|Received: 15 December 2017

Accepted: 18 December 2017

DOI 10.1002/btm2.10085

EDITORIAL

Introduction to Editorial Board Member: Professor Paula T. Hammond

In this issue of Bioengineering and Translational Medicine, we are pleased to introduce our Editorial Board Member, Professor Paula T. Hammond. Prof. Hammond is the David H. Koch Chair Professor of Engineering and the Head of the Department of Chemical Engineering at the Massachusetts Institute of Technology (MIT). Prof. Hammond received her BS degree from MIT in Chemical Engineering, her MS degree from the Georgia Institute of Technology, and her PhD degree from MIT.
Over the past two decades, Professor Hammond’s research has made deep and impactful contributions in the fields of synthetic polymers, nanomedicine, and materials assembly. Professor Hammond is a leader in the use of molecular interactions, which include electrostatic and hydrogen-bonding forces, to generate “layer-by-layer” deposited functional materials with highly controlled microscale and nanoscale structures on a broad range of surfaces as a means to create ordered

architecture.1–3 Her research has leveraged these nanoscale forces, inherent to many synthetic and natural materials, toward developing a range of new biochemical and electrochemical materials with synergistic functionality that are well beyond the capacity of individual materials.
Professor Hammond’s research draws on and extends concepts of thermodynamics and self-assembly in which the basis of the approach is the use of secondary, or nonspecific interactions, in combination with steric repulsion and electrostatic interactions, to direct the deposition of molecules and larger scale materials systems onto activated surfaces in a stepwise layer-by-layer approach. She has pioneered the development and application of this technology to generate controlled release thin film coatings for biomedical implants that address tissue regeneration,4 wound healing,5 and transdermal delivery from microneedle platforms,6 to nanoparticle drug carriers for drug, gene, and

FI G URE 1 Professor Hammond describing the spray layer-by-layer technology to President Barack Obama during the President’s visit to MIT on October 23, 2009 Source. MIT Spring 2010 Chemical Engineering Newsletter (http://web.mit.edu/cheme/alumni/newsletter/XCurrentsSpring10.pdf)
VC 2017 The Authors. Bioengineering & Translational Medicine is published by Wiley Periodicals, Inc. on behalf of The American Institute of Chemical Engineers This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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FI G URE 2 Group photo at the 15 year Hammond Lab reunion on June 4, 2011 Photo courtesy of the Hammond Group

siRNA delivery.7–9 Professor Hammond has also extended the applications of self-assembled materials to electrochemical energy devices,10 including photovoltaics11 and fuel cells.12
Another major research area in Professor Hammond’s group focuses on nanoscale self-assembly through the design of functionalized block copolymers. Block copolymers, which consist of two or more covalently bound polymer segments of different chemical composition, are known for their ability to microphase separate and organize into mesophase structures on nanometer length scales in the bulk state, and at surfaces and interfaces, based on chemical differences between blocks. Professor Hammond’s research has demonstrated the role of controlling the molecular architecture on the nanoscale in the ordering of block copolymer morphology, particularly for copolymer systems with asymmetric (irregular or nonlinear) blocks. Professor Hammond’s research has investigated the development and application of dendritic-linear block copolymers as nanoencapsulants for targeted drug delivery.13
Professor Hammond has led a remarkable career as a researcher and educator. Her research has been published in over 300 journal articles and book chapters, and has been heavily cited, with more than 21,000 citations. In recognition of these contributions to materials chemistry and nanomedicine, Prof. Hammond has been presented with numerous awards and honors. She has been elected to the National Academy of Engineering (2017), the National Academy of Medicine (2016), and the American Academy of Arts and Sciences (2013). She is an elected Fellow of the American Physical Society, the American Institute of Biological and Medical Engineers, and the American Chemical Society Polymer Division. She is the recipient of the AIChE Charles M. A. Stine Award (2013) in recognition of outstanding contributions to the field of materials science and engineering, and the Alpha Chi Sigma Award (2014) for Chemical Engineering Research. Professor Hammond has been featured numerous times in the top 100 cited materials scientists. In addition to research and teaching excellence, Prof. Hammond has had a deep interest for administrative leadership. At MIT, she co-founded the MIT Institute for Soldier Nanotechnology. She served as the Executive Officer of

the Chemical Engineering Department of MIT (2008–2011) and currently serves as the department chair.
Professor Hammond’s hallmark is her infectious enthusiasm and optimism, which are always inspiring and create a lasting impression. She is a champion of her students, always eager to engage and provide guidance, discuss research, and embrace new ideas. Professor Hammond has fostered an intellectually stimulating, open, positive, and collegial research environment in the laboratory and has been a role-model mentor, devoted teacher, and colleague to her many trainees. On their behalf, I express my admiration for her scientific contributions and appreciation for the opportunity to learn from her experience. We look forward to embracing and applying her values and pedagogy to our careers.
Nisarg J. Shah John A. Paulson School of Engineering and Applied Sciences,
Harvard University, Cambridge, MA 02138 Email: nisarg_shah@harvard.edu
LITERATURE CITED [1] Hammond PT. Building biomedical materials layer-by-layer. Materials
Today. 2012;15(5):196–206. [2] Hammond PT. Engineering materials layer-by-layer: Challenges and
opportunities in multilayer assembly. AIChE J. 2011;57(11):2928–2940. [3] Krogman KC, Lowery JL, Zacharia NS, Rutledge GC, Hammond PT.
Spraying asymmetry into functional membranes layer-by-layer. Nat Mater. 2009;8(6):512–518. [4] Shah NJ, Hyder MN, Quadir MA, et al. Adaptive growth factor delivery from a polyelectrolyte coating promotes synergistic bone tissue repair and reconstruction. Proc Natl Acad Sci. 2014;111(35): 12847–12852. [5] Castleberry SA, Almquist BD, Li W, et al. Self-assembled wound dressings silence MMP-9 and improve diabetic wound healing in vivo. Adv Mater. 2016;28(9):1809–1817.

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[6] DeMuth PC, Min Y, Huang B, et al. Polymer multilayer tattooing for enhanced DNA vaccination. Nat Mater. 2013;12(4):367
[7] Poon Z, Chang D, Zhao X, Hammond PT. Layer-by-layer nanoparticles with a pH-sheddable layer for in vivo targeting of tumor hypoxia. ACS Nano. 2011;5(6):4284–4292.
[8] Deng ZJ, Morton SW, Ben-Akiva E, Dreaden EC, Shopsowitz KE, Hammond PT. Layer-by-layer nanoparticles for systemic codelivery of an anticancer drug and siRNA for potential triple-negative breast cancer treatment. ACS Nano. 2013;7(11):9571–9584.
[9] Morton SW, Herlihy KP, Shopsowitz KE, et al. Scalable manufacture of built-to-order nanomedicine: Spray-assisted layer-by-layer functionalization of print nanoparticles. Adv Mater. 2013;25(34): 4707–4713.

[10] Lee SW, Kim B-S, Chen S, Shao-Horn Y, Hammond PT. Layer-bylayer assembly of all carbon nanotube ultrathin films for electrochemical applications. J Am Chem Soc. 2008;131(2):671–679.
[11] Argun AA, Ashcraft JN, Hammond PT. Highly conductive, methanol resistant polyelectrolyte multilayers. Adv Mater. 2008;20(8):1539–1543.
[12] Hyder MN, Lee SW, Cebeci FÇ, Schmidt DJ, Shao-Horn Y, Hammond PT. Layer-by-layer assembled polyaniline nanofiber/multiwall carbon nanotube thin film electrodes for high-power and highenergy storage applications. ACS Nano. 2011;5(11):8552–8561.
[13] Wood KC, Little SR, Langer R, Hammond PT. A family of hierarchically self-assembling linear-dendritic hybrid polymers for highly efficient targeted gene delivery. Angew Chem Int Ed Engl. 2005;44(41): 6704–6708.