Lecture Summaries

This session will explore the encapsulation strategies being used for creating single-injection vaccines. One key challenge in vaccination efficacy and compliance is the need for multiple doses given months apart. While this is not necessarily a major issue in the developed world, it is a major logistical problem in the developing world—where nearly all vaccine-preventable deaths occur. The two papers this week discuss strategies for encapsulating vaccines in materials that degrade over time and release their contents over time in an effort to elicit the same level of immune response generated by current multi-dose vaccination regimens after just one injection.

The first manuscript introduces the concept of using polymers to control the release of vaccines over time to eliminate the need for multiple injections administered over the course of months. The second paper describes how natural materials might be able to enhance immunogenicity but present other manufacturing challenges. Key points of discussion will include biodegradation mechanisms, natural versus synthetic materials, microparticle formulation, release kinetics, protein stability, and humoral immunity.

Leveraging the specificity of the immune system to combat cancer has recently garnered intense interest in both academia and industry. One strategy involves priming the immune system with tumor-specific peptides that will then seek out cancer cells, identify them as foreign, and kill them. Another popular strategy is called chimeric antigen receptors (CAR-T therapy), which involves the isolation of a patient’s T cells from blood, genetic modification to introduce a cancer-targeting receptor, and re-infusion of those modified cells resulting in cancer cell death.

This paper describes a nanoparticle that targets lymph nodes to improve the immunogenicity of cancer vaccines through non-specific (size-based) and specific (receptor-based) targeting strategies.

Inexpensive, rapid, and early diagnosis of infectious diseases is an urgent unmet need with numerous applications from public health to clinical diagnostics. More than 90% of deaths due to infectious diseases such as acquired immune deficiency syndrome (AIDS), malaria, and tuberculosis (TB) are reported to occur in developing countries, particularly in Sub Saharan Africa. Therefore, the demand for low cost and easy to use diagnostic tools are very clear. Microfluidics technology offers wonderful solutions for development of this kind of device.

In this session we review two papers focusing on development of low cost and portable diagnostic tools for detection of HIV and blood stream infection. The first paper by Kang et al presents a new technology capable of selectively detecting bacteria directly from milliliters of diluted blood at single-cell sensitivity. Their process has only one-step and is culture- and amplification-free with the process time around 1.5–4 h. In the second paper, Shafiee et al for the first time demonstrate development of a label-free electrical sensing chip that can detect lysed viruses through impedance analysis.

This session is dedicated to a visit to Sigilon Therapeutics, a Cambridge-based biotechnology company that has developed a super-biocompatible chemistry (Afibromer™) that allows encapsulated cells to avoid a strong foreign body reaction and immune rejection that would otherwise cause them to die. Many patients can benefit from cell-based therapeutics, but fibrosis has presented a barrier to the success of encapsulated cell-based approaches. Using this material, Siglion is developing Living Therapeutics™, in which cells programmed to secrete therapeutic compounds are encapsulated in Afibromer and serve as long-term internal “drug factories” for disease correction. Sigilon’s technology provides a unique, controllable, and dose-adjustable approach to continuously deliver protein therapeutics.

The goal of this visit is to put the technology described in the second paper of Session 5 into a direct therapeutic and commercial context and indicate some differences between academic research and industrial development. This experience will include a tour of the lab and a presentation by a Sigilon employee describing the history of the technology, founding of the company, recent growth, product strategy, and regulatory hurdles to commercialization.  

Cancer, if detected early, before it has the chance to spread in the body, is more likely to be treated successfully. In the late stages treatment becomes more difficult or impossible. Microfluidics technology has the potential to provide noninvasive, inexpensive, and informative clinical diagnosis of cancer. Two papers will be discussed in this session.

First we will review work by Fan et al, in which they report an integrated microfluidic chip, capable of sampling a large panel of protein biomarkers over broad concentration ranges, within a short time (10 min) of sample collection. This diagnostic tool uses only a drop of blood from a finger prick.

The second paper is about a new method for isolation of circulation tumor cells (CTCs). These are cells from a primary tumor that have entered into the vascular or lymphatic systems and are circulated in the body by the blood stream. Isolation and counting of CTCs from blood is a method for cancer diagnostics and also important for monitoring patient treatment. To purify and identify CTCs, protocols based on affinity to cell-surface markers have been used. However, these chemical-based techniques have not been very efficient because of variability of cell biomarker expression associated with tumor heterogeneity and cross-reactivity of antibody probes. This paper reports a label free high-throughput microfluidic chip to isolate, count, and characterize the biophysical properties of CTCs.

The delivery of macromolecules such as RNA and DNA has numerous therapeutic applications. However, the intracellular delivery of these materials is a very challenging task, since existing vector-based and current viral repurposing and physical methods have limitations, including decreased efficacy over time and cellular toxicity.

In this session, we will review two papers describing strategies to transport genetic materials into cells. The first paper by Sharei at al. describes a microfluidic platform for delivery in which cells are deformed mechanically when they pass through a constriction smaller than the cell diameter. The resulting shear forces transient holes in cell membranes and facilitates the transfer of material from the surrounding buffer into the cytosol. The second paper describes the design of lipid nanoparticles to optimize lymph node targeting to promote a strong T cell response against cancer cells.