Therapeutics are currently developed to treat a specific indication, or diagnosis. However, we already know that a drug developed to treat one disease can be used to treat another. Clinicians also know that similar symptoms or even an identical diagnosis between two patients does not mean they will both be treated by a drug approved for that disease. Unravel has developed the concept of a Therapeutic Responder Group to stratify or cluster patients using Unravel’s proprietary AI algorithms and patient RNA signatures based on potential treatment response rather than the root cause of a disorder. No matter if the disorder is caused by a single gene, multiple genes, or genetic and environmental factors, Therapeutic Response Groups are used to find shared ways to treat them.  

Although DNA sequencing of the genome has gotten far more attention, RNA tells a different story. DNA mutations are mostly unchanged over the life of a patient. RNA on the other hand tells a dynamic story of each patient’s specific condition, not just the genetic contributions of their entire genome but also the impact of their environment, sleep, diet, medications, activity, and even the microbiome. As a patient’s disorder progresses or is treated, RNA keeps informing on what is happening. Even for disorders with clear disruption of proteins, RNA still provides a view of the biological system, offering strategies for treatment. The historical lack of RNA data, unlike DNA data, is a major motivator for creating this database.   

A variety of cells – including epithelial, immune, mucosal gland, nerve, etc. – are found in the nostrils. Our nasal swabs capture 57,000+ coding and non-coding transcripts. In addition, they provide reliable coverage of all 1,600 neuronal and synaptic genes, as well as neuronal-related pathways. We also see pathways relevant to most other disorders as epithelial, connective, immune, and vascular tissues are collected in the process. 

*PLEASE NOTE THAT WE DO NOT PROVIDE DIAGNOSTIC OR THERAPEUTIC SERVICES. ALL DATA AND REPORTS ARE INTENDED FOR RESEARCH USE ONLY.  

BioNAV™ was trained using data from an assortment of cell lines, including cancer lines, that were manipulated to over- or under-express a single gene. While there are cell-specific differences, this approach enabled us to identify conserved probabilistic networks. Additionally, the drug database was created using mostly cell lines to generate the data. We were able to overcome the specificity problems by identifying overarching drug effects. This means we are likely missing the context-specific effects in our analysis, but it also means that the predicted mechanisms/drugs are much more likely to translate across preclinical models and into patients. In essence, we are okay with false negatives as long as we find some effective drugs. 

In the SquishyWare™ model, we use CRISPR editing to knock down genes or induce missense and other mutations at one or more sites across one or more genes. While there is generally good evolutionary conservation in sequence and function, we can also humanize the model by injecting mRNA for any desired gene/sequence. This also enables us to work with gain-of-function mutations and complex genetic scenarios. 

We also frequently work with established models as available, including through our collaboration with Jackson Laboratory and correlate model’s drug responses with that of patients to best align preclinical models to the patient populations. 

We see consistency in drug predictions for cases where we resampled the same individual. Normally this occurs over a span of several months, but we see pathways corresponding to drug treatment shift in response while other pathways remain fairly unchanged. In personalized studies, we collect RNA over 8 time points across 2 days. This serves to handle the natural changes in expression due to circadian rhythms. 

We are waiting to compare the results of this study, comparing blood to nasal swab samples collected at the same time. Samples are being sequenced, and this is in studies with humans and, separately, in sea lions. We fully expect gene expression baseline and differential changes to be quite different between tissues. We however expect the drug predictions to be highly correlated, as we have seen from other studies with different tissue types (and even species), such as in our statin and COVD-19 publication: Target-agnostic drug prediction integrated with medical record analysis uncovers differential associations of statins with increased survival in COVID-19 patients

If someone’s state of health can represent the patient’s desired state of health, then they can be considered the healthy control. This is because, in layman’s terms, BioNAV™ predicts molecules that will make the patient more like the control.