Mark W. Grinstaff

Mark W. Grinstaff is the William Fairfield Warren Distinguished Professor and a Professor of Biomedical Engineering, Chemistry, Materials Science and Engineering and Medicine, at Boston University, Director of the National Institutes of Health's T32 Program in and Director of . is an interdisciplinary lab of scientists and engineers working on innovative projects. Grinstaff has developed new paradigms for translating rigorous academic research into practical applications, fostering intellectual advancement, economic growth, and enhanced clinical outcomes. His career is characterized by continuous exploration and innovation, with his discoveries influencing diverse research areas. Additionally, he is a co-founder of several companies and a co-inventor of several regulatory-approved drug and device products currently used in the clinic today.

Early life and education

Grinstaff was born on May 23, 1965, in Texas. He attended Redlands High School in Redlands, California, and was an Eagle Scout and Vigil member of the Order of the Arrow, Boy Scouts of America. Grinstaff completed his undergraduate studies at Occidental College. During his first year at Oxy, he worked at the hummingbird section of a museum while simultaneously studying the kinetics of Friedel-Crafts chloromethylation reactions in the laboratory of Franklin DeHaan. He later worked as a chemistry teaching assistant. During his junior year at Oxy, he decided to pursue chemistry over medicine. He obtained his Chemistry degree in 1987.
In 1992, Grinstaff earned his doctorate from the University of Illinois at Urbana–Champaign, under the mentorship of Kenneth S. Suslick. While at UIUC he studied sonochemistry and reported one of the first synthetic methods to metal nanoparticles. His focused on the use of sound waves to make amorphous iron and and . For his postdoctoral work, he joined Harry B. Gray's laboratory at the California Institute of Technology where he conducted research on electron transfer chemistry in proteins and the .

Research career

Grinstaff's interdisciplinary research bridges polymer chemistry, biology, engineering, and medicine. The research is based on a molecular-focused approach involving the development of innovative tools and reagents, and the investigation of natural and synthetic polymers.

2021 – today

RNA Therapeutics Engineering Era

Messenger ribonucleic acid therapeutics are at the forefront of modern medicine as delivery of this polynucleotide results in in vivo protein production via translation. Critical to this advance was the original discovery of the application of modified nucleosides to mRNA by Karikó and Weissman which revolutionized the field and enable clinical utility. Advanced RNA technologies such as self-amplifying RNA offer even greater promise of lower dose vaccines and protein replacement therapies. While saRNA shows promise in preclinical and clinical studies, it triggers a potent innate immune response which impedes its replication and protein expression and thereby restricts its therapeutic utility. Unfortunately, incorporation of modified nucleoside triphosphates in saRNA does not yield protein expression supporting the current decades-long understanding in the field that modified NTPs do not work in saRNA. Building off the unexpected discovery that other modified nucleotides do enable successful translation in saRNA, Grinstaff, in collaboration with Dr. Wilson Wong, reported significantly reduced innate immune response with substantial protein expression and duration.

Control of Metabolic Dysfunction

An international team of scientists led by Dr. Mark Grinstaff, Dr. Orian Shirihai, and Dr. Jialiu Zeng published the first report of the potential use acidic nanoparticles as a first-in-kind therapeutic for non-alcoholic fatty liver disease . NAFLD affects 20% to 30% of the world's population and no current treatments target the liver directly to counteract the disease of excess fat droplets in the liver. In NAFLD, lysosomes – small organelles in liver cells – responsible for eliminating excess fat do not function because of their poorly acidified level. Grinstaff investigated whether restoration of lysosomal function, by increasing its acidity to normal levels, recovers liver function and reduces the build-up of fat droplets in the liver. The lysosome targeting acidifying nanoparticles, termed as AcNPs, composed of fluorinated polyesters activate once in the lysosome to increase the acidity to healthy levels and restore autophagic flux, mitochondrial function, and insulin sensitivity – all key physiological indicators of liver function. In established high fat diet mouse models of NAFLD, re-acidification of lysosomes via AcNPs treatment returns liver function to lean, healthy levels with reversal of fasting hyperglycemia and hepatic steatosis. The ability to prepare new functional nanotechnologies which control cellular process is exciting and opens new areas of research.

2016–2021

Biodegradable Pressure Sensitive Adhesives

are materials that adhere to surfaces without requiring solvent, heat, or water activation. While widely used in products such as topical dressings and bandages, current PSAs are not applied internally within the human body. In clinical settings, PSAs could be useful for applications such as wound closure, drug delivery, tissue reinforcement, cell-embedded tissue scaffolds, and wearable medical devices due to their ability to join similar or dissimilar surfaces.
Research led by Mark Grinstaff has explored the development of degradable PSAs based on polyglycerol carbonates. These materials have been studied for their potential to restore tissue integrity and provide scaffolds for healing in a rapid and non-traumatic manner.

Research on Arthrofibrosis

, a condition affecting over 5% of the general population, is characterized by a painful reduction in joint range of motion due to the accumulation of fibrotic tissue. Existing treatments are limited in efficacy and do not address the underlying cause of collagenous tissue build-up within joints.
Grinstaff, in collaboration with Drs. Ara Nazarian and Edward Rodriguez, investigated the therapeutic potential of relaxin-2, a naturally occurring peptide hormone. Their research demonstrated that relaxin-2 administration restored joint range of motion and reduced capsular fibrosis in a murine model of shoulder arthrofibrosis.

Biosensors for Medical Applications

s are crucial tools for diagnostics and patient care but are often limited by the availability of molecular sensing components. In collaboration with Dr. Galagan, Grinstaff's research focused on mining bacterial systems for transcription factors and enzymes to create novel biosensors. These biosensors have been designed for detecting analytes such as hormones and addictive substances.

2012-2015

Development of New Polymers and Biomaterials

Poly-amido-saccharides

Grinstaff and collaborators synthesized poly-amido-saccharides, hybrid materials that combine the structural features of polysaccharides with defined molecular properties. Polysaccharides are diverse in molecular configuration, functionalization, linkage types, and degree of branching, and thus, are challenging synthetic targets. PASs are enantiopure polypeptide-polysaccharide hybrid materials with defined molecular weights and narrow dispersities synthesized using an anionic ring-opening polymerization of a β-lactam sugar monomer.

Glycerol-based polycarbonates

Grinstaff's team pioneered the synthesis of linear polycarbonates derived from glycerol. These polymers provide users the capabilities of well-known polymers like PLA or PLGA with the additional benefits of easily modifiable structure and non-acidic products upon biodegradation. He described the first synthesis of linear polycarbonates based solely on glycerol using a ring opening polymerization strategy. He also reported the first synthesis of atactic and isotactic linear polys via the ring-opening copolymerization of rac-/-benzyl glycidyl ether with CO₂ using complexes in high carbonate linkage selectivity and polymer/cyclic carbonate selectivity. These polymers have been applied in drug delivery and tissue engineering due to their biodegradability and structural flexibility. This research led to the development of drug-eluting buttress technologies for lung tumor prevention, which have undergone clinical translation through the start-up AcuityBio, later acquired by Cook Biotech Inc.

Superhydrophobic biomaterials

Grinstaff has also explored superhydrophobic materials for biomedical applications, including drug delivery devices and diagnostic tools. The commonality in the design of these biomaterials is to create a stable or metastable air state at the material surface, which lends itself to a number of unique properties. Grinstaff fabricated drug-loaded 3D meshes with varying surface tensions and introduced the concept of using surface tension as a new parameter to control drug release rates. In collaboration with Dr. Yolonda Colson, flexible drug-loaded buttresses, implanted at the resection margin, prevent lung tumor and extend survival in vivo. These materials utilize surface tension properties to control drug release rates and design sensors. For instance, a rapid sensor for measuring fat content in breast milk was developed to address nutritional challenges in low birth-weight infants.

2009–2012

Cartilage Imaging Agents

Grinstaff contributed to the development of imaging techniques for assessing articular cartilage, creating the first cationic X-ray computed tomography and magnetic resonance imaging contrast agents. These agents, such as CA4+, allow non-destructive, 3D imaging of cartilage glycosaminoglycan content, equilibrium modulus, and coefficient of friction. Research utilizing these agents has been conducted on various animal models and human cadaveric specimens. Collaborative work with Dr. has expanded this area, including advancements in two-color CT imaging, which are being applied in arthritis research and therapy evaluation.