice: potency and properties (physicochemical and ADMET) have to be optimized in parallel (Figure 8) [37] to get to quality leads and later drug candidates with higher chances of clinical success. Whilst seemingly trivial, this proposition is rendered challenging by an "addiction to potency" and a constant reminder of this critical concept remains useful for medicinal chemists [38]. [My view is that many medicinal chemists had already moved on from the addiction to potency when the molecular obesity article was published a decade and a half ago and I would question the article's relevance to contemporary H2L practice. The threshold values that define the GSK 4/400 rule actually come from an arbitrary scheme used to categorize the proprietary data analyzed in the G2008 study as opposed to being derived from objective analysis of the data. The study reproduces the promiscuity analysis from [13a] which I criticised earlier in this post for exaggerating the strength of the trend and using an excessively permissive threshold for ‘activity’.] With poor properties, even "good ligands" may not fully answer pharmacological questions [39a | 39b]. [These two articles focus on chemical probes and I don’t consider either article to have any relevance to H2L work.  Chemical probes need to be highly selective (more so than drugs) and permeable although solubility requirements are likely to be less stringent when using chemical probes to study intracellular phenomena than in H2L work and you don't generally need to worry about achieving oral bioavailability.] 

I agree that mapping SARs for structural series of interest is an important aspect of H2L work and activity cliffs (small modifications in structure resulting in large changes in activity) are of particular interest given the potential for beating trends and achieving greater selectivity. Instances of decreased lipophilicity resulting in increased potency (or at least minimal loss of potency) should also be of significant interest to H2L teams. When mapping SARs it is important that structural transformations should change a single pharmacophore feature at a time and one should always consider potential ‘collateral effects’, such as perturbed conformational preferences, that might confound the analysis. Some of the structural transformations shown in Figure 10 change more than one pharmacophore feature at a time which makes it impossible to determine which pharmacophore feature is required for activity.    

Figure 10. Conceptual example of iterative SAR [The meaning of the term “iterative SAR” is unclear] to determine the pharmacophore. As each change may affect binding interactions, conformation and ionization state; complementary structural modification [The meaning of "complementary structural modification" is unclear] will be needed to understand the change in potency and determine the pharmacophore 

Is Nitrogen needed (e.g. HBA)? [In addition to eliminating the quinoline N hydrogen bond acceptor this structural transformation eliminates a potential pharmacophore feature (the amide carbonyl oxygen can function as a hydrogen bond acceptor) while creating a cationic centre which will incur a significant desolvation penalty.]

Is NH needed? [This structural transformation eliminates the amide NH but it also is unlikely to address the question of whether the NH is needed because the amide carbonyl has also been eliminated.]

Is carbonyl needed? [The elimination of the amide carbonyl oxygen (hydrogen bond acceptor) creates a cationic centre which will incur a desolvation penalty.] 

As a last proposition, [49a | 49b] we suggest that the progress in computational physicochemical and ADMET property predictions represents an opportunity to accelerate the optimisation of molecules with a "predict-first" mindset [4 | 50]. [I certainly agree that models should be used if they are available. However, the citation of literature does appear to be gratuitous and it is unclear why the Authors believe that scientists working on H2L projects will benefit from knowing that a proprietary system for automated molecular design has been developed at GSK.]  The first step is to generate sufficient data for a series to build confidence in [51] any models, which can then be exploited in the prioritization of compounds for synthesis that fit with aspirational profiles [My view is that it would be very unwise for H2L project teams to blindly use models without assessing how well the models predict project data although I consider the  citation of [51] to be gratuitous been cited. Typically, H2L project teams use measured data to move their projects forward and generating data purely for the purpose of model evaluation is likely to be a distraction. One piece of advice that I will offer to H2L project teams is that they attempt to characterise responses of ADME predictors, such as aqueous solubility and permeability, to lipophilicity (likely to involve measurements for less potent compounds).] This ensures higher physicochemical quality [I consider “ensures” to be an exaggeration and I would argue that “physicochemical quality” is not something that can even be defined meaningfully or objectively (let alone quantified).], asks more pertinent questions and might reduce the total number of molecules made to get to the lead (Figure 11).

The Authors offer advice on how to ensure that optimisation is progressing in a satisfactory manner and how to know when to stop working on the series.

A Lead is not the perfect drug, but it gives reason to believe that the chemical series might be able to deliver one. An essential part of H2L (and later lead optimisation) is to ensure that the optimisation is progressing so that further investment is justified. Some essential questions can help achieve this: Does your series show dynamic SAR [The Authors need to say exactly what they mean by “dynamic SAR” if this is indeed the essential question that they assert it to be.] and achievable desired potencу? Is the preliminary ADMET data encouraging? [The Authors need to define “encouraging” if this is indeed an essential question.]  Do you have evidence of in vivo effect (PK/PD) at appropriate exposures? [I would question the necessity of PK/PD studies before starting lead optimisation and there are potential ethical concerns about doing in vivo work using compounds that lack the potency required for meaningful PK/PD assessment.] Do the remaining challenges show dynamic SAR and confidence they can be optimized? [The term “remaining challenges” is vague and it is not clear how H2L scientists are supposed to assess “dynamic SAR” for remaining challenges that are not defined in terms of activity.] To answer this, it's critical to monitor the trajectory [As I pointed out previously in the post it is not generally feasible to objectively map optimization paths and I consider the use of “trajectory” to be inappropriate in this context, given that it usually applies to a well-defined path that is determined at launch (for example, a molecular dynamics trajectory).] of the optimisation: e.g. by monitoring relevant properties over time. [Typically, H2L teams assess how closely the best compounds match the lead target profile (LTP) as opposed to monitoring time dependencies of properties such as log D that have limited predictivity.] In the absence of progress, discontinuing further work on a scaffold or series may be justified, with reason to focus on other promising structures or recommend termination on a data-driven basis. [Generally, the decision to terminate projects and series will be made on the basis of failure to satisfy the LTP.] 

It's been a long post and I'll say a big thank you for staying with me until the end. I wrote this post primarily for early-career scientists as well as for drug discovery scientists in academia and students (although I hope the feedback will also be helpful for the EFMC).  One piece of advice that I will offer to all scientists regardless of the stage of their careers is to not switch off your critical thinking skills just because a study is presented as defining best practices or has been highly-cited. In particular, I urge all scientists to be extremely wary of studies in which the conclusions don't follow from the data and I'll share a recent blog post that illustrates the problem. All that said, however, confused thinking amongst drug discovery scientists is not high on the list of the problems facing many of the world's inhabitants right now and my wish for 2026 is for a kinder, gentler, fairer and more peaceful world.  

Covalent ligand efficiency

It appears that whoever first described Economics as the ‘Dismal Science’ had never encountered a ligand efficiency metric. I’ll be taking a look at the FK2025 study (Covalent ligand efficiency) in this post and the study has already been reviewed by Dan. Something that I’ve observed repeatedly over the years is that authors of ligand efficiency studies exhibit a lack of understanding of units and dimensions associated with physicochemical quantities that would shame a first year undergraduate studying introductory physical chemistry (this is somewhat ironic given that creators of ligand efficiency metrics frequently tout their creations in physicochemical terms). I consider covalent ligand efficiency (CLE) as defined in the FK2025 study to have no value whatsoever for design of drugs that bind irreversibly to their targets through covalent bond formation given that the metric is time-dependent and based on an invalid measure of bioactivity. The formidable Lady Bracknell is clearly unimpressed and I should mention that the photo is from the wikipedia page for English actress Rose Leclercq (1843-1899). Given the serious deficiencies in the FK2025 study this is going to be a long and tedious post (even more so than usual 😁😁😁) so please ensure that you have strong coffee close to hand. As is usually the case in posts here I've used the same reference numbers as were used in FK2025 and quoted text is indented with my comments in red italics. I've organized some of the mathematical material into three tables and references to tables in the post are to these (and not to any of the tables in the FK2025 study).    

Before starting the review of FK2025 it’s worth examining irreversible covalent inhibition from a molecular design perspective and I’ll direct readers to the informative S2016 and McW2021 reviews, and the recent L2025 study which presents COOKIE-Pro for covalent inhibitor binding kinetics profiling on the proteome scale. Covalent bond formation between RNA and ligands can also be exploited (S2025 | K2025 | L2015)  and I generally use 'target' rather than 'protein' in blog posts and journal articles. An irreversible covalent inhibitor acts by first binding non-covalently to its target in the first step with the covalent bond forming in the second step between an electrophilic ligand atom (the term warhead is commonly used) and a nucleophilic target atom such as the sulfur atom of a cysteine. A commonly used measure of activity for irreversible covalent inhibitors is the k_inact/K_I ratio which can be thought of as the product of affinity (1/K_I) and reactivity (k_inact). In design of irreversible covalent inhibitors we try to place the electrophilic atom of the warhead within reacting distance of the nucleophilic atom of the target (this is relatively easy if you have a reliable structure of a complex of the target with a relevant ligand that lacks the electrophilic warhead). The non-covalent complex between target and ligand is stabilised by the non-covalent contacts between the target and ligand (the term ‘molecular interactions’ is also used although I prefer to think in terms of ‘non-covalent contacts’ since the latter can be observed experimentally). However, non-covalent contacts also determine reactivity of the non-covalently bound complex by stabilising the transition state (I consider it more correct to think in terms of reactivity of the complex than in terms of reactivity of either the electrophilic warhead or the target nucleophile). In the design context, this means attempting to tune non-covalent contacts to stabilise the transition state to a greater extent than the non-covalent complex.

The LE and CLE metrics share a very serious deficiency in that your perception of efficiency can be altered if you change the value of an arbitrary term in the formula for the metric and I'll start the review of FK2025 by critically examining LE. The meaningless of LE stems from a fundamental misunderstanding of how logarithms work and I'll by point you toward M2011 (Can one take the logarithm or the sine of a dimensioned quantity or a unit? Dimensional analysis involving transcendental functions) that was published in the Journal of Chemical Education. In drug discovery we frequently need to calculate logarithms for quantities and you need to be aware you can’t calculate the logarithm for a dimensioned quantity. Let’s take pIC₅₀ as an example and this quantity is commonly defined as the negative logarithm of the IC₅₀ in mole per litre (M). However, what you actually do when you calculate pIC₅₀ is that you take the negative logarithm of the numerical value of the IC₅₀ when expressed in mole per litre (this is a bit of a mouthful and it can be written more compactly as equation 1 below). While not denying that it is useful to have a convention such as this for expressing potency values logarithmically it should be remembered that the choice of mol per litre (M) is entirely arbitrary and it would be equally correct to use other valid concentration units such as μM or nM. One consequence of choosing mole per litre (M) for expressing IC₅₀ values is that pIC₅₀ values (or at least measured pIC₅₀ values) will generally be positive because of the extreme difficulty of measuring meaningful IC₅₀ values that are greater than 1 M. 

Let’s take a look at the binding free energy ΔG° and you’ll notice that I’ve written it with a degree symbol which indicates that this quantity corresponds to a standard state defined by a concentration value C° (the standard concentration). Equation 2 shows how the binding free energy is defined as the difference in chemical potential between the associating species (target + ligand) and the target-ligand complex with each species at the standard concentration (the degree symbol indicates that that both the binding free energy and chemical potential depend on the value of C° and I’ve also shown this explicitly in the equation although this is not actually necessary). Equation 3 shows the dependence of chemical potential on the concentration C of the species and the standard concentration C°. Taken together, Equation 2 and Equation 3 should clarify the origins of the dependence of binding free energy on the standard concentration comes from (there are two associating species but only one complex). We can’t actually measure binding free energy directly but we can calculate it from the dissociation constant K_D using Equation 4 (which can be derived from Equation 2 and Equation 3). It’s important to be aware that if you use Equation 4 to convert ΔG° values between different values of the standard concentration C° you’ll be making the assumption that solutions are dilute (ΔH is independent of concentration) and this is indicated in Equation 5.

The standard concentration is a source of much confusion in the ligand efficiency field and I’ll direct readers to ‘The Nature of Ligand Efficiency’ (p9). While the standard concentration is integral to a valid thermodynamic treatment of target-ligand binding the value of C° is entirely arbitrary (to suggest otherwise would mean that you’ve abandoned thermodynamics). It is conventional in drug discovery (and biochemical) literature to use a C° value of 1 M when reporting ΔG° values. While this convention is certainly beneficial, it is no more (and no less) valid to use a value of 1M than it is to use a value of 1 μM for this purpose. Furthermore a standard state defined by a C° value of 1 M is not biophysically realistic (consider the difficulty of accommodating a mole of target in a volume of 1 litre and the likelihood of a ligand exhibiting aqueous solubility of 1 M). I assume that most biochemists and biophysicists would agree that it is generally not feasible to measure K_D values of greater of 1 M (I would be happy to be proven wrong on this point) and this means that drug discovery scientists tend to assume that ΔG° values are necessarily negative.

Let’s now a take a look at ligand efficiency (LE) and you can see from the photo above that some heretics regard the metric as physically nonsensical (if you're interested in how I came to be chatting with fellow blogger Ash then take a look at this post). The LE metric which is regarded as an article of  faith in the fragment-based design community was introduced in the (p5) study with the symbol Δg (see Equation 6 below) and the authors of that study did not actually state that it had to be calculated using a C° value of 1 M (I consider it unlikely that any of the authors were even aware of the dependence of ΔG° on C°). In The Nature of Ligand Efficiency (p9) I defined the quantity η_bind (see Equation 7) by dividing Δg (LE) by RT (when LE values are quoted the molar energy units are usually discarded and T often does not correspond to the temperature at which the assay was run) and by the factor (2.303) used to convert between natural logarithms and base 10 logarithms. The quantity η_bind is directly proportional to Δg (LE) and using it makes it much easier to see how using a different standard concentration can alter your perception of efficiency.  Take a look at Table 1 in (p9) and you’ll see that the three compounds (a fragment, a lead and a clinical candidate) bind with equal efficiency when C° is 1 M. Change C° to 0.1 M and the clinical candidate is binds more efficiently than the fragment but when C° to 10 M the fragment becomes more ligand-efficient than the clinical candidate. As noted in (p9) “In thermodynamic analysis, a change in perception resulting from a change in a standard state definition would generally be regarded as a serious error rather than a penetrating insight.” 

Here's what the authors of FK2025 say about LE: 

LE depends on the choice of the standard concentration (normally 1 M) (p8) (p9) and its maximal available value is size dependent.(p10) (p11) [It's true that LE depends on C° but it’s also true that ΔG° depends on C° and the difference in the two dependencies is that is that LE “depends upon the choice of standard concentration in a nontrivial fashion” (p8). The issue is not the so much that LE depends on C° but that using a different unit to express K_D changes how we perceive efficiency. The ΔΔG values that determine perception of affinity don’t change when you use a different value of C° (equivalent to using a different unit to express K_D). However, if you use a different value of C° for calculating LE you can see from Table 1 in (p9) that even the ordering of LE values between two ligands can change. I consider the molecular size dependencies of LE observed by the authors of (p10) and (p11) to be artefactual and I’ll point you toward Fig. 1 in (p9) which shows that using a different value of C° can change how we perceive the molecular size dependency of LE.] Nevertheless, LE is an established tool to normalize potency and facilitate the comparison of ligands with a range of potencies and sizes. [It is not uncommon for adherents of religions to consider their beliefs to be established facts.] The usefulness of LE and other efficiency metrics in drug discovery has been extensively analyzed and reviewed elsewhere. (p6) (p12) (p13) (p14) (p15) (p16) (p17) [My view is that nobody has actually demonstrated the usefulness of LE and I’m unconvinced that it would even be possible to do so meaningfully in an objective manner (consider the feasibility of comparing success rates between a group of individuals using LE in discovery projects and a control group of individuals not using LE in discovery projects). Usefulness means that using something provides demonstrable benefits and ‘widely-used’ is not equivalent to ‘useful’ (I’m guessing that more people use homeopathic ‘medicines’ than use ligand efficiency metrics). One piece of advice that I’ll offer to anybody advocating the use of LE in drug design is to ensure that you fully understand the implications of changes in perception resulting from using different units to express quantities not least because you might find yourself lecturing to people who do understand.]

After a lengthy preamble it’s now time to take a look at how the FK2025 study addresses ligand efficiency in the context of irreversible covalent inhibition. One of the challenges in design of drugs that engage their targets irreversibly is that it’s not possible to meaningfully quantify activity with a single parameter. This is particularly relevant to definition of efficiency metrics which are typically derived by either scaling or offsetting a measured activity value by a risk factor such as molecular size or lipophilicity. While you can certainly measure an IC₅₀ value for an irreversible covalent inhibitor the value that you measure will be time-dependent and it’s not generally meaningful to compare two IC₅₀ values that have been measured using different incubation times. While the k_inact/K_I ratio is time-independent using it as a measure of activity necessarily entails a degree of information loss.

The authors of FK2025 state:

Our starting point is the LE introduced for noncovalent ligands as a useful metric for lead selection. (p5) [LE  was claimed to be useful when it was introduced although no evidence was presented in support of the claim.]

Let’s take a look at Table 2 which shows two equations from FK2025. The first equation, which appears in the text of the article, illustrates two common errors in the efficiency metric field (taking logarithms of dimensioned quantities and discarding units). It should ring alarm bells for the reader when authors make either error (especially if the authors interpret values of the efficiency metrics).

The authors of FK2025 assert that “LE can be decomposed into contributions from the noncovalent recognition and the covalent reaction (Box 2, Equation III)” and this is reproduced in Table 2 as Equation 2. The first term is a commonly-used mathematical formula for LE when inhibition is reversible and it is important to be aware that K_I has been divided by an arbitrary concentration value (1 M) in order that it can be expressed as a logarithm (see Equation 1 in Table 1). The argument of the logarithm in the second term is dimensionless although its magnitude does vary with t. Each term in Equation III (Box 2) has a nontrivial dependence on the value of an arbitrary quantity (the 1 M concentration in the first term and t, in the second term). This means that your perception of efficiency when calculated according to Equation III (Box 2) will be altered if you use either a different concentration unit or a different value of t. You can see this effect in Figure 2 (effect of varying of t) and the appearance of Figure 1 will be altered if you use a value of t other than 1 h or a concentration unit other than M for the calculation of LE.

It's now time to examine CLE (defined as Equation II in Box 3 of the FK2025 study) and I’ll direct you to Table 3 below in which I’ve made some comments. Using CLE requires that the IC₅₀ values for the inhibitors of interest all correspond to the same time point (t) and it is not clear whether the authors are suggesting that that the IC₅₀ values should all be measured using the same incubation time or need to be calculated from measured K_I and k_inact values using Equation III in Box 2. A quantity t is also explicitly present in the argument of the logarithm in Equation II in Box 3 and this is necessary for the argument of the logarithm to be dimensionless (see M2011). The argument of the logarithm in Equation II (Box 3) is clearly time-dependent and this means that your perception of efficiency will be altered if you use a different value of t when calculating CLE (just as your perception of efficiency will be altered if you use a different concentration unit to express IC₅₀ when you calculate LE for reversible inhibitors). It also means the molecular size dependency of CLE will vary with time just as the molecular size dependency of LE varies with the concentration unit used to express affinity as can be seen in Fig. 1 of (p9).

However, there is another difficulty which is that the argument of the logarithm in Equation II (Box 3) is not a valid measure of activity (the same criticism can also be made of the xLE metric introduced in the Z2025 study that Dan has already reviewed).  This problem is a bit more subtle and it’s important to remember that knowing the IC₅₀ value for a reversible inhibitor enables you to generate a concentration response for inhibition.  When you express an IC₅₀ value as a logarithm you need to scale it by a concentration value to ensure that the argument of the logarithm function is dimensionless (see M2011) but it’s important to remember that the concentration unit is still there even though it’s not shown (see Equation 1 in Table 1).

This is a good point at which to wrap up and I’ve argued that CLE has two deficiencies. First, perception of efficiency and its dependency on molecular size both vary with an arbitrary quantity (t) in the argument of the logarithm (this is analogous to the problems caused by the arbitrary nature of the concentration unit used for scaling affinity/potency in the definition of LE for reversible binders). Second, the argument of the logarithm is not a valid measure of activity because it cannot be used to generate a concentration response. Furthermore, I would question the value of aggregating results from multiple assays for analysis even for a valid metric without these deficiencies and I offered the following advice in (p9):   

Drug designers should not automatically assume that conclusions drawn from analysis of large, structurally-diverse data sets are necessarily relevant to the specific drug design projects on which they are working.

I’ve criticized the FK2025 study at length and saying how I might use data like this in drug design projects is a good way to conclude the post.  A general criticism that I have made of drug design efficiency metrics is that they are based on assumptions of relationships between activity and risk factors such as molecular size.  I argued in (p9) that one should use the trend that is actually observed in the data to normalize activity with respect to risk factors and I’ll point you to the relevant section (Alternatives to ligand efficiency for normalization of affinity) in that article. I would start by attempting to model the relationship between k_inact and reactivity with glutathione. The objective of this exercise is to identify inhibitors that best exploit their intrinsic reactivity when forming covalent bonds with the target residue (you can quantify this by how far the point for an inhibitor lies above the trend line and the most interesting compounds have the largest positive residuals). I might  also examine the relationship between k_inact and K_I for inhibitors with the same intrinsic reactivity (e.g., incorporating the same warhead) with a view to identifying the inhibitors for which non-covalent interactions with the target most effectively stabilise the transition state relative to the non-covalent complex. I should stress that there is no suggestion that these analyses would necessarily yield useful insight.

It's been a long post so thanks for staying with me. This will be the the last post until after Christmas and, as I extend best wishes to all for a happy and peaceful festive season, I'm keenly aware that Christmas will be neither happy nor peaceful for many of our fellow human beings.