Peking University Third Hospital Reports 78.3% Measured Comfort Outcome with XIHE 9.4μm Far-Infrared Resonance Technology
2026-06-08 · 5 min read
78.3%
Measured Comfort Outcome
3 – 5 cm
Reported Emission Depth
8 weeks
Application Protocol
Study at a Glance
| Participants | Musculoskeletal discomfort cohort |
| Duration | 8 weeks |
| Technology | XIHE 9.4μm graphene FIR |
| Measured Comfort Outcome | 78.3% |
| Microcirculation Change | 64.9% |
| Follow-Up | 4 weeks |
| Institution | Peking University Third Hospital |
Background
Musculoskeletal discomfort affects a large global population. While various interventions exist, non-invasive physical modalities — particularly far-infrared technology — have drawn increasing research interest. However, most commercially available FIR devices lack precise wavelength control, limiting consistency across studies.
XIHE's technology addresses this variable through precision-engineered 9.4μm emission — a wavelength range at which research suggests cellular water molecules achieve strong absorption. This study was designed to evaluate the measured outcomes of this approach under controlled conditions.
Study Design
The study enrolled participants with musculoskeletal discomfort across lumbar, cervical, and knee regions. Participants received standardized XIHE graphene far-infrared application sessions over an 8-week protocol, with primary endpoints measuring Visual Analog Scale (VAS) comfort scores, microcirculation parameters, and functional mobility indices.
"The consistency of the 9.4μm wavelength delivery — session after session — was the key differentiator from conventional infrared devices we have tested previously."
Key Findings
Comfort Improvement: 78.3% of participants reported a meaningful change in VAS comfort scores (≥2 points). Results were sustained at 4-week follow-up, suggesting lasting physiological adaptation rather than transient effects.
Microcirculation: Capillary blood flow velocity was observed to change by 64.9% in application areas, as measured by laser Doppler flowmetry. This supports the proposed mechanism of far-infrared energy reaching deep tissue layers and interacting with microvasculature.
Functional Mobility: Participants demonstrated measurable improvement in range-of-motion and daily activity scores. The non-thermal nature of the resonance mechanism allowed for comfortable, extended sessions.
Research Significance
These findings contribute to the growing body of evidence on XIHE's 9.4μm graphene far-infrared technology as a validated, non-pharmaceutical comfort support technology suitable for integration into physiotherapy environments, recovery centers, and professional wellness programs. The data supports application as both a standalone comfort modality and alongside other wellness approaches.
The study is part of XIHE's broader research program, which now spans 18 SCI-indexed publications and 8 randomized controlled trials across multiple research domains.
References & Further Reading
Clinical Trial Protocol PKU-CT-2026-014 · Peking University Third Hospital, Department of Rehabilitation Medicine. Full study data and methodology available to clinical partners upon request. Request the complete trial report →
Related Research
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Read mechanism →Frequently Asked Research Questions
Does far-infrared resonance support circulation?
Research observations from this study reported measurable changes in microcirculation parameters, including capillary blood flow velocity.
Can far-infrared technology support recovery?
Study participants demonstrated improvements in comfort scores and functional mobility after an 8-week protocol.
What wavelength does XIHE technology use?
XIHE graphene modules emit within the 5–15μm far-infrared band with a peak emission at 9.4μm — a wavelength research suggests is readily absorbed by water-rich biological tissues.
Why is 9.4μm significant for biological research?
Research suggests that water molecules strongly absorb energy within this wavelength range, making it a focus of far-infrared biological resonance investigations.