Validation of a novel medical device (Chloe SED®) for the administration of analgesia during manual vacuum aspiration: a randomized controlled non-inferiority pilot study.

Introduction: Millions of women worldwide annually undergo manual vacuum aspiration (MVA) with no pain medication, which is a violation of their basic human dignity. We designed a novel device (Chloe SED®) to administer paracervical block (PCB) during MVA in countries where pain medication is not typically given due to the high cost of the necessary tools. Methods: We conducted a single-blinded, randomized controlled non-inferiority trial including 61 patients at two hospitals in Kisumu, Kenya, to validate Chloe SED® for administration of PCB during MVA. PCB administered with Chloe SED® was compared to PCB administered with a standard spinal needle. Patients requiring MVA were block randomized in blocks of six, each provider completing six PCBs-three with the Chloe SED® and three with the standard spinal needle. The trial was registered with the Kenya Pharmacy and Poisons Board, ECCT/19/03/01 (https://ctr.pharmacyboardkenya.org/applications/index/protocol_no:RUNDVC8xOS8wMy8wMQ__/filter:/investigator:/sites:/pages:5/start_date:/end_date:/disease_condition:/users:/ercs:/stages). An intention-to-treat analysis was completed. The primary outcome was the non-inferiority of the pain score during uterine evacuation with a non-inferiority margin of 2 points on an 11-point numerical rating scale. Secondary outcomes included the non-inferiority of the pain score at four other time points and patient satisfaction. Results: Chloe SED® showed non-inferiority of the primary outcome with a mean pain score during evacuation of 3.8 [90% confidence interval (CI): 3.1-4.6] compared with the spinal needle at 4.1 (90% CI: 3.5-4.7). Non-inferiority of the pain score was shown at all time points. Most patients expressed a desire for the continued use of the device to administer PCB for MVA. No adverse events were noted. Conclusion: In summary, the Chloe SED® appears non-inferior to the spinal needle and desirable for the administration of PCB during MVA.

Design of a syringe extension device (Chloe SED®) for low-resource settings in sub-Saharan Africa: a circular economy approach.

Underfunded healthcare infrastructures in low-resource settings in sub-Saharan Africa have resulted in a lack of medical devices crucial to provide healthcare for all. A representative example of this scenario is medical devices to administer paracervical blocks during gynaecological procedures. Devices needed for this procedure are usually unavailable or expensive. Without these devices, providing paracervical blocks for women in need is impossible resulting in compromising the quality of care for women requiring gynaecological procedures such as loop electrosurgical excision, treatment of miscarriage, or incomplete abortion. In that perspective, interventions that can be integrated into the healthcare system in low-resource settings to provide women needing paracervical blocks remain urgent. Based on a context-specific approach while leveraging circular economy design principles, this research catalogues the development of a new medical device called Chloe SED® that can be used to support the provision of paracervical blocks. Chloe SED®, priced at US$ 1.5 per device when produced in polypropylene, US$ 10 in polyetheretherketone, and US$ 15 in aluminium, is attached to any 10-cc syringe in low-resource settings to provide paracervical blocks. The device is designed for durability, repairability, maintainability, upgradeability, and recyclability to address environmental sustainability issues in the healthcare domain. Achieving the design of Chloe SED® from a context-specific and circular economy approach revealed correlations between the material choice to manufacture the device, the device's initial cost, product durability and reuse cycle, reprocessing method and cost, and environmental impact. These correlations can be seen as interconnected conflicting or divergent trade-offs that need to be continually assessed to deliver a medical device that provides healthcare for all with limited environmental impact. The study findings are intended to be seen as efforts to make available medical devices to support women's access to reproductive health services.

Purification of regulatory T cells with the use of a fully enclosed high-speed microfluidic system.

BACKGROUND AIMS: Despite promising advances in cellular therapies, it will be difficult to fully test or implement new therapies until advances are made in the processes for cell preparation. This study describes the use of an advanced prototype of a flow-cytometry cell purification system constructed for operation in a clinical environment to prepare regulatory T cells defined as CD4(+)/CD25(bright)/CD127(neg/low). METHODS: The sort performance of the Gigasort system was directly compared with available droplet sorters using mixtures of highly fluorescent and non-fluorescent 5-µm polystyrene particles. CD4(+)-enriched cell preparations were processed with the use of a sterile, disposable fluid handling unit with a chip containing parallel microfluidic-based sorters. RESULTS: Similar purity and sort efficiency as found with droplet sorters were obtained with the 24-channel chip sorter system. Starting with 450 million fresh peripheral blood mononuclear cells, 150,000 to 1.7 million cells that were, on average, 85% FoxP3-positive and 97% viable, were obtained in <4 h. CONCLUSIONS: This study presents a technology adapted to regulatory requirements for clinical cell purification and that achieves high throughput and cell-friendly conditions by use of a microfluidic chip with 24 parallel microsorters, providing a rapid, sterile method of purifying regulatory T cells accurately and with excellent viability.