The team used advanced imagining techniques to analyse breast tissue from more than 500 women aged 15 to 86 years old. The tissue included biopsies taken from women for non-cancer-related reasons.

Combining these images with details of the hormone receptors and immune cells present, as well as the tissue architecture, the researchers were able to map how breast tissue changes over time in unprecedented detail. Their findings point to reasons why breast cancer risk increases with age and why tumors in younger women differ biologically.

The author added: “Our map revealed that as women age, their breast tissue goes through major changes, with the most dramatic changes occurring at menopause. There are changes, too, during their twenties, possibly linked to pregnancy and childbirth, but these are far less pronounced.”

The map revealed that all types of cells become fewer in number and divide far less often. Milk-producing structures known as lobules shrink or disappear, while the ducts that that carry milk become relatively more common, with the supporting layer around them becoming thicker. Fat cells increase while blood vessels decrease.

Meanwhile, changes occur in the immune environment. Younger breasts have more B cells and active T cells, which helps them identify and kill cancer cells. As tissue ages, these types of cells decline in number, replaced by other types of immune cell that indicate a more inflammatory and potentially less protective immune environment. ScienceMission sciencenewshighlights.

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Scientists have created the most detailed map to date, comprised of over 3 million cells, showing how breast tissue changes as women age – including dramatic changes during menopause.

A novel synergistic drug combination (N + A) consisting of an NAD⁺ precursor (NMN) and an NAD⁺ consumption (CD38) inhibitor (API) promotes musculoskeletal regeneration in aging. Notably, increased NAD⁺ serves as a coenzyme for SIRT3, exerting a robust anti-senescence effect, thus promoting tri-lineage differentiation into chondrocytes, osteoblasts, and myocytes. Furthermore, oral administration of the N + A formulation modulated the intestinal microenvironment, promoting the gut microbiota-derived production of the metabolite PHS, thereby exerting indirect anti-aging effects in musculoskeletal disorders.

Osteoarthritis, a condition that causes pain and reduced mobility in joints such as the knees and fingers, is one of the most common joint disorders worldwide, particularly among aging populations. The disease is characterized by the gradual breakdown of cartilage, which normally cushions the bones within joints.

Despite its prevalence, current treatments for osteoarthritis mainly focus on alleviating pain rather than addressing the underlying cause of cartilage degeneration. Effective therapies that can halt or reverse cartilage damage remain limited.

A joint research team led by Dr. Chul-Ho Lee and Dr. Yong-Hoon Kim at the Laboratory Animal Resource Center of the Korea Research Institute of Bioscience and Biotechnology (KRIBB), in collaboration with Prof. JinHyun Kim at Chungnam National University Hospital, has identified a key protein, SHP (NR0B2), that plays a critical protective role in cartilage and may offer a new therapeutic strategy for osteoarthritis. The paper is published in the journal Nature Communications.