Overview
We are a development stage medical device development company focused on advancing innovative technologies for sensing and treating disorders relating to the nervous system. Our first-in-class technology platform includes a catheter-based microchip-enabled sensing array that can detect and differentiate neural signals with a high degree of sensitivity as demonstrated in animal studies. We are initially developing our technology for patients with pancreatic cancer, a condition that can cause debilitating pain and needs a more effective solution. However, we believe our technology constitutes a platform with the potential to address dozens of indications in a range of areas including chronic pain management from all causes, hypertension, cardiovascular disease and a wide range of other nerve-related disorders.
We calculate sensitivity in units of minimum signal detection voltage in micro volts (uV) time area of the electrode (square millimeters). It is a combined measure that is related to the signal resolving power and spatial resolution of the system. For the BSC Orion, the nearest device on the market, the metrics are 10uV for signal detection levels, and roughly 0.4mm by 0.5mm for the electrode dimensions. For the Autonomix device, the metrics are <1uV for signal detection levels and roughly 0.02mm by 0.03mm for the electrode dimensions. The differences in these metrics result in a calculation of 3,000 times greater sensitivity for the Autonomix device. We believe, if we can recreate these results in clinical trials, this will enable a method of transvascular targeting, treating, and confirming treatment of diseases involving the nervous system throughout the body that is not currently available and may be capable of filling a wide range of unmet medical needs.
Our development efforts can be divided into to two sub parts: diagnostic and therapeutic, where diagnostic is focused on sensing and identifying neuronal activity that may be associated with a disorder with enough precision to enable targeted therapy with ablation. Our sensing catheter has already been developed sufficiently to demonstrate in animal models successful identification of a signal from a specific nerve bundle before ablation and confirmation of termination of that signal from the treated nerves after ablation. We are now in the process of improving the design of this catheter to meet the standards required for human use. In parallel with this effort, we are conducting a first-in-human demonstration of transvascular ablation to relieve pain associated with pancreatic cancer, with the intent to bring sensing and treatment together in a future pivotal clinical trial to enable the commercial launch of our technology. We are a development stage company and there is no guarantee that the results of any trials will produce positive results or that the results will support our claims.
We believe one of the most demanding aspects of our commercialization plan will be scaling up from our existing sensing prototype to a robust commercial version. Today, our sensing device is hand built and includes a combination of hand-crafted and 3D printed parts. We have not yet assembled or tested what will be the commercial version of our proposed device. Even if our proposed device is cleared for commercial use, there is no assurance that we will be able to successfully build such device on a commercial scale.
As of March 31, 2024, we had an accumulated deficit of $39.0 million, negative cash flows from operating activities of $6.6 million and working capital of $8.6 million, which raises substantial doubt about our ability to continue as a going concern. Further, we have incurred and expect to continue to incur significant costs in pursuit of our business plans. We cannot assure you that we will be successful in raising additional funds. These factors, among others, raise substantial doubt about our ability to continue as a going concern.
Our Technology
Targeting the Peripheral Nervous System
The peripheral nervous system comprises a vast network of nerve fibers extending throughout the human body and interacting with every organ. Peripheral nerves can be further classified as autonomic (supplying sympathetic and parasympathetic nerve signals from the brain to tissue and organs, i.e., fear inducing production of adrenaline) and somatosensory (supplying signals to the brain from tissue and organs, i.e., the sensation of pain). Whether as a root cause or a manifestation of resulting symptoms, these nerves play a role in virtually all diseases.
Unfortunately, we believe that very few tools currently exist for the sensing and targeting of nerve fibers within the peripheral nervous system. At Autonomix, our primary goal is to provide a breakthrough in sensing technology that will become an indispensable tool for diagnosing, targeting, and treating disorders relating to the peripheral nervous system. And, although our Company’s name hails from the autonomic subgroup of the peripheral nervous system, our technology is intended for both the autonomic and somatosensory systems and could eventually find uses within the central nervous system.
Exploiting the Vascular Superhighway
The Autonomix system we are developing is primarily catheter based, meaning that our sensing equipment will be delivered to its targeted location via a lumen within the body. While this could include oral, urethral, and other natural openings of the body, our primary focus is using the vasculature, most often arteries, to reach our target. Fortunately, nature has endowed us with “superhighway” access in the form of our arterial structure, as most of the peripheral nerves travel along our arteries. As can be seen in this cross-sectional view of the kidney and renal artery, the web of peripheral nerve fibers (shown in yellow) parallels the renal artery, and this form of nerve pathway development is typical throughout the body.
Our sensing catheter has been designed to be introduced by a small incision into an artery (such as the femoral artery) and with a conventional guide wire or sheath be directed to any organ in the body where it will be close enough to the nerve fibers servicing that organ to sense, target and treat the nerves associated with that targeted disorder, and to confirm that the intended treatment was successful.
The Sensing Problem
Although this vascular superhighway has long been utilized for certain catheter-based evaluation and intervention, we believe its use throughout the body has been limited by the lack of adequate sophistication of catheter systems. According to a Markets and Markets report, titled “Electrophysiology Market Global Forecast to 2027” published in February 2023, the global electrophysiology market in terms of revenue was estimated to be $6.8 billion in 2021 and is expected to reach $11.6 billion by 2027. The report cites as a driver for such market the increased incidence of cardiovascular disease and the use of catheters to deliver corrective ablation in the field of cardiology. Most commonly, radio frequency (RF) energy is emitted from inside the walls of the heart or arteries sufficient to ablate (destroy) a cardiomyocyte or nerve within its path. This “transvascular” use of ablation forms the basis for treating atrial fibrillation, for example.
More recently, companies like Medtronic have successfully used transvascular ablation of the nerves surrounding the renal artery to treat refractory hypertension (high blood pressure that has been resistant to standard drug therapy). One of the challenges they face however is that the nerves they are targeting operate at much lower voltage levels than, say, the level emitted by a cardiomyocyte. In cardiology, there are sensing systems capable of sensing down to a level of about 10 to 15 microvolts. That’s more than enough sensitivity to detect (and target) a cardiomyocyte that is emitting 100 microvolts per pulse, but the nerves around the renal artery (and around most peripheral nerve targets throughout the body) are operating at around 1 to 2 microvolts; much too low to be detected by existing sensing technology.
What this means is that the ablation of nerves from within the renal artery is essentially conducted “blind.” Without a sensing system capable of detecting and targeting signals from nerves within the nervous system, clinicians cannot see the nerves causing hypertension in the patient. As a result, they are forced to hypothesize and treat one small area at a time, hoping they hit the desired target without hitting an unintended target. Over-treating the area could relegate the patient to life in a wheelchair by destroying their ability to regulate blood pressure.
The Autonomix Solution
We believe the reason no one has commercialized a sensing system capable of solving this problem is that the physics involved demanded a major technological breakthrough. By their very nature, electrical signals from the body are analog and even though a 10-microvolt signal can be detected and transmitted down the roughly 2 meters of wire required to travel along the catheter, outside the patient, and into the necessary processing equipment shown in this picture below of a typical catheter lab, this isn’t feasible with the 1 to 2 microvolt signal from a typical peripheral nerve. Given the cacophony of other signals emitted throughout the body and by other equipment in the lab as well as degradation of the signal due to the distance traveled along the catheter, these faint signals become lost or are rendered meaningless.
We are seeking to solve this problem through our design, which is still in development, of a proprietary microchip comprised of multiple key components. Each antenna is comprised of two small electrodes that can detect the presence of voltage down to as little as 0.5 microvolts giving us sufficient sensitivity to register the impulse of a nearby nerve bundle that might typically be generating 1.5 to 2.0 microvolts with each impulse. Our current design connects 8 antennae to our proprietary chipset (which is designed to handle up to 16 antennae) where an onboard amplifier and analog to digital converter convert each signal into a robust digital form. The chipset also includes a multiplexer intended to enable the transmission of data from each of the antennae simultaneously down the catheter body to the catheter handle. The Wi-Fi handpiece then transmits this data to a nearby laptop for viewing and analysis by the clinician.
In a typical catheter lab, these signal conversion functions are often carried out by “briefcase” sized devices processing the raw analog signals that must travel the full length of the catheter, outside the patient’s body and then from the patient to the equipment. While this is feasible for higher voltage signals from the heart, the signals from peripheral nerve bundles are often too faint to travel all this distance without loss or corruption and yet the typical catheter lab equipment is far too big to fit inside a catheter. The patented Autonomix solution shrinks these processes down to a microchip small enough to place immediately adjacent to the antennae detecting the signals, greatly reducing the distance the signals must travel. The picture of the “proprietary chipset” below is our actual chipset and is not a rendering.
As shown in the diagram below, this basket antenna array is built from a micro-thin, laser-cut flexible circuit board. We believe the special arrangement of the antennae will make it possible to effectively geolocate the nerve in 3-dimensional space for targeting treatment.
Sense, Ablate, Confirm
This sensing system is currently being developed to be deployed alongside a separate radio frequency ablation catheter system for a combined diagnostic and therapeutic solution which will require the use of two separate catheters that will be used during the procedure. However, our longer-term design is intended to combine the two catheters into one device so that the combined system could be capable of sensing, treating (ablating) and confirming successful treatment all with one relatively simple and minimally invasive procedure.
Focus on Pancreatic Cancer Patients
We believe the Autonomix sensing technology has the potential to provide a level of detail and resolution in navigating the peripheral nervous system that until now has simply not been possible. As such, we believe this platform, if shown to be effective, could be applied to a wide range of disorders throughout the body. With that said, our experience tells us that the best way to develop a new technology like this is to narrowly focus on a proof of concept that we think will reflect the capabilities of our system while providing the most expeditious pathway to regulatory clearance, commercialization and revenue generation.
For this reason, we are initially focusing on the treatment of pain associated with pancreatic cancer and we have designed our commercialization efforts around this as our first proposed indication for use.
We believe this is a good choice for several reasons:
Significant Unmet Need
According to a report by The Oncologist, titled “Pancreas Cancer-Associated Pain Management” first published April 22, 2021, “[p]ain is highly prevalent in patients with pancreas cancer,” “90% of these patients reported discussing pain with their health care provider,” and “50% of the respondents reported visits to the emergency room for symptoms related to pain.” One of the tragedies of this condition is that most pancreatic cancer patients have a short time to live and the debilitating pain resulting from the tumor can significantly reduce the quality of that remaining time. Moreover, we believe that prolonged pain can diminish a patient’s will to live, making that remaining time even shorter.
The standard of care treatment usually begins with opioids, but patients often become resistant, and the side effects of chronic opioid use can eventually outweigh the benefits.
The most common alternative method of treatment is a neurolytic celiac plexus blockade (“NCPB”), which is a percutaneous (via needle through the skin) ethanol injection guided by CT scan to attempt to direct the ethanol (which will destroy neural tissue on contact) to the area of the pancreatic tumor and related peripheral nerves. Regardless of this initial targeting, the varied structure of the abdominal cavity leads to the potential for ethanol to either miss the intended target or migrate to unintended areas creating unwanted side effects.
Furthermore, according to a study titled “Neurolytic Celiac Plexus Block for Pain Control in Unresectable Pancreatic Cancer” published by the American Journal of Gastroenterology, 2007, Vol.102 (2), p.430-438, Article 430, meta-analysis from multiple randomized controlled trials suggests that patient benefits from NCPB are only marginally better than opioids and may not be outweighed by the potential risks. The most common side effects are diarrhea, transient hypotension, constipation, nausea and vomiting, and lethargy while rare major adverse events reported in the literature include infectious complications, bowel perforation, intraabdominal hemorrhage, fistula formation, stomach paralysis, partial paralysis of the lower limbs or loss of other motor function, chronic diarrhea, arterial damage, water on the lung, and death.
In contrast, we believe the Autonomix procedure could represent a much safer and more reliable treatment. This has the potential to significantly increase remaining quality of life for pancreatic cancer patients, and in so doing, even potentially extend overall survival.
To begin with, our entire approach is via arterial catheter, inserted in most cases via the femoral or brachial artery. We believe this method of access that should significantly reduce the potential for complications as compared with NCPB. We believe our sensing technology has the potential to identify and target the nerves that are responsible for the pain signal and with the ability to focus the ablative energy on that target, we should have a much greater degree of accuracy, control and reliability as compared with NCPB.
When comparing to the use of opioids, we believe the potential benefits are even more obvious. The Autonomix procedure we are developing is, by design, targeted directly to the nerves responsible for the pain being treated and offers the potential for “one and done” durability, whereas opioids are systemic treatments subjecting the entire body to unnecessary exposure, requiring constant dosing, and inducing debilitating chronic systemic side effects as a consequence.
Beneficial Clinical Trial Dynamics/Expedited Regulatory Process
Despite the significant unmet need, there are very few clinical trials worldwide focused on improving pain management for pancreatic cancer patients and currently none that we are aware of in the proposed location of our planned first-in-human proof of concept study. We believe this means there is limited competition for such patients, making it theoretically easier to recruit for our trial.
At the same time, because we are focusing on palliative care for patients whose lives are being limited by a rare cancer, we believe regulatory authorities are willing to consider lower preclinical hurdles and smaller and simpler trial designs to help encourage trial sponsors to seek improved treatment options. However, these decisions are under the exclusive control of regulatory authorities and there is no guarantee that our trial designs will be approved. If regulatory authorities are willing to consider lower preclinical hurdles and smaller and simpler trial designs, this would translate into lower preclinical and clinical trial cost, as well as shorter completion times. Furthermore, study duration is also shortened by the very nature of the indication and primary efficacy endpoint: reduction of pain associated with pancreatic cancer.
Specifically, we intend for each patient to need only one treatment and we expect we will be able to immediately determine if there is any reduction of pain from our procedure such that an initial indication of pain reduction will likely be provided by patients upon conclusion of that treatment. Although follow up visits will be required to assess continuing safety and durability of efficacy over a span of several months, an initial indication of efficacy will be available almost as quickly as patients are treated . For this reason, we are hopeful that the overall duration of this first trial will be measured in months rather than years, as is often the case for clinical trials with longer treatment durations or where a clinically significant response takes more time to be produced.
Meaningful Commercial Market
Although pancreatic cancer is considered a rare disease, according to the American Cancer Society “Key Statistics for Pancreatic Cancer” (https://www.cancer.org/cancer/types/pancreatic-cancer/about/key-statistics.html), the American Cancer Society estimates in 2023 that approximately 64,000 will be diagnosed with pancreatic cancer in the U.S. on an annual basis and an article in the International Journal of Cancer (Int. J. Cancer. 2021;149:993–1001) indicates that annual new cases in the European Union reached 109,000 in 2019 and are expected to grow. A market analysis published by Precedence Research (https://www.precedenceresearch.com/ pancreatic-cancer-market) reported that the global market for treatment of pancreatic cancer in 2022 was estimated to be $2.2 billion. Published research by The Oncologist, titled “Pancreas Cancer-Associated Pain Management” stated that “90% of patients [with pancreatic cancer] reported discussing pain with their health care provider”. As a point of reference, a one-month course of Abraxane (a commonly prescribed drug for the treatment of pancreatic cancer) has a retail price of more than $10,000. While this should not be considered an indicator of how an Autonomix procedure will ultimately be priced, we believe it reflects the magnitude of potential market size and helps form the basis for expecting a significant revenue opportunity from this indication.
The incidence of pancreatitis, a non-cancerous condition that can also result in chronic pain, is estimated to be as much as three times that of pancreatic cancer. We believe that, if our procedure is cleared for use in treating pancreatic cancer pain, we should be able to eventually expand that clearance to include pain resulting from pancreatitis.
The Potential to Impact Cancer
Recent independent research has indicated that neural pathways may play an insidious role in cancer progression. An article published in Metastatic Cancer: Clinical and Biological Perspectives, titled “Sympathetic Nervous System Regulation of Metastasis” demonstrates that as pancreatic tumors progress to invade the liver (a common occurrence in patients with pancreatic cancer and a significant driver of morbidity) they do so by traveling along local neural pathways. Our development team speculated that disruption of these pathways might have the potential to slow or stop the progression of the primary tumor.
In collaboration with a specialist in pancreatic cancer, we conducted a study in mice to see if ablation (in this study, ethanol ablation was used, similar to its use with NCPB in humans) of the nerve fibers around the pancreas might have an effect on tumor progression. As can be seen in this study summary, there was a reduction in tumor progression in this model. This was a small study, and we can’t be certain that these results are indicative of the potential for impacting tumor progression in humans, but we do see this as encouraging further study and may represent a future opportunity beyond pain management.
Indicative of Additional Market Potential
We believe pancreatic cancer pain management is a “proof of concept,” and we believe success here will be indicative of the potential of our system in a wide range of disorders where the peripheral nervous system is involved.
Examples of future potential additional uses include renal denervation for treating hypertension, addressing other sources of pain including lower back and other joint locations, Complex Regional Pain Syndrome (“CRPS”), other tumor related pain, and pelvic pain, pulmonary disorders such as chronic obstructive pulmonary disease, and urinary tract and digestive disorders, and enabling more targeted treatments in cardiology, just to name a few.
A Markets and Markets report, titled “Electrophysiology Market Global Forecast to 2027” published in February 2023 describes the global electrophysiology (EP) market as representing approximately $6.8 billion in 2021 in annual global revenue, and is expected to reach $11.6 billion by 2027. The vast majority of this market today is represented by cardiology related diagnosis and intervention. Our vision for the Autonomix technology is to help expand electrophysiology well beyond cardiology to include nearly all reaches of the peripheral nervous system and we believe doing so will ultimately result in a market opportunity much greater than the current projections for the EP.
We believe enabling targeted transvascular treatment of pain will enable us to access the $75 billion pain management market, as cited in the Mordor Intelligence Pain Management Market Industry Report (https://www.mordorintelligence.com/industry-reports/pain-management-market). Additionally, facilitating a safer, more targeted method for renal denervation should enable us to access the $23 billion hypertension market, as indicated by Polaris Market Research (https://www.polarismarketresearch.com/industry-analysis/global-hypertension-drug-market). When additional indications such as COPD, irritable bowl syndrome, and overactive bladder are included, we believe the Autonomix platform has the potential to address more than $100 billion in market opportunities.
Commercialization Plan
Regulatory Pathway
The most likely approval pathway for our technology is referred to as “de novo” premarket notification. This is differentiated from the more common “510(k)” pathway, which is only applicable when there is a clear “predicate” device already on the market (doing the same thing in substantially the same way) and from the lengthier “PMA” process when there is no precedent at all for a technology. In our case, both sensing and ablation have established precedence, just not at this level of sensitivity or in our targeted indications.
Whether in the United States or EU, we must demonstrate that our technology is safe and effective. The safety standard is ultimately met through a combination of animal studies, independent laboratory testing, a design history file documenting compliance with established standards and, ultimately, human clinical trials. Many of these requirements are staged such that not all must be met on the front end of development. In addition, efficacy must be based on a sound scientific rationale and ultimately demonstrated in a human clinical trial.
Human trials are often designed to begin with a Proof of Concept (“PoC”); the US Food and Drug Administration (“FDA”) sometimes refers to these as Early Feasibility Studies (“EFS”) and then progress to a “Pivotal” or approval, trial. The design and endpoints of pivotal trials are often negotiated with the relevant regulatory authority (i.e., FDA in the United States, EMA or country-specific Competent Authority (“CA”) in Europe). Our regulatory package for authorization to conduct our first-in-human clinical trial was approved by the Ethics Committee (“EC”) at our intended clinical site hospitaloutside the United States. This approval allowed the clinical trial to begin The regulatory package submitted included not only a detailed clinical protocol for conducting the study, but also an extensive Investigator’s Brochure (“IB”) setting forth details about the equipment to be used, historical safety of human procedures conducted with this equipment and details of our animal studies using this equipment for the first time in the area of the pancreas.
We plan to present the relevant data from this study to the FDA in a pre-submission meeting to request “Breakthrough Status” in an effort to minimize the clinical requirements for clearance in the United States. The first trial is not designed to replace the trial that will be required by the FDA to support our submissions for clearance in the United States, but rather to potentially impact the size of that required trial.
According to an article by Applied Clinical Trials, titled “Medical Device Development: U.S. and EU Differences” published August 1, 2006 “[t]he way in which devices are regulated in the EU is very different from the way they are regulated in the United States,… [which] has introduced significant differences in time-to-market approval for the United States versus the EU, particularly in the case of high-risk Class III and Class IIb implantable devices.” While this is changing based on the advent of a new EU regulation called Medical Device Regulation (“MDR”) that is expected to make the EU process more like the FDA process, MDR is being rolled out country by country. We believe the approval process in some EU countries for utilizing CE marked devices off label is less demanding than in the US. As a result, we have decided to conduct the PoC in Europe instead of the US.
Once the PoC is established, however, there are compelling reasons to focus the approval process first and foremost in the US. One reason is that therapeutic procedures in the US will usually command higher prices and once those prices are set, EU pricing authorities will often index off of the US price. Another is that product launches are usually easier in the US where a single sales force can serve the entire region (as opposed to country-specific distribution teams in the EU) and where one regulatory standard applies across the board.
The development of the PoC data forms the basis for two FDA-related processes. First is the request of a “Pre-Submission” meeting to discuss the overall regulatory strategy, the primary focus of which is to agree on a pivotal testing protocol. Assuming promising PoC data, the second is to submit a request for “Breakthrough” status based on the significant unmet need. Breakthrough status affords us expedited access to FDA and a higher level of proactive interaction that may support faster approval.