Stress is more than a mental or emotional experience. It creates measurable physiological changes in the body, including shifts in hormone levels, inflammatory signaling, and cellular energy production. One of the most visible places this disruption can appear is in the hair growth cycle.

Periods of high stress are frequently associated with increased hair shedding and thinning. Understanding why this happens — and how cellular energy plays a role — is key to supporting healthier hair growth.

Does Stress Really Cause Hair Loss?

Chronic stress has been shown to disrupt the normal hair growth cycle. Elevated cortisol levels and stress mediators can push hair follicles prematurely from the growth phase (anagen) into the shedding phase (telogen).

Research demonstrates that stress signaling molecules such as corticotropin-releasing hormone (CRH) and Substance P (a neuropeptide also known as SP) can directly influence follicular cycling and inflammatory pathways.

Split image showing two close-up healthcare moments: on the left, a man examining his thinning hair with his hand; on the right, a person holding a hairbrush with visible hair shedding in their palm.

The Hair Growth Cycle: Why Energy Matters

Each follicle cycles through three primary phases: anagen (growth), catagen (transition), and telogen (resting/shedding). Hair growth is metabolically demanding and requires significant ATP production within the follicle’s mitochondria.

When mitochondrial energy production declines — whether from inflammation, stress, or reduced circulation — follicles may produce thinner hair shafts, shorten the anagen phase, or shed prematurely.

Illustration of the hair growth cycle showing five stages: anagen (growth phase), catagen (transition phase), telogen (resting phase), exogen (shedding phase), and early anagen (new growth phase), with cross-sectional views of hair follicles in the scalp.

What Is Photobiomodulation?

Photobiomodulation (PBM) is the scientific term for therapeutic red and near-infrared light therapy. Research has shown that specific wavelengths of red light are absorbed by cytochrome c oxidase within the mitochondria, increasing ATP production.

Increased ATP supports cellular repair, protein synthesis, and improved microcirculation — all of which are critical for healthy follicular function.

Red Light Therapy for Hair Growth: Clinical Evidence

Randomized controlled trials have demonstrated that low-level light therapy (LLLT) in the 630–660nm range can increase hair density and hair count in individuals with androgenetic alopecia.

These studies suggest that red light therapy supports follicles by increasing cellular energy availability, enhancing circulation, and modulating inflammatory processes.

Celluma Hair Mode: FDA-Cleared Promotion of Hair Growth

Celluma Hair Mode uses 640nm red light and is FDA-cleared for the promotion of hair growth. Treatments are administered every other day for 16 weeks, with each session lasting 30 minutes.

The device’s patented shape-taking design allows close proximity to the scalp, which is critical for therapeutic light delivery. Light intensity decreases with distance, following the inverse square law — making consistent and close proximity important for effective energy absorption.

Two people are using the Celluma Restore on the scalp to support hair thinning concerns.

Supporting the Scalp Environment

Healthy hair growth also depends on a well-supported scalp environment. Factors such as hydration, barrier integrity, and microcirculation influence follicular resilience.

When combined with supportive topical care such as RESTORE Hair Serum, light-based follicular stimulation can be paired with scalp-focused conditioning to promote overall scalp wellness.

Stress can disupt the hair growth cycle and influence follicular energy production. Photobiomodulation provides a research-supported approach to increasing mitochondrial ATP production and supporting the biological processes required for hair growth.

Celluma's Hair Mode is FDA-cleared for the promotion of hair growth and is designed around clinically studied optical parameters. When used consistently and as directed, it offers a non-invasive, drug-free option to support fuller-looking, healthier hair.

Selected Scientific References

Arck, P.C. et al. (2003). Stress inhibits hair growth in mice by induction of premature catagen development. FASEB Journal. https://doi.org/10.1096/fj.02-0869com

Peters, E.M.J. et al. (2006). Stress and the hair follicle: Exploring the connections. American Journal of Pathology. https://doi.org/10.2353/ajpath.2006.060323Peters

Karu, T.I. (1999). Primary and secondary mechanisms of action of visible to near-IR radiation on cells. Journal of Photochemistry and Photobiology B. https://doi.org/10.1016/S1011-1344(98)00219-X

de Freitas, L.F., & Hamblin, M.R. (2016). Proposed mechanisms of photobiomodulation. IEEE Journal of Selected Topics in Quantum Electronics. https://doi.org/10.1109/JSTQE.2016.2561201

Lanzafame, R.J. et al. (2013). The growth of human scalp hair mediated by visible red light. Lasers in Surgery and Medicine. https://doi.org/10.1002/lsm.22173

Jimenez, J.J. et al. (2014). Efficacy and safety of a low-level laser device in the treatment of hair loss. American Journal of Clinical Dermatology. https://doi.org/10.1007/s40257-014-0086-7

Avci, P. et al. (2014). Low-level laser therapy in the treatment of hair loss. Lasers in Surgery and Medicine. https://doi.org/10.1002/lsm.22170

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