Gilbert looks forward to attending the annual DDL (Drug Delivery […]
Meet Gilbert team:
Interview with Scott Fleming
Name:
Scott Fleming
Role title:
Chief Commercial Officer
Joined Gilbert:
2019
Office location:
HTC 27, Eindhoven
Author:
Maurits Huigen, CEO
Interview with Scott Fleming (LinkedIn), Gilbert’s Chief Commercial Officer
Scott brings 30+ years’ experience in pharmaceuticals, drug delivery and digital health to Gilbert, where he’s been active since 2019. Before joining Gilbert, Scott worked at management firm PA Consulting, counseling major pharma & biotechs on drug delivery strategy and technology development before exiting to co-found MicroDose Therapeutx in Princeton, NJ, to develop its own proprietary inhalation technologies. As Head of Sales & Marketing he helped grow MicroDose from a start-up inhaler device company with an out-licensing model to an integrated pulmonary products company. This growth attracted buyers and in 2013 MicroDose was acquired by Teva Pharmaceuticals, and Scott joined their global respiratory group in Amsterdam as Brand Lead for eConnectivity and other specialty products, before going back to helping start-ups.
Can you give us some history on the main developments in pulmonary drug delivery?
Sure, and as Gilbert is developing a ‘liquid inhaler’ format, I will focus on nebulization systems, which convert liquid medication into aerosols for inhalation.
The first electric nebulizers were developed in the 1930s, but by the 1950s Jet nebulizers, that used compressed gas to create a fine mist of medication, had become the most common form of delivery. These large machines required a fixed gas source and were typically used only in hospitals. As technology improved through the 1960s-1970s more portable versions were introduced allowing for at-home treatment. But these too were bulky, noisy and highly inefficient, with long nebulization times and delivering only 10-15% of the dose into the lungs. Jet nebs are also cumbersome to assemble/disassemble and to keep clean. The 1980s brought a new technology, ultrasonics, using high-frequency sound waves to create a mist, offering a quieter and faster option to jet nebulizers. Ultrasonic nebulizers were popular in the home-care market as they were smaller and quieter, but they are incompatible with suspensions and viscous solutions and also generate heat which can damage sensitive molecules like proteins. The 1990s introduced vibrating mesh (VM) nebulizers which force liquid through tiny holes in a vibrating membrane to create an aerosol. VM nebs are more efficient and portable than jet nebulizers, and today are widely used for both hospital and home care. But the fine mesh in VM nebs can become clogged or experience foaming, especially with suspensions and more viscous formulations.
In 2004 the first soft mist inhaler (SMI), Respimat(R) was launched. SMIs deliver a fine mist using mechanical energy from a spring to create a slow-moving mist. SMIs require manual activation which can be difficult for some patients (like the elderly), can only deliver a small dose per inhalation and are currently available for only a limited number of medications.
Are new advancements needed?
It’s been 20 years since we’ve seen a major innovation in the market, and in the meantime advancements in the development of therapeutics has continued to progress, creating new unmet needs and challenges for pulmonary delivery devices. Today, Inhaled therapies are a standard for chronic respiratory conditions, but most are small-molecules, whereas biologics could offer more targeted solutions with longer-lasting effects, especially for managing inflammation and immune responses. In the market overall, biologic-based treatments are replacing small molecule therapeutics at a rapid rate. In 1980 biologics made up less than 1% of the overall pharmaceuticals market, but today they make up 25-30% with projections to reach 45-50% by 2040. This in turn is driving the development of inhaled biologics, and by 2030 biologics like monoclonal antibodies (mAbs) and RNA-based therapies will likely be formulated for inhaled delivery, targeting a broad range of respiratory conditions like severe asthma, cystic fibrosis (CF), non-CF bronchiectasis (NCFB), and COPD. And by 2040, inhaled gene therapies, stem cells, or growth factors to repair lung tissue damaged by COPD and pulmonary fibrosis are envisioned. These future inhaled therapies will require ever more complex formulations and processes, making them more expensive and requiring higher efficiency of delivery to be cost effective, along with greater precision and targeting in the lungs to be efficacious.
Is this where electrospray and Gilbert’s Smart Precision Inhaler comes in?
Yes, It is well known that for inhalation therapies to be effective they need to be deposited in the right region of the lungs to target the intended disease process and relevant receptors, and that aerosol particle size and distribution are the key determinants for lung deposition. But many of the technologies I’ve listed are limited in the particle sizes they can generate and most have fairly broad particle size distributions, which can limit the efficacy of treatment and potentially also contribute to undesired side effects. So there is a strong need for a technology that provides more customizable particle size AND tighter particle size distribution.
EHDA (Electro Hydrodynamic Atomization or Electrospray) is just such a technology, as it produces monodispersed particles. And with our electrospray engine we have the ability to customize the particle size as needed. Additionally, Electrospray produces a soft mist aerosol that can be easily inhaled, which could result in higher lung deposition, and fewer patient errors. There is no product on the market today that has the potential for such precise targeting to the lungs enabled by monodispersity to optimize the therapeutic response and limit potential side effects. So with our Gilbert Smart Precision Inhaler we are satisfying a number of unmet needs in the market. And that’s why we ask the question to our pharma partners; ‘What’s your target’? As we believe with EHDA we can hit their target more successfully.
And what makes the device ‘Smart’?
As this is an electronic device, we can easily incorporate the necessary hardware and software in a holistic integrated design. We intend to include the latest sensor and software solutions for monitoring device functions and proper use technique, and to control basic features like breath activation and fault detection so we can continuously improve patient interaction with the device. But we also plan to track more advanced behavioural aspects of use for analysis to enable the user and health care provider to confirm or improve therapy adherence. Adherence to respiratory treatments is lower than in most other diseases, as it involves a device interaction; when users don’t feel they’re doing it right, they stop using it. A lot of the products are also maintenance therapies, which don’t produce an immediate effect, and this also reduces adherence. By making it ‘smart’, we aim to improve compliance and adherence, to give better coordinated care and end up with fewer patient errors. All with the aim to improve patient experience and disease outcomes.
Can you explain ‘Breath activated’ and why that is important?
Jet nebulizers and most VM nebs deliver aerosol continuously, whether or not the patient is inhaling or exhaling. This approach has two major drawbacks, first is that about half of the dose is lost, and to waste that amount of an expensive drug with every dosing can make the treatment unaffordable. Second is that this lost aerosol is vented into the atmosphere (what are called fugitive aerosols) which may have harmful affects on the environment or anyone in the vicinity. The Gilbert Smart Precision Inhaler is breath activated, and only generates aerosol upon demand (only while the patient is inhaling) while suspending mist generation during exhalation. With this ‘closed’ system we maximize efficiency, using less drug overall, reducing waste and cost while limiting the safety risks of fugitive aerosols.
So how unique is this Smart Precision Inhaler?
Totally unique, as I believe we are the only company today developing an inhaler based on EHDA or electrospray for the respiratory market, and therefore the only company that can offer the precision lung targeting enabled by a monodispersed aerosol with customizable particle size. Electrospray also puts no mechanical stress on the liquid and therefore should be suitable for fragile molecules like proteins. Adding to this the capabilities to monitor both technique and dose tracking to improve adherence, and future mobile applications and connection to the broader healthcare system to improve both self and coordinated patient-centric care, should put us at the forefront of respiratory treatment. So with our Gilbert Smart Precision Inhaler we are indeed unique in our ability to meet the challenging delivery needs of the complex and expensive therapies coming out of research.
Gilbert is developing the next generation of soft mist inhalers based on a proprietary electrospray (Electro Hydrodynamic Atomization or EHDA) technology to redefine treatment for lung patients. Gilbert’s breath actuated smart precision inhaler creates a monodispersed soft mist aerosol, with a customizable droplet size enabling more precise targeting of drugs to desired regions of the lungs, which has the potential to improve the efficacy and safety of treatments. Electrospray enables gentle, efficient delivery of both small and large molecule therapies in both solution and suspension formulations.
Visit us at Gilbert | Redefining treatment for lung patients, follow us on Linkedin or contact us at info@gilbert.eu to learn if electrospray is suitable for your application.
Related posts
The Gilbert team looks forward to attending the International Conference […]
The Gilbert team looks forward to attending the European Respiratory […]
Let’s stay in touch!
Stay up-to-date with Gilbert’s latest news, vacancies and achievements by following us on social media.