Squid-inspired technology could replace needles for medications and vaccines

Using jet propulsion inspired by squid, researchers demonstrate a microjet system that delivers medications directly into tissues, matching the effectiveness of traditional needles.

Study: Cephalopod-inspired jetting devices for gastrointestinal drug delivery. Image Credit: Jasni/Shutterstock.com
Study: Cephalopod-inspired jetting devices for gastrointestinal drug delivery. Image Credit: Jasni/Shutterstock.com

In a recent study published in Nature, a research team led by scientists from Massachusetts Institute of Technology and Novo Nordisk explored a novel, needle-free microjet system to deliver drugs directly into the gastrointestinal tract.

Inspired by the jet propulsion system in cephalopods, these devices were designed to efficiently administer macromolecules such as insulin and ribonucleic acid (RNA) via precise, high-pressure jets into the gastrointestinal tract, potentially improving drug absorption and addressing the challenges associated with traditional injection-based delivery methods.

Background

Drug delivery for macromolecules has depended on needle-based injections, which raises issues such as the need for medical training, the risk of needle-related injuries, and the challenge of disposing of sharps. In recent times, the development of ingestible devices has offered a convenient alternative, potentially enhancing patient compliance.

However, current oral delivery devices struggle to effectively deliver large molecules, such as proteins, due to their vulnerability to digestive breakdown. Many oral systems also fail to achieve bioavailability levels comparable to those of subcutaneous injections. Furthermore, although robotic and autonomous devices have shown some success with self-directing and needle-free drug delivery, these methods have remained largely underexplored for gastrointestinal applications.

About the study

In this study, inspired by the natural propulsion mechanisms observed in cephalopods, the researchers aimed to develop a jet-based drug delivery approach to enhance the safe and effective delivery of large molecules in gastrointestinal tissues. They developed and tested a series of microjet devices (MiDe systems) designed to deliver drugs directly into the gastrointestinal tract.

Four device configurations were created: two autonomous, self-activating versions (MiDeRadAuto and MiDeAxAuto) and two versions compatible with endoscopic guidance (MiDeRadEndo and MiDeAxEndo). Furthermore, the orientation of each device was optimized for specific gastrointestinal tract sections. The radial models were designed to target tubular structures such as the small intestine, while the axial models were suited for wider areas in the stomach.

The devices were first calibrated in laboratory settings through in vitro and ex vivo studies. During these tests, the researchers varied nozzle diameter, input pressure, and jet angle to determine optimal conditions for effective tissue penetration.

Ex vivo trials on porcine gastrointestinal tissue measured the fluid delivery depth and distribution in the tissue layers using computed tomography (CT) to visualize the fluid spread. Following these tests, the researchers fine-tuned the device pressure and nozzle dimensions to produce high-pressure jets suitable for different gastrointestinal regions.

Additionally, in the in vivo trials, the MiDe devices delivered therapeutic agents such as insulin, glucagon-like peptide 1 (GLP-1) analogs, and small interfering RNA (siRNA) into specific gastrointestinal sites in pigs and dogs. Subsequently, the researchers collected blood samples at regular intervals to measure systemic bioavailability.

Moreover, high-speed imaging was used to capture the jetting dynamics, enabling the researchers to assess the stability and recoil of the device. Safety and precision tests were also conducted to confirm the suitability of the device for use in the gastrointestinal tract without causing adverse effects or damage to surrounding tissues.

Results

The researchers demonstrated that MiDe devices significantly improved the delivery and bioavailability of macromolecules within the gastrointestinal tract. The devices achieved high systemic absorption for insulin, GLP-1 analogs, and siRNA, with performance comparable to subcutaneous injections.

Specifically, the radial endoscopic device (MiDeRadEndo) delivered GLP-1 with a 67% bioavailability in pig intestines, while the axial endoscopic device (MiDeAxEndo) achieved an 82% bioavailability for siRNA in the stomach. Autonomous devices, MiDeRadAuto and MiDeAxAuto, demonstrated 31% and 23% bioavailability, respectively, for insulin in pigs.

The results showed that bioavailability was influenced by factors such as jet angle, distance from tissue, and pressure level. A 40% decrease in volumetric delivery efficiency (VDE) was observed when the jet angle reached 45° relative to the tissue.

Furthermore, while the self-orienting design of MiDeAxAuto enabled stable positioning in the stomach, MiDeRadAuto was seen to maintain a co-axial orientation in the intestine despite some variability due to animal movement. Histological analysis also confirmed that the jets delivered therapeutic agents deep within the target tissue layers without causing damage.

The radial devices minimized recoil with a dual-nozzle design, which also enhanced stability. Moreover, the devices demonstrated reliable safety and stability across in vivo and ex vivo tests, suggesting that MiDe systems can safely and effectively deliver large molecules within the gastrointestinal tract.

Conclusions

Overall, the findings demonstrated that the needle-free, microjet-based MiDe systems for drug delivery into the gastrointestinal tract achieved bioavailability levels similar to subcutaneous injections while safely and effectively targeting specific gastrointestinal regions. These findings indicated that the MiDe platform could be used to advance oral drug delivery technology, making it feasible to deliver macromolecule therapies directly into the gastrointestinal tract.

Journal reference:
  • Arrick, G., Sticker, D., Ghazal, A., Lu, Y., Duncombe, T., Gwynne, D., Mouridsen, B.,... Traverso, G., 2024. Cephalopod-inspired jetting devices for gastrointestinal drug delivery. Nature. doi:10.1038/s41586-024-08202-5 https://www.nature.com/articles/s41586-024-08202-5

Dr. Chinta Sidharthan

Written by

Dr. Chinta Sidharthan

Chinta Sidharthan is a writer based in Bangalore, India. Her academic background is in evolutionary biology and genetics, and she has extensive experience in scientific research, teaching, science writing, and herpetology. Chinta holds a Ph.D. in evolutionary biology from the Indian Institute of Science and is passionate about science education, writing, animals, wildlife, and conservation. For her doctoral research, she explored the origins and diversification of blindsnakes in India, as a part of which she did extensive fieldwork in the jungles of southern India. She has received the Canadian Governor General’s bronze medal and Bangalore University gold medal for academic excellence and published her research in high-impact journals.

Citations

Please use one of the following formats to cite this article in your essay, paper or report:

  • APA

    Sidharthan, Chinta. (2024, November 20). Squid-inspired technology could replace needles for medications and vaccines. News-Medical. Retrieved on December 22, 2024 from https://www.news-medical.net/news/20241120/Squid-inspired-technology-could-replace-needles-for-medications-and-vaccines.aspx.

  • MLA

    Sidharthan, Chinta. "Squid-inspired technology could replace needles for medications and vaccines". News-Medical. 22 December 2024. <https://www.news-medical.net/news/20241120/Squid-inspired-technology-could-replace-needles-for-medications-and-vaccines.aspx>.

  • Chicago

    Sidharthan, Chinta. "Squid-inspired technology could replace needles for medications and vaccines". News-Medical. https://www.news-medical.net/news/20241120/Squid-inspired-technology-could-replace-needles-for-medications-and-vaccines.aspx. (accessed December 22, 2024).

  • Harvard

    Sidharthan, Chinta. 2024. Squid-inspired technology could replace needles for medications and vaccines. News-Medical, viewed 22 December 2024, https://www.news-medical.net/news/20241120/Squid-inspired-technology-could-replace-needles-for-medications-and-vaccines.aspx.

Comments

  1. Wayne Kröncke. Wayne Kröncke. Bulgaria says:

    I recall that the US Military experimented with a High pressure needle-less injection system for annual flu & other shots, in the early 1970s. They stopped when they found that slight moements of the nozzle against the skin could slice the recipient open & cause lots of bleeding*. They resumed the needle next year.
    *-I had mine, luckily the nozzle didn't move.

The opinions expressed here are the views of the writer and do not necessarily reflect the views and opinions of News Medical.
Post a new comment
Post

While we only use edited and approved content for Azthena answers, it may on occasions provide incorrect responses. Please confirm any data provided with the related suppliers or authors. We do not provide medical advice, if you search for medical information you must always consult a medical professional before acting on any information provided.

Your questions, but not your email details will be shared with OpenAI and retained for 30 days in accordance with their privacy principles.

Please do not ask questions that use sensitive or confidential information.

Read the full Terms & Conditions.

You might also like...
Transcranial ultrasound stimulation: A new frontier in noninvasive brain therapy