News Release

Positively charged nanomaterials treat obesity anywhere you want

Columbia researchers discover that the cationic charged P-G3 reduces fat at targeted locations by inhibiting the unhealthy lipid storage of enlarged fat cells

Peer-Reviewed Publication

Columbia University School of Engineering and Applied Science

Figure 1

image: Illustration of depot-specific targeting of fat by cationic nanomaterials view more 

Credit: Nicoletta Barolini/Columbia University

New York, NY—December 1, 2022—Researchers have long been working on how to treat obesity, a serious condition that can lead to hypertension, diabetes, chronic inflammation, and cardiovascular diseases. Studies have also revealed a strong correlation of obesity and cancer--recent data show that smoking, drinking alcohol, and obesity are the biggest contributors to cancer worldwide.

The development of fat cells, which are produced from a tiny fibroblast-like progenitor, not only activates the fat cells’ specific genes but also grows them by storing more lipids (adipocytes and adipose tissue). In fact, lipid storage is the defining function of a fat cell. But the storage of too much lipid can make fat cells unhealthy and lead to obesity.

Challenges in targeting fat cells

The ability to target fat cells and safely uncouple unhealthy fat formation from healthy fat metabolism would be the answer to many peoples’ prayers. A major challenge in obesity treatment is that fat tissue, which is not continuous in the body but is found piece by piece in “depots,” has been difficult to target in a depot-specific manner, pinpointed at the exact location.

There are two main kinds of fat: visceral fat, internal tissues that surround the stomach, liver, and intestines, and subcutaneous fat, found under the skin anywhere in the body. Visceral fat produces potbellies; subcutaneous fat can create chin jowls, arm fat, etc. To date, there has been no way to specifically treat visceral adipose tissue. And current treatments for subcutaneous fat like liposuction are invasive and destructive.

 New studies use cationic nanonmaterials to target fat

Two new studies from researchers at Columbia Engineering and Columbia University Irving Medical Center (CUIMC) may have the answer to targeting fat cells depot-specifically and healthily. The papers demonstrate a new method to treat obesity by using cationic nanomaterials that can target specific areas of fat and inhibit the unhealthy storage of enlarged fat cells. The materials remodel fat rather than destroying it, as, for example,  liposuction does. The first paper, published today by Nature Nanotechnology, focuses on visceral adiposity, or belly fat. The second paper, published online November 28 by Biomaterials, focuses on fat underneath the skin as well as chronic inflammation associated with obesity.

The team of researchers, led by Li Qiang, associate professor of pathology and cell biology at CUIMC,  and Kam Leong, Samuel Y. Sheng Professor of Biomedical Engineering and of systems biology at CUIMC, recognized that adipose tissue contains large amounts of negatively charged extracellular matrix (ECM) to hold fat cells. They thought that this negatively charged ECM network might provide a highway system of sorts for positively charged molecules. So they took a positively charged nanomaterial, PAMAM generation 3 (P-G3), and injected it into obese mice. The P-G3 quickly spread throughout the tissue and the team was excited that their method to specifically target visceral fat worked.

Unexpected results

And then something intriguing happened: P-G3 shut off the lipid storage program in fat cells and the mice lost weight. This was totally unexpected, given the well-established function of P-G3 in neutralizing negatively charged pathogens, such as DNA/RNA cell debris, to alleviate inflammation.

“Our approach is unique--It departs from the pharmacological or surgical approaches,” says Qiang, who specializes in obesity and adipocyte biology. “We used cationic charge to rejuvenate healthy fat cells, a technique no one has ever used to treat obesity. I think this novel strategy will open the door to healthier and safer reduction of fat.”

P-G3 helps new fat cell formation and also inhibits the unhealthy lipid storage of enlarged fat cells

In these two studies, the researchers discovered that the cationic material, P-G3, could do an intriguing thing to fat cells--while it helped new fat cell formation, it also uncoupled lipid storage from the housekeeping functions of fat cells. And because it inhibits the unhealthy lipid storage of enlarged fat cells, the mice had more metabolically healthy, young, small fat cells like those found in newborns and athletes. The researchers found that this uncoupling function of P-G3 also holds true in human fat biopsies, signifying the potential of translation in humans.

“With P-G3, fat cells can still be fat cells, but they can't grow up,” said Leong, a pioneer in using polycation to scavenge pathogens. “Our studies highlight an unexpected strategy to treat visceral adiposity and suggest a new direction of exploring cationic nanomaterials for treating metabolic diseases.”

New applications for drug delivery, gene therapy, and aesthetics

Now that they can selectively target visceral fat, Leong and Qiang envision several applications. The Biomaterials study demonstrates a simple approach that could be used for aesthetic purposes; like Botox, P-G3 can be locally injected into a specific, subcutaneous fat depot. The investigators, who have patents pending, are now engineering P-G3 into various derivatives to improve the efficacy, safety, and depot specificity.

What the researchers are particularly excited about is developing P-G3 into a platform that can deliver drugs and gene therapies specifically to a given fat depot. This may repurpose many drugs from systemic safety concerns, such as Thiazolidinediones (TZDs), a potent but unsafe drug that is a strong modulator of fat and used to treat type 2 diabetes—but it has been linked to heart failure and banned in several countries. 

“We’re very excited to discover that cationic charge is the secret to targeting adipose tissue,” Qiang said. “Now we can shrink fat in a depot-specific manner--anywhere we want--and in a safe way without destroying fat cells. This is a major advance in treating obesity.”


About the Study

Journal: Nature Nanotechnology 

The study is titled “Selective targeting of visceral adiposity by polycation nanomedicine.”

Authors are: Qianfen Wan1†, Baoding Huang7,2†, Tianyu Li2, Yang Xiao2, Ying He1, Wen Du3, Branden Z.    Wang1, Gregory F. Dakin4, Michael Rosenbaum3,5, Marcus D. Goncalves6, Shuibing Chen4, Kam W. Leong2, Li Qiang1

1Naomi Berrie Diabetes Center and Department of Pathology and Cell Biology, Columbia University 2Department of Biomedical Engineering, Columbia University

3Department of Medicine, Columbia University

4Department of Surgery, Weill Cornell Medicine  

5Department of Pediatrics, Columbia University

6 Department of Medicine, Department of Surgery, Weill Cornell Medicine

7Department of Orthopedic Surgery, The Sixth Affiliated Hospital, Sun Yat-Sen University  and Guangdong Provincial Key Laboratory of Orthopedics and Traumatology; Guangzhou, China 

This work was supported by Russell Berrie Foundation (L.Q. and Q.W.), Blavatnik SIRS funding (L.Q. and   K.W.L.), National Institutes of Health grant RO1AR073935 and the U.S. Army Medical Research grant W81XWH1910463 (K.W.L.), and The Manoogian Simone Foundation (M.D.G). 

A patent application is pending. All other authors declare no conflict of interest. 

Journal: Biomaterials

The study is titled “Polycationic PAMAM ameliorates obesity-associated chronic inflammation and focal adiposity.”

 Authors are: Baoding Huanga,b, Qianfen Wanc, Tianyu Lib, Calhoun Carmenc, Kam W. Leongb, and Li Qiangc

a Department of Orthopaedic Surgery, The Sixth Affiliated Hospital, Sun Yat-sen University and Guangdong Provincial Key Laboratory of Orthopaedics and Traumatology, Guangzhou, China

b Department of Biomedical Engineering, Columbia University

C Naomi Berrie Diabetes Center and Department of Pathology and Cell Biology, Columbia University

The study was supported by the Russell Berrie Foundation (L.Q. and Q.W.), Blavatnik SIRS funding (L.Q. and   K.W.L.), National Institutes of Health grant RO1AR073935 and the U.S. Army Medical Research grant W81XWH1910463 (K.W.L.).

The authors have patents pending. No other competing interests are declared.



Nature Nanotechnology paper:

DOI: 10.1038/s41565-022-01249-3

Biomaterials paper: 

DOI:  10.1016/j.biomaterials.2022.121850



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