Why close the gender gap in engineering education?

I am a proud graduate of Biomedical Engineering at the University of Delaware. The program was in its infancy when I entered college, instantly empowering us to become pioneers in higher education. It exposed me to staggeringly brilliant people. It equipped me to dive my fists into bovine knee joints on a surprisingly regular basis. I appreciate that.

But if I could do it over, I would at least consider an alternative path—mechanical engineering with a concentration in biomedical applications—and one reason for that is Dr. Jenni Buckley. She is a MechE superstar, a household name in the College of Engineering, a person I look up to although we crossed paths by the narrowest of margins. Fortunately, guest lectures and chance encounters in Spencer Lab afforded me small doses of her jokey, genial personality.

Should I major in biomedical engineering or [insert other engineering major here]? is actually an excellent conversation for another day. I’m here to talk about Jenni Buckley’s TEDx talk on closing the gender gap in engineering: Designing for diversity.

Dr. Buckley raises a few points in this talk. To summarize:

  • The proportion of female college students in engineering has plateaued at ~20%. The proportion of females college students in STEM majors altogether continues to rise.
  • Most of that 20% is dispersed across environmental, chemical, and biomedical engineering (aka the “modern” disciplines).
  • 30% female enrollment is the target we should aim for. Otherwise known as the critical mass, this number is self-sustaining and promotes further growth.
  • Women are drawn to immediate societal impact – hence, the appeal of environmental, chemical, and biomedical prefixes.
  • Women display equal math literacy and equal college retention rate in engineering when compared to men. The bottleneck, simply put, is girls choosing other majors.
  • Pop culture has something to do with this.
  • Current outreach is not successfully increasing the proportion of women in engineering.

She concludes with a call to action. We must redesign the ways in which we attempt to close the gender gap. We must show girls that they can save the world via engineering (not just biomedical engineering, I would add) and that they do belong in these majors.

There are a few schools of thought on what to do with this information. Susan Pinker wrote in the WLS, “A key tenet of modern feminism is that women will have achieved equity only when they fill at least 50% of the positions once filled by men.” But we have all of this biology crap stating women are simply not interested in math and science or something like that (is it obvious where I stand?). Some say we can’t stop until we reach that goal of 50% while others suggest: we’ve come a long way…maybe it’s time to give it a rest. 

Here is where I actually stand. Maybe the biology crap isn’t crap. And maybe we don’t need ≥50% female enrollment in engineering. But the world needs more female design engineers for the same reason it needs more male nurses. Can you think of one product or service that affects only men or only women across the entire supply chain? Your profession has a huge impact on others. I don’t care if you are a server, an educator, a call center rep, a CEO, a janitor, a stay-at-home parent. Your voice is really really important.

I know this debate can get complicated. There are arguments to be made on the grounds of social justice, nature vs nurture, the gender wage gap, and so on. But isn’t diversity a big enough reason to, well, keep designing for diversity?


A low-cost auto-transfusion device by Sisu Global

Abell Foundation invests in Baltimore medical device maker
Image provided by Chiaki Kawajiri via Baltimore Sun

Hemafuse is a handheld, hand-operated device. It suctions blood from body cavities and filters said blood for re-transfusion in patients that are hemorrhaging (i.e. bleeding profusely). “Company leaders saw a need for such devices in hospitals, rural areas and conflict zones, where standard equipment is too expensive or unusable. It will begin sales in Africa,” the Baltimore Sun reports. Supposedly, soup ladles are the best available option in many situations. That’s right – soup ladles. A team of clinicians will spend ~30 min scooping out pooled blood from a body cavity using…soup ladles.


Immuno-modulation and Tissue Regeneration

When your immune system is fighting a cold, it makes itself known with stuffy noses, fevers, and coughs galore. Less conspicuously, it protects you when you bump your knee or scrape your arm (or worse). There is plenty of crosstalk between immunity and wound repair, indeed, and researchers are beginning to harness this relationship in various strategies for tissue regeneration. But in doing so, they are tasked with deconstructing the many convoluted mechanisms involved.

Neutrophils – “first responders” at the site of injury, if you will – are one of several immune factors that evoke positive and synergistic effects in wound repair. They work to stop pathogens in their tracks and recruit anti-inflammatory cells to the site. Monocytes and macrophages arrive soon after to clear out pathogens, dead cells, debris etc. while secreting molecules that move the healing process along. 

Some immune factors are known to inhibit tissue regeneration, on the other hand. Toll-like receptors and interleukin-1 receptors are involved in signaling pathways that reduce the quality of wound healing, particularly in cases of ischemia-reperfusion and bone regeneration. Still, there is evidence that such receptors are involved in pathways that directly or indirectly support repair processes at the same time.

So we know that mechanisms of immunity can serve as positive or negative forces in tissue regeneration – or both. To complicate matters further, they are influenced by age and organ type among other factors. Julier et al suggest, nonetheless, that “the next generation of regenerative therapies may evolve from typical biomaterial-, stem cell-, or growth factor-centric approaches to an immune-centric approach.”

Regenerative medicine aims to restore function in cells, tissues, and organs by sometimes elaborate means. Below are two immuno-modulatory strategies covered in Julier’s review article:

Physiochemical Properties of Implants

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Fig. 1

I am tempted to regard biomaterials as simply vehicles for therapy (e.g. cells, growth factors) and articles like this remind me otherwise. The implanted biomaterial contains powerful immune capabilities in and of itself. It consists of polymers with bonds, or cross-links, that link one polymer chain to another, and the degree at which this occurs impacts macrophage activity profoundly. For example, a higher cross-link density is known to elicit pro-inflammatory macrophages that secrete greater levels of cytokines. Surface chemistry certainly comes into play as well; hydrophobic, ionic surfaces are associated with more macrophages and less cytokines compared to hydrophilic, neutral counterparts. Figure 1 illustrates key physiochemical tools that can be modified at our disposal.

Extracellular Vesicles (EV)

EVs are little cargo bags released by cells for reasons that are as wide-ranging as they are innumerable. They are found in almost all cell types and all bodily fluids; traversing along the latter, they are “taken in” essentially by local or distant target cells. EVs from immune cells, in particular, are heavily speculated to be involved in the conversation between immunity and tissue healing by transporting critical immune factors to the site of injury. They can be loaded with exogenous agents and engineered to target specific cells for regeneration therapy. EV delivery methods are being explored, currently, ranging from intravenous injection to *ahem* biomaterial scaffolds.

Based on the aforementioned, incorporating the immune system into regenerative strategies is as exciting and inspiring as it is troubling. The concept isn’t entirely new, of course. The collection of evidence cited in this review article alone spans the better part of two decades. That being said, a suggested shift in therapeutic focus is avant-garde.

Google  “regenerative medicine therapies” and you’ll find tons of info on growth factors, cells that secrete them, progenitor cells of cells that secrete them, and – you guessed it – biomaterials. Modulating the immune system gets a special shout out here and there, and that could very well amplify as evidence accrues. I guess only time will tell.

“Promoting tissue regeneration by modulating the immune system” is a review article that was published in Acta Biomaterialia. For full access, click here.

Acoustic droplet ejection and its role in tailored cancer therapy

*Adapted from a grad school thing. Enjoy 🙂

1. Introduction

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Acoustic droplet ejection (ADE) is a technique wherein high-frequency sound waves are focused onto the surface of a fluid in order to eject droplets, as shown in Figure 1 [1]. The physics and technology governing this process have been active areas of research & development for nearly a century now. Motivation for ADE is driven by limitations with conventional methods when it is necessary to dispense small volumes of fluid with high fidelity. While ADE is especially effective at the milliliter and nanoliter scales, droplets as small as a picoliter may be produced with high precision and accuracy [2]. Only sound is required to transfer the liquid; this eliminates the cost of washing, replacing, and disposing of any solids that may regularly come into contact with the liquid such as pipette tips, pin tools, and ejection nozzles. Thus, due to favorable economical and operational conditions, ADE is suitable for a wide variety of applications.

In recent times, this field has made substantial contributions to the life sciences. The technology is gentle enough to transfer proteins, high molecular weight DNA, and live cells without damaging them [3]. Proteomics, cell-based assays, and drug discovery are just a few of many biomedical arenas that have benefited substantially from ADE. One application of interest is the development of tailored cancer therapy via ex vivo assessment of drug activity in patient tumor cells, which I describe later on.

Continue reading “Acoustic droplet ejection and its role in tailored cancer therapy”