Japan’s Stem Cell Regulation in 2025: ASRM, PMD Act, and What Patients Can Realistically Expect

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Table of Contents

Why Japan Matters in Regenerative Medicine

Japan is widely regarded as one of the most structured and safety-focused jurisdictions for regenerative medicine. Rather than allowing stem cell therapies to evolve in a regulatory gray zone, Japan has developed a clear legal architecture built on two primary pillars.

Key Legal Pillars
• ASRM – Act on the Safety of Regenerative Medicine (2014)
• PMD Act – Pharmaceuticals and Medical Devices Act (amended 2014)

Together, these laws establish a dual system that distinguishes between:

Clinical Practice

What hospitals and clinics are permitted to do with cells in patients

Commercial Products

What companies can manufacture and market as approved therapies

The result is a system that is:

  • Highly regulated, with stringent safety standards
  • Limited in access, with relatively few fully approved regenerative products
  • Designed to support innovation, but only within clearly defined regulatory boundaries

Beyond the legal architecture itself, Japan’s approach is rooted in specific historical and policy concerns. In the early phase of global stem cell commercialization, regulators observed a rapid rise in clinics promoting unproven interventions for complex diseases such as neurodegenerative disorders, autoimmune conditions, and advanced cancers.

Rather than responding case by case, Japanese policymakers opted to build a dedicated framework that could distinguish rigorously designed regenerative medicine from opportunistic, poorly documented “stem cell” services. ASRM and the PMD Act were therefore conceived not only as technical regulations, but as a signal that regenerative medicine would be treated as a serious, long-term healthcare domain rather than a short-lived trend.

Core Legal Framework: ASRM and PMD Act

ASRM – Regulating Clinical Use of Cell Therapies

The Act on the Safety of Regenerative Medicine (ASRM) governs how regenerative treatments are provided in clinical settings, whether they are:

  • Conducted as formal clinical research, or
  • Offered as self-funded medical procedures outside of conventional insurance coverage.

1. Mandatory Regenerative Medicine Provision Plan

Any clinic or hospital wishing to provide a regenerative procedure must submit a Regenerative Medicine Provision Plan. This plan is reviewed by a certified ethics/scientific committee and then either approved by MHLW for high-risk (Class I) procedures or notified for Class II/III.

2. Risk-Based Classification (Class I–III)

Procedures are categorized into Class I–III based on clinical risk, type of cells, and degree of manipulation.
  • Class I covers high-risk therapies such as iPSC/ES or gene-modified cells.
  • Class II includes culture-expanded autologous or certain allogeneic MSC uses.
  • Class III applies to minimally manipulated autologous cells.

3. Facility and Process Requirements

Any substantial manipulation, including culture or expansion, must occur in a certified Cell Processing Center (CPC). These facilities must meet strict standards for sterility, environmental control, documentation, and qualified staffing.

4. Safety Monitoring and Reporting

Providers must track outcomes, monitor patient safety, and submit adverse event reports to MHLW/PMDA. Periodic reporting ensures continued compliance and oversight for all ASRM-regulated interventions.

In practice, ASRM ensures that even “private” stem cell treatments cannot be offered as informal or unregulated experimental services. They must be embedded within a documented, reviewed, and monitored plan.

PMD Act – Regulating Commercial Regenerative Products

The PMD Act regulates regenerative products as marketable medical products, analogous to pharmaceuticals and medical devices, with a specifically tailored category for:

  • Processed cells intended to repair, reconstruct, or regenerate human tissues and functions.

1. Standard Approval

Full marketing approval is granted only when a regenerative product demonstrates comprehensive evidence of quality, safety, and efficacy. This pathway reflects Japan’s highest regulatory threshold under the PMD Act.

2. Conditional and Time-Limited Approval

A hallmark of Japan’s regenerative medicine framework, this approval allows earlier patient access when there is probable efficacy and an acceptable safety profile—often supported by Phase II data.
  • Permits limited market entry prior to full Phase III evidence.
  • Requires extensive post-marketing studies, long-term follow-up, and real-world data collection.
  • Companies must demonstrate sustained clinical benefit within a defined period or risk losing approval.

3. GCTP Standards (Manufacturing Requirements)

Manufacturing must comply with Good Gene, Cellular, and Tissue-based Products Manufacturing Practice (GCTP)—Japan’s regulatory counterpart to GMP for regenerative medicine. These standards ensure consistency in:
  • Identity: Ensuring the correct cellular product is manufactured.
  • Purity: Minimizing contaminants and impurities.
  • Potency: Confirming the intended biological activity.
  • Sterility: Preventing microbial contamination.
  • Stability: Ensuring the product maintains quality throughout storage/transport.

ASRM and the PMD Act operate in parallel: A product may receive approval under the PMD Act, but it can only be used in clinical settings that also comply with ASRM and other relevant clinical practice regulations.

Who Actually Regulates: MHLW, PMDA, and Review Committees

In practice, Japan’s stem cell regulation is not driven by a single agency but by a coordinated network of authorities. Each body plays a distinct role in the life cycle of a regenerative therapy—from early clinical planning to commercial approval and long-term safety monitoring. Understanding how these institutions interact is essential for interpreting why access is tightly controlled, and why certain procedures can only be performed in specific settings.

1. MHLW (Ministry of Health, Labour and Welfare)

MHLW sets national health policy and is responsible for implementing the ASRM. It certifies ethics/scientific review committees, oversees safety reporting, and issues regulatory guidance that strongly shapes what clinics are allowed to provide under Japan’s regenerative medicine framework.
  • Implements ASRM across hospitals and clinics
  • Certifies review committees responsible for approving clinical plans
  • Oversees adverse event and safety reporting nationwide
  • Issues guidance that shapes clinical practice boundaries

2. PMDA (Pharmaceuticals and Medical Devices Agency)

PMDA reviews regenerative products under the PMD Act, evaluating safety, quality, and efficacy data. It inspects manufacturing facilities and manages Japan’s conditional approval and post-marketing surveillance systems.
  • Reviews commercial regenerative product submissions
  • Evaluates preclinical and clinical evidence
  • Inspects domestic and international manufacturing sites
  • Oversees conditional approval and post-market safety studies

3. Certified Review Boards / Committees

These independent ethics and scientific committees review clinical plans under ASRM. They verify risk classification, evaluate protocol design, and ensure patient protection measures are in place before treatments may begin.
  • Evaluate regenerative medicine plans submitted by clinics
  • Confirm Class I–III risk classification
  • Assess patient safety and ethical compliance
  • Monitor ongoing protocols approved under ASRM

Together, they form a multi-layered, documentation-driven system in which no significant regenerative procedure or product can proceed legally without passing through one or more regulatory gatekeepers.

MHLW — Ministry of Health, Labour and Welfare

Primary Role: National policy leadership & ASRM implementation

Key Responsibilities:
• Certifies review committees
• Approves Class I procedures
• Issues regulatory guidance
• Coordinates safety reporting

Oversight Focus: Clinical practice regulation

PMDA — Pharmaceuticals and Medical Devices Agency

Primary Role: Product review & PMD Act enforcement

Key Responsibilities:
• Evaluates product applications
• Inspects manufacturing facilities
• Manages conditional/time-limited approvals
• Conducts post-market surveillance

Oversight Focus: Commercial regenerative products

Certified Review Boards / Committees

Primary Role: Ethical & scientific protocol review

Key Responsibilities:
• Evaluate treatment plans
• Verify risk classification
• Monitor patient protection & consent
• Oversee approved ASRM plans

Oversight Focus: Independent ethical governance

Risk-Based Classification: What Class I–III Really Mean

Under ASRM, risk classification determines the intensity of regulatory oversight:

  • Class I – Highest Risk
    • iPSC/ES cell–derived products
    • Gene-modified cell therapies
    • High-risk allogeneic therapies or novel cell types
    • Require the strictest review, detailed preclinical safety data, and close MHLW oversight.
  • Class II – Medium Risk
    • Many autologous MSC therapies involving culture expansion
    • Certain allogeneic MSC uses in non-standard indications
    • Require Certified Review Board approval, notification to MHLW, and CPC-based manufacturing.
  • Class III – Lowest Risk
    • Minimally manipulated autologous cells and same-surgical-procedure uses
    • Lower documentation burden than Class I/II, but still require review and defined safety and quality controls.

ASRM Risk Classification System

Under Japan’s ASRM framework, regenerative medicine procedures are classified into three risk tiers. The higher the class, the greater the regulatory scrutiny, data requirements, and facility obligations.

Class I – Highest Risk

High-risk / Novel Cell Therapies

Includes highly innovative or high-risk products that require the strictest level of review and documentation.
Examples
  • iPSC/ES cell therapies
  • Gene-modified cell therapies
  • High-risk allogeneic therapies
Key Requirements
  • Special committee review
  • MHLW approval required
  • Detailed preclinical safety data
  • Extensive protocol documentation

Class II – Medium Risk

Culture-Expanded / Selected Allogeneic Uses

Covers many culture-expanded autologous MSC therapies and certain allogeneic applications in non-standard indications.
Examples
  • Culture-expanded autologous MSCs
  • Some allogeneic MSC indications
  • Other non-standard cell applications
Key Requirements
  • Certified Review Board approval
  • Notification to MHLW
  • CPC-based manufacturing
  • Standard safety monitoring

Class III – Lowest Risk

Minimally Manipulated Autologous Uses

Applies to lower-risk procedures using minimally manipulated autologous cells and same-surgical-procedure approaches.
Examples
  • Minimally manipulated autologous cells
  • Same-surgical-procedure uses
  • Low-risk somatic applications
Key Requirements
  • Review board approval
  • Simplified documentation
  • Basic quality controls
  • Reduced reporting burden

In practice, the same cell type can fall into different ASRM classes depending on how it is processed and used. A same-day autologous procedure involving minimal handling generally falls under Class III.

When those cells undergo culture expansion for non-standard indications, the intervention typically shifts to Class II, requiring greater documentation, controlled manufacturing conditions, and additional oversight.

If the cells are allogeneic or genetically modified, the same therapeutic concept may move into Class I. This illustrates that ASRM classification is influenced not only by cell origin, but also by processing complexity, intended use, and the risk profile associated with each step.

Approved Products: TEMCELL, Stemirac, HeartSheet Withdrawal and Others

Despite Japan’s reputation as a global frontrunner in regenerative medicine, the number of fully approved or currently active conditionally approved regenerative medical products remains small.

The 2024-2025 period has become a turning point, as two conditionally approved products—HeartSheet and Collategene—were withdrawn after failing to demonstrate sufficient efficacy during post-marketing surveillance. This shift marks a more stringent enforcement of Japan’s conditional and time-limited approval system.

Approved & Conditionally Approved Regenerative Products in Japan (Updated to late 2025)

The following table highlights regenerative products that have secured full or conditional approval in Japan.

ProductType & Indication2025 Regulatory StatusAccess & Coverage
TEMCELL (JCR Pharma)Allogeneic bone marrow–derived MSCs
Steroid-refractory acute GVHD		Full approvalNHI-covered; available nationwide.
Stemirac (Nipro)Autologous bone marrow–derived MSCs
Subacute spinal cord injury		Conditionally approvedLimited coverage; restricted access.
Autologous Cultured ChondrocytesCultured cartilage cells
Orthopedic cartilage repair		Fully approvedCoverage varies by indication.

Approved & Conditionally Approved Products in Japan

Key regenerative products with full or conditional marketing approval in Japan.

Product
TEMCELL (JCR Pharma)

Type & Indication
Allogeneic bone marrow–derived MSCs
Steroid-refractory acute GVHD

2025 Regulatory Status
Full approval

Access & Coverage
NHI-covered; available nationwide in transplant centers.

Product
Stemirac (Nipro)
Type & Indication
Autologous bone marrow–derived MSCs
Subacute spinal cord injury
2025 Regulatory Status
Conditionally approved
Access & Coverage
Limited coverage; access restricted to designated institutions.

Product
Autologous Cultured Chondrocytes
Type & Indication
Cultured cartilage cells
Orthopedic cartilage repair
2025 Regulatory Status
Fully approved
Access & Coverage
Coverage varies by indication; used in specialized orthopedic centers.

Withdrawn Regenerative Products: Evidence Gap Case Studies

Two regenerative products were withdrawn after insufficient confirmatory evidence. These cases illustrate
how Japan’s conditional approval pathway responds when clinical benefit is not demonstrated.

 

HeartSheet (Terumo) — Autologous skeletal myoblast sheet

Withdrawn (July 2024)

Withdrawn after failure to confirm efficacy in post-approval studies. Often referenced as an example of the
conditional approval pathway discontinuing products that do not demonstrate sufficient benefit.

 

Collategene (AnGes) — Plasmid HGF gene therapy

Withdrawn (June 2024)

Withdrawn after the sponsor chose not to pursue renewal due to insufficient confirmatory benefit—
demonstrating the higher evidentiary bar expected for gene-based regenerative interventions.

TEMCELL

Type: Allogeneic bone-marrow mesenchymal stem cell (MSC) product

Indication: Steroid-refractory acute graft-versus-host disease (aGVHD)

Status:

  • First granted conditional approval
  • Successfully converted to full approval after confirmatory data demonstrated safety and clinical benefit

Access:

  • Provided at hematopoietic stem cell transplant centers
  • Covered by Japan’s National Health Insurance (NHI) for approved indications

Why it matters:
TEMCELL remains the definitive example of how Japan’s conditional approval pathway should work—early access followed by rigorous real-world data that ultimately supports full authorization.

Stemirac

Type: Autologous bone-marrow–derived MSC therapy

Indication: Subacute spinal cord injury (AIS grades A–C)

Status (as of late 2025):

  • Conditionally approved in 2018 based on single-arm study
  • Seven-year conditional period ending December 2025
  • Expected to submit full approval application before deadline
  • Outcome pending PMDA review

Access:

  • Restricted to government-authorized hospitals
  • Costs typically borne out-of-pocket

Why it matters:
Stemirac now sits at a critical regulatory junction. The PMDA/MHLW must determine whether observational, non-controlled post-marketing data are sufficient for full approval—especially after the withdrawal of HeartSheet and Collategene. This decision will strongly influence the future viability of Japan’s single-arm-trial-based conditional approval model.

Other Regenerative Products and Recent Withdrawals

HeartSheet (Withdrawn 2024)
  • World’s first conditionally approved cell-sheet therapy (2015)
  • Failed to demonstrate confirmatory efficacy despite multiple extensions
  • Officially withdrawn July 2024
  • Becomes the first PMDA-approved regenerative product ever revoked
This was a pivotal moment demonstrating that conditional approval is not a regulatory shortcut—products must prove real-world benefit to remain on the market.
Collategene (Withdrawn 2024)
  • Plasmid-based HGF gene therapy for critical limb ischemia
  • Approved under conditional pathway in 2019
  • Sponsor withdrew its application for full approval in June 2024
  • Second major example of conditional approval not converting to full approval
Autologous Cultured Chondrocytes

Still fully approved for certain orthopedic indications. These therapies represent some of the earliest regenerative medical products authorized in Japan and continue to be used for cartilage regeneration in specialized orthopedic centers.

MSC and WJ-MSC Therapies: Where They Fit

Mesenchymal stem cells (MSCs) and Wharton’s Jelly–derived MSCs (WJ-MSCs) are important components of Japan’s regenerative medicine pipeline, but their use is carefully segmented:

Approved MSC Products

  • Examples: TEMCELL, Stemirac.
  • May only be used for approved indications.
  • Strict adherence to authorized protocols.
  • No off-label use allowed.

Investigational MSC Uses

Includes orthopedics, neurology, immunology:

  • Formal PMD Act clinical trials, or
  • ASRM-approved regenerative medicine plans.
  • Must be conducted in accredited institutions.

Allogeneic MSCs & WJ-MSCs

  • Higher-risk due to donor origin.
  • Require donor screening + CPC manufacturing.
  • Often Class I or high-end Class II.
  • As of 2025: No full-approval WJ-MSC products.

Manufacturing and Facility Standards: CPC and GCTP

A defining characteristic of Japan’s system is the tight regulation of cell manufacturing.

Cell Processing Centers (CPCs)

  • Any substantial manipulation (culture, expansion, or complex processing) must be performed in a certified CPC.
  • CPCs must demonstrate:
      • Appropriate cleanroom design and environmental controls
      • Validated processes and equipment
      • Robust documentation, traceability, and batch records
      • Qualified personnel and quality management systems

GCTP Compliance

  • For commercial products, manufacturing must comply with GCTP standards, which address identity, purity, potency, sterility, and stability.

These infrastructure and quality requirements significantly contribute to the higher cost of therapies in Japan but also to their comparatively high reliability when contrasted with offerings in less regulated environments.

Costs, Insurance, and Accessibility

Japan occupies a high-cost, high-compliance segment of the global stem cell market. Access is shaped by how therapies are funded, whether they are reimbursed under the National Health Insurance (NHI), and where services are physically concentrated.

Private, Self-Funded Therapies

  • Typically involve substantial out-of-pocket costs.
  • Pricing varies by cell type, protocol, number of administrations, and CPC-related expenses.
  • Generally not covered by NHI; patients pay directly.

Approved Products Under NHI

  • Examples include products such as TEMCELL.
  • Available to eligible Japanese residents meeting defined clinical criteria.
  • NHI coverage can substantially reduce individual financial burden.

Availability and Concentration of Services

  • Access is concentrated in major medical centers and specialized institutions in large cities.
  • Foreign patients face additional barriers: language, travel logistics, and eligibility screening.

Overall, Japan is not positioned as a low-cost “stem cell tourism” destination.

Enforcement, Advertising Restrictions, and Patient Protection

Japan actively enforces regulations in the regenerative medicine field to limit misleading or unsafe practices.

Key Regulatory Mechanisms

  • Mandatory approvals and notifications for ASRM plans
  • CPC certification and periodic inspections
  • Adverse event reporting to MHLW and PMDA
  • Strict advertising regulations under medical and consumer laws:
    • Prohibition of exaggerated cure claims
    • Ban on promoting unapproved indications
    • Mandatory disclosure for investigational or conditional therapies

Administrative Actions & Sanctions

  • Warnings and corrective orders
  • Suspension or revocation of treatment plans
  • Withdrawal of product authorization
  • Administrative penalties and — in severe cases — criminal sanctions

Overall, these enforcement mechanisms create a highly controlled environment for regenerative medicine in Japan, particularly in comparison with regions where advertising and treatment practices are less tightly regulated.

Key Regulatory Mechanisms

  • Mandatory approvals and notifications for ASRM plans
  • CPC certification and periodic inspections
  • Adverse event reporting to MHLW and PMDA
  • Strict advertising regulations under medical and consumer laws:
    • Prohibition of exaggerated cure claims
    • Ban on promoting unapproved indications
    • Mandatory disclosure for investigational or conditional therapies

Administrative Actions & Sanctions

  • Warnings and corrective orders
  • Suspension or revocation of treatment plans
  • Withdrawal of product authorization
  • Administrative penalties and — in severe cases — criminal sanctions

Strengths, Limitations, and Ideal Patient Profile

Strengths

  • High safety and manufacturing standards (CPCs and GCTP compliance)
  • Clear national legal framework (ASRM + PMD Act), reducing regional inconsistency
  • Structured innovation pathways via conditional approval and clinical trials
  • Active regulatory oversight, especially in safety and advertising practices

Limitations

  • Relatively few fully approved regenerative products compared with the field size
  • Limited clinical freedom; physicians must adhere to strict plan-based protocols
  • High treatment costs for self-funded interventions
  • Language and access barriers for non-Japanese speakers

Who Japan Is Best Suited For

Japan is generally most appropriate for:

  • Patients who are eligible for NHI-covered, fully approved products (e.g., aGVHD patients receiving TEMCELL), particularly residents.
  • Domestic or international patients with sufficient financial resources who:
    • Prioritize regulatory oversight and safety over cost,
    • Seek clearly defined, protocol-driven MSC or regenerative treatments under ASRM or within clinical trials, and
    • Understand that many potential uses of stem cells remain investigational rather than established standard care.
For individuals primarily seeking broad, low-cost, or highly speculative stem cell interventions, Japan is not a natural fit.

Outlook to 2030: Gradual Expansion, Not Deregulation

Japan’s regenerative medicine landscape is expected to expand gradually through 2030, driven by maturing clinical evidence rather than regulatory relaxation.

1. Growth in Approved Products

Steady increases in approved regenerative products are anticipated, particularly in immunology, orthopedics, and neurology, as more robust clinical data accumulates.

2. Advancement of iPSC and Gene-Edited Therapies

iPSC-derived and selectively gene-edited cell therapies may progress from early-phase studies toward conditional approvals as manufacturing and safety standards evolve.

3. Refinement of the Conditional Approval Framework

• Clearer criteria for conversion to full approval
• More structured post-marketing evidence requirements
• Greater predictability for developers

Japan’s Global Influence

Japan’s risk-based framework is increasingly referenced by jurisdictions seeking to regulate unproven stem cell clinics or accelerate access to advanced therapies. Its conditional approval outcomes—both successful conversions and debated cases—serve as case studies for policymakers designing their own pathways.

Overall, Japan’s trajectory points toward controlled innovation rather than deregulation, strengthening its role as a reference model for integrating regenerative medicine into a mature healthcare system.

Summary

By 2025, Japan has established one of the most structured and mature national frameworks for regenerative medicine worldwide—linking clinical governance, product oversight, and manufacturing standards into a unified system that prioritizes safety, traceability, and regulatory clarity.

Regulatory Snapshot: Core Pillars of Japan’s System

ASRM – Clinical Governance

Governs who may perform regenerative procedures through risk-based classification and mandatory plan review.

PMD Act – Marketed Products

Defines which cell and gene products may be marketed, including the conditional approval pathway and post-market evidence requirements.

CPC & GCTP – Manufacturing Standards

Ensures validated, quality-controlled, and traceable cell manufacturing and processing.

Costs & Accessibility

High costs and limited insurance coverage keep most interventions within specialized centers.

Regulatory Snapshot: Core Pillars of Japan’s System

ASRM – Clinical Governance

Governs who may perform regenerative procedures through risk-based classification, mandatory plan review, and institutional accreditation.

PMD Act – Marketed Products

Defines which cell and gene products may be marketed, including Japan’s
conditional approval pathway with required post-market evidence.

CPC & GCTP – Manufacturing Standards

Ensures validated, quality-controlled, and traceable cell manipulation
and manufacturing across clinical and commercial settings.

Costs & Accessibility

Costs and accessibility remain limiting factors, with most interventions
confined to specialized institutions and insurance coverage restricted to a few indications.

For stakeholders—including patients, clinicians, researchers, and industry—Japan offers:

  • A high-trust, high-barrier regulatory environment
  • Predictable governance across clinical, product, and manufacturing domains
  • Best suited to stakeholders who value structured, evidence-based access

Overall, Japan’s approach reflects a commitment to innovation tempered by rigorous oversight, positioning the country as a reference model for jurisdictions seeking to advance regenerative medicine within a mature and ethically grounded healthcare framework.

Scientific References

Official Government Sources

  • PMDA – Pharmaceuticals and Medical Devices Agency Link
  • MHLW – Ministry of Health, Labour and Welfare (Japan) Link
  • PMDA – Regenerative Medicine (ASRM / PMD Act Summaries) Link
  • PMDA – Review Reports: Regenerative Medical Products (incl. TEMCELL, Stemirac, HeartSheet, Collategene) Link
  • PMDA – Report on the Deliberation Results: TEMCELL Link
  • PMDA – Report on the Deliberation Results: HeartSheet (full approval rejected, July 24, 2024) Link

Academic & Peer-Reviewed Sources

  • Pursuing cell therapy approvals in APAC (ScienceDirect – 2025) Link
  • Revisions to the Act on the Safety of Regenerative Medicine in Japan (PMC) Link
  • New Governmental Regulatory System for Stem Cell-Based Therapies in Japan (ResearchGate) Link
  • Stem Cell Therapies: Ensuring Quality & Safety (NCBI) Link
  • Clinical Trials of Stem Cell Therapy in Japan (PMC) Link
  • Perspectives on Stem Cell-Based Regenerative Medicine (PMC) Link
  • Mesenchymal Stem Cells: Japan’s First Approved Cell Therapy (JSTAGE) Link
  • Stem Cell Therapy: Revolutionary Cure or Pandora’s Box? (StemCell Research & Therapy) Link

Media & Ethical Guidelines

  • Ethical Limits on Embryo Research – Nikkei Link

Disclaimer

This guide provides an overview of Japan’s stem cell regulatory framework as of December 2025 to help patients, clinicians, and researchers understand the current landscape. Individual medical decisions should be made in consultation with qualified healthcare providers who can assess your specific situation and verify current regulatory requirements.

Stem cell regulations evolve continuously. For the most current information, please refer to:

  • Ministry of Health, Labour and Welfare (MHLW) Japan
  • Pharmaceuticals and Medical Devices Agency (PMDA)
  • Certified medical institutions and review boards

We recommend verifying facility certification, practitioner credentials, product approval status, and clinical trial authorization before pursuing treatment.

Last Updated: December 2025