A new class of drugs and treatment paradigm in chronic disease: botanical extracts
Clinical drug development is a rigorous process to determine the safety and efficacy of a drug candidate.One of the challenging steps in the process is determining the toxicity of drug candidates. Each candidate’s toxicity profile has to be determined before embarking on any combination therapy.This increases the cost of developing combination therapies from novel drug candidates.Therefore, if one were to modulate multiple targets or pathways, only drugs that have gone through rigorous pre-clinical and clinical testing should be considered. In other words, each novel drug candidate has to undergo its own thorough toxicology testing.
For centuries, botanical extracts have been a source of treatment as demonstrated in Ayurveda (traditional Indian medicine) and Traditional Chinese Medicine (TCM).These traditional drugs are often extracts, derived from an entire plant, andare composed of a multitude of bioactive components.The fact that Ayurveda and TCM exist and remain popular attests to some efficacy albeit largely anecdotal.However, these therapeutic modalities lost favour with the pharmaceutical industry in decades pastdue tobatch-to-batch inconsistencies in manufacturingand the lack of well-controlled clinical trials.The regulatory hurdles isolated these traditional medicines which had little beyond empirical evidence.
More recently, these traditional drugs are being tested in the same well-designed and controlled clinical studiesapplied to single entity drugs [5].The US Food and Drug Administration (FDA) established a clear regulatory pathway for botanicaldrugs[6].To date, only 2 drugs have been approved via this botanical path[5].Veregen® (sinecatechins), an extract derived from green tea ( Camelia sinensis Kuntze) for treating genital and perianal warts topically was the first botanical drug approved by the US FDA in 2006.In 2012, the FDA approved the second botanical drug and first oral botanical drug, Fulyzaq® (crofelemer) now called Mytesi®, an anti-diarrheal drug for HIV patients derived from the latex of the South American croton tree ( Croton lechlerii Müll. Arg).
The US FDA’s botanical path considers theextract to be drug, and not the isolated chemical entities.The rationale behind this regulatory approach is that the observed efficacy has been associated with the use of the entire plant or its extracts.Failure to replicate therapeutic results can be attributed to the inability to isolate a distinct chemical entity that can reproduce the desired effects.The observed efficacyis thus associated with the action of multiple components including any synergistic effects that are lost during the fractionation of the extract.Botanical drug discovery will therefore involve methods that allow the isolation and characterisation of synergistic bioactive components and will play a significant role in sustaining efficacy in the development of this class of drugs [7].
A promising class of bioactive compounds in extracts are polyphenols;the two aforementioned FDA-approved botanical extracts involve polyphenols.Polyphenols and flavanols have multiple modes of action. They have shown efficacy towards managing metabolic disease, which can be attributed to these simultaneous activities [8].These molecules are also known to regulate the microbiome [9].Interestingly, polyphenols that are by-products of a filtered molasses concentrate has been shown to modulate postprandial glucose and insulin response.Furthermore, from a clinical nutrition standpoint, these polyphenols can lower the glycemic index of carbohydrate-rich foods [10,11].
Several species of algae and microalgae (cyanobacteria) are a rich source of bioactive components that have shown potential for treating diabetes and metabolic syndrome [12].Spirulina extracts have also shown novel, anti-microbial activity as well as anti-inflammatory properties that can treat mild to severe fungal infections such as onychomycosis [13], viral infections [14]and some effects on the microbiome [15].
Given the complex nature of a botanical extract, it is conceivable that it can simultaneously modulate multiple pathways of the host as well as the microbiome. This is a plausible reason for its observed efficacy.As an extract, it is most likely composed of multiple bioactive components involved in multiple mechanisms of action.However, complexity can potentially be a curse since the extract may have components with underlying toxic effects. In any case, the appropriate fractionation and separation techniques combined with analytical testing should provide a good handle in ensuring consistency in batch-to-batch preparations.
Unlike single compounds that need to be tested individually, an advantage of the botanical regulatory path is that the extract can be tested as a single entity for toxicity and safety.It is not necessary to purify each component but there is a requirement that some components are identified and that there is a validated analytical assay that can be used to measure and ensure product consistency.Another advantage especially if the botanical is from a food source or considered as GRAS (generally recognized as safe), is its safety profile which expedites the conduct of clinical studies and can significantly reduce drug development costs.
For a botanical drug, the botanical source should be amenable to large-scale production and the extraction process needs to be scalable for drug development. Thus, one of the challenges is to ensure consistency in product batches which can be influenced by consistency in the growth environment of the botanical source.For example, microalgae can be cultured in bioreactors [16].Advances in agricultural and aquaculture mass production techniques in controlled environments will help ensure product consistency, e.g. indoor agriculture/vertical farming [17]. Once the botanical material is produced, advanced analytical techniques in mass spectrometry and separation technologies provide the quality control needed for the botanical source and its extracts.
The new paradigm of targeting multiple pathways in chronic disease with botanical extracts represents a novel approach in treating or managing chronic diseases.
One possible commercialisation strategy, which allows early market entry, is to initially develop a nutritional product from a botanical source that is known to be safe or labelled GRAS with limited claims on the disease of interest.In addition to achieving market acceptance and early revenues, this approach allows the product to develop a safety profile and for the company developing it to accumulate efficacy data albeit anecdotal from customer feedback.At the same time, standard drug development via an IND (investigational new drug) can commence based on the US FDA botanical regulatory path, which requires an established manufacturing process and the conduct of well-controlled clinical trials to demonstrate efficacy and safety.This parallel development and marketing process allows cross-fertilisation of product information towards the development of a more efficacious and safe botanical drug.This approach provides a risk-mitigating and cost-effective strategy for future botanical drug development, which should translate to efficacious therapeutic options that lower healthcare costs especially for chronic diseases for any demographic and not only the aging population.
The success in conquering human disease has led to longer lives but has come with a price – the emergence of chronic indications associated with aging and longer lifespans. Thus, although there has been significant success in developing novel drugs with the single target paradigm, drug development in chronic diseases has increasingly been challenging.It is becoming clear that chronic diseases involve multiple, dysfunctional pathways thatmay need simultaneous modulation [1,2].Most of the targets being modulated by current drugs or drugs in development are downstream of the disease pathway and correlate more with symptoms rather than the cause of the disease.Targets such as TNF (tumour necrosis factor)-alpha in inflammation and hyperglycaemia in diabetes are examples of this.Currenttrendsin combination therapy and precision medicinein oncologywith different immunotherapies and chemotherapies represent strategies in simultaneously targeting multiple pathways to manage disease.
Recent discoveries on the role of the microbiomehave also led to a better understanding of its interaction with the host and its contribution to chronic diseases.Although it is possible that there are a limited number of control points which would have more broad and effective effects to manage disease, these are currently unknown.A key element in most chronic diseases is inflammation.Notwithstanding, therapeutic targets in inflammation remain vague and elusive due to multiple pathways.Not only is it important to identify which targets to address but it are also imperative to identify where in the pathway to intervene. Inrheumatoid arthritis, the cause of inflammation in different joints was attributed to various pathways[3].Anotherobservation is cross-talk between rheumatoid arthritis and coronary artery diseasewithin the same inflammationpathway [4].Thus, modulating a single target or pathway associated with inflammation is probably not sufficient to manage or treat a chronic illness.Furthermore, the more upstream in the pathway the target is the better.Most targets ofcurrent drugssuch as TNF-alpha and IL (interleukin)-6 are downstream in the inflammation pathway.
Drugs sourced from natural products such as microorganisms and plants have been the foundation of the pharmaceutical industry.Aspirin had its origins in the time of Hippocrates (460-370 BCE) where willow bark andsalicylate-rich plants were used to reduce pain, fever and inflammation.The turning point came centuries later when Bayer scientists produced synthetic acetylsalicylic acid (aspirin)with the same effects as salicylateextracts.Another example is the fungus that Alexander Fleming identified in 1928,which had anti-bacterial activity.Howard Florey extracted the penicillin molecule paving the way for its large-scale commercial production anditsrevolutionary use to treat infections.Together Ernst Boris Chain, Fleming and Florey won the Nobel Prize in Physiology or Medicine in 1945.
In the last 40 yearsa drug discovery and development paradigm based on a single, drugtarget and its mechanism of action evolved.Advances in high-throughput screening, genomics and structure-based drug design validated and accelerated its progress.Examples include the discovery and development of more selective COX-2 (cyclooxygenase-2) inhibitors, withfewer sideeffects than aspirin; statins or inhibitors of HMG CoA reductase, the key enzyme in cholesterol biosynthesis for the treatment of hypercholesterolaemia; and anti-retroviral agents targeting the HIV (human immunodeficiency virus) reverse transcriptase enzyme.The same period also saw the emergence of biological or large molecule drugs (mainly proteins) to treat metabolic disease (e.g. recombinant insulin for diabetes; human growth hormone for dwarfism; interferon-beta for multiple sclerosis) and rare, orphan diseases (recombinant human deoxyribonuclease for cystic fibrosis).This periodalso witnessed the fulfilmentof humanised and fully humanmonoclonal antibodies’ promisein the treatment of cancer and other inflammatory diseases such as rheumatoid arthritis.