Pr Eric E. GabisonOphthalmology · Cornea & refractive · Paris
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HomeCoursesCorneal transplantation › Endothelial grafts DMEK/DSAEK & regenerative
Course contents ▾
  1. Evolution & paradigm
  2. Applied anatomy
  3. Epidemiology 2026
  4. Taxonomy
  5. Tissue banks
  6. Immunology & rejection
  7. Penetrating KP
  8. Anterior lamellar
  9. Endothelial
  10. Regenerative turn
  11. Keratoprostheses
  12. Surface & limbus
  13. Complications & follow-up
  14. Special situations
  15. Perspectives & synthesis
Chapter 09

Endothelial keratoplasties (DSAEK · DMEK · PDEK)

The core of 2026 activity. They treat endothelial failure (Fuchs, bullous keratopathy) by replacing only the endothelium ± a thin support, through a small incision, with no corneal suture.

DSAEK / UT-DSAEK

A graft of endothelium + Descemet + a thin layer of posterior stroma (prepared with a microkeratome). The ultra-thin (UT-DSAEK) variant reduces thickness to approach the visual performance of DMEK. The stiffer graft is easier to manipulate: DSAEK retains an advantage in complex eyes (aphakia, altered iris, drainage tubes, unstable chamber) and for the surgeon on the learning curve. Limitation: the stromal interface caps visual recovery and induces a slight hyperopic shift; the main early complication is graft dislocation.

DMEK — the reference technique

Grafting of the Descemet membrane + endothelium only (~15-20 µm), with no stroma. It is the most anatomical reconstruction, offering the best visual acuity, the fastest recovery and the lowest rejection rate (~1-2%).

Operative sequence (landmarks)

  1. Descemetorhexis: removal of the recipient's diseased Descemet under air.
  2. Graft preparation/staining (trypan blue); it scrolls with the endothelium facing outward; asymmetric marking (F/S) for orientation.
  3. Injection into the anterior chamber via an injector (often preloaded), then controlled unfolding (tapping manoeuvres, air bubbles, fluid currents).
  4. Orientation check, centring, then gas-bubble tamponade (air or SF₆ ~20%) pressing the graft against the stroma during pump-dependent adhesion.
  5. Strict supine positioning postoperatively.

Complications

  • Partial graft detachment — the most frequent; corrected by re-bubbling (gas reinjection).
  • Primary failure (non-functioning graft, often orientation/handling related).
  • Pupillary block from the gas bubble, ocular hypertension, rejection (rare).

Variants & widening indications

DMEK now extends to eyes once deemed difficult (aphakic, vitrectomised, tube-carrying) thanks to preloaded tissue and adapted anchoring techniques. Shared-tissue approaches — hemi-DMEK, quarter-DMEK — aim to treat several recipients with a single graft, a direct answer to scarcity.

PDEK (pre-Descemet EK)

A variant using a type-1 big bubble to prepare a graft including the Dua layer + Descemet + endothelium. Slightly thicker and more robust than DMEK, the graft is more manageable while preserving excellent optical quality; it allows the use of young donors (more reproducible bubble), expanding the tissue pool.

Comparison of endothelial keratoplasties
CriterionDSAEK / UT-DSAEKDMEKPDEK
Grafted tissueEndo + Desc + post. stromaEndo + DescemetEndo + Desc + Dua
Final acuityGood (interface)ExcellentExcellent
RecoveryWeeks-monthsFastFast
RejectionLowVery low (~1-2%)Very low
HandlingEasyDemandingIntermediate
Best settingComplex eyeStandard caseYoung donor / robustness

▶ Watch the videos: endothelial grafts & Fuchs dystrophy (egabison.com)

Chapter 10 — the heart of 2026

The regenerative & graft-free turn

The conceptual break of the decade: instead of transplanting donor tissue, stimulate, inject or manufacture. Five directions converge, all driven by the global shortage and by corneal biology.

1 · DSO / DWEK ± ROCK inhibitors

In selected Fuchs patients (central guttata, preserved peripheral endothelium, peripheral density > ~1000 cells/mm²), only the diseased central Descemet is removed (Descemet stripping only) without a graft: healthy peripheral endothelial cells migrate and repopulate the centre. Adding a topical Rho-kinase inhibitor (ripasudil, netarsudil) accelerates corneal clearing and promotes cell migration/function — visual recovery is faster than with observation alone in published series.

A crucial caveat on outcome: left to itself, clearing after DSO is slow and unpredictable — highly variable timelines (from a few weeks to several months) and a non-negligible proportion of non-clearing. In practice, the procedure is only conceivable combined with a Rho-kinase inhibitor: it drives both the speed and the very probability of recolonisation. A "bare" DSO without ROCK-i exposes the patient to unpredictable and often disappointing recovery.

An important nuance: DSO is an alternative, not a guarantee. Cases show excellent clearing over several years, but also late failures (recurrent guttata, neo-Descemet), some leading secondarily to DMEK — a 10-year follow-up has documented this scenario. Patient selection and counselling about the limitations are decisive.

Clinical pearl — DSO selection

DSO only makes sense if the peripheral endothelial "reserve" can recolonise the centre. Localised central guttata + healthy periphery = good candidate; pancorneal involvement = poor candidate, go straight to DMEK.

Pitfall — the endothelial cost of a failed DSO

DSO is not a "consequence-free trial". Central recolonisation occurs at the expense of the peripheral endothelial capital — precisely the reserve on which the prognosis of a subsequent DMEK depends. If it fails, the salvage DMEK is therefore performed on an already-depleted periphery: lower baseline density, reduced functional margin, potentially compromised graft survival.

Practical consequence: DSO worsens the prognosis of the DMEK that might follow it. It should be presented to the patient as a gamble that, if it fails, may degrade plan B — not as a neutral, reversible step.

2 · Injectable endothelial cell therapy

The most disruptive innovation, born from the work of Shigeru Kinoshita (Kyoto). The principle: culture human corneal endothelial cells ex vivo (a single donor can thus treat dozens of recipients), then inject them into the anterior chamber with a ROCK inhibitor (Y-27632) and face-down positioning, with no graft at all.

  • Vyznova™ (neltependocel) — approved by the PMDA in Japan and commercially launched in September 2024 for bullous keratopathy: the world's first endothelial cell therapy to obtain regulatory authorisation.
  • AURN001 (neltependocel + Y-27632, Aurion Biotech) — US development: the phase 1/2 CLARA trial met all endpoints at 12 months, followed by treatment of the first patients in the pivotal phase 3 (ASTRA study) in spring 2026. Alcon took a majority stake in Aurion in 2025.

Potential impact: turning tissue-dependent graft surgery into a standardised injection procedure, largely freeing it from corneal scarcity and graft-handling constraints.

2026 marker — vesicles & local regenerative medicine

Beyond the cells themselves, research is exploring cell-derived products (secreted factors, extracellular vesicles from mesenchymal stem cells) as regenerative eye drops for the surface and stroma — a "graft-free, no-living-cell-implanted" route for corneal healing and certain surface diseases.

3 · 3D-bioprinted endothelium — Precise Bio (PB-001)

The most recent breakthrough on the endothelial side: instead of injecting a cell suspension, a living endothelial graft is 3D-bioprinted. PB-001 (Precise Bio) combines human corneal endothelial cells, biomaterials and robotic layer-by-layer bioprinting: a tissue that unrolls and adopts the corneal curvature, uniting the handling of DSAEK with the optical precision of DMEK, delivered pre-loaded on a standard injector.

World first: on 29 October 2025, a first patient (legally blind in the treated eye) received PB-001 at the Rambam Medical Center (Haifa) — the world's first transplant of a functional, cell-based, bioprinted corneal endothelium. Phase 1 trial (10-15 patients, corneal oedema from endothelial dysfunction), topline results expected in the second half of 2026.

Why it is a breakthrough

The endothelial graft no longer requires a deceased donor: it is manufactured on demand. Combined with injectable cell therapy, this points to a possible way out of the global corneal shortage for the leading indication (Fuchs, bullous keratopathy).

4 · Bioengineered acellular corneas

For the stroma, manufactured substitutes aim to replace donor tissue. The leader is BPCDX (bioengineered porcine construct, double crosslinked): a medical-grade type-I porcine collagen hydrogel, doubly crosslinked (chemical + photochemical), with no cells or viable biological material, classed as a class III medical device. It is implanted intrastromally by a minimally invasive technique without sutures or tissue removal, thickening and remodelling the recipient's cornea.

Pilot data (Nature Biotechnology, 2022: 20 advanced-keratoconus eyes, India/Iran, 24 months with no adverse event) were extended in 2026 by new series (e.g. a 17-eye study, stage 3-4 keratoconus, 12-month follow-up). The appeal is twofold: an answer to scarcity and access in resource-limited countries, where the graft shortage is most acute.

5 · Bioprinting, scaffolds & gene therapy

  • 3D / DLP bioprinting and bio-ink scaffolds (collagen, hyaluronic acid, silk…) to rebuild an organised stroma, and even limbal structures — active translational research.
  • Corneal gene therapy: allele-specific approaches and editing (CRISPR) for stromal dystrophies linked to the TGFBI/BIGH3 gene; correcting or silencing the mutant allele to prevent recurrence after grafting.
  • Corneal xenotransplantation (decellularised or genetically modified pig): a route explored to widen the tissue supply.

6 · CAIRS — the allogenic additive

For keratoconus, allogenic intrastromal ring segments (shaped human corneal tissue inserted into a stromal tunnel) remodel the surface with no synthetic material and no penetrating graft. They join the "additive" logic: nothing is removed or replaced, the cornea is reinforced and regularised. Planning (number, thickness, position of segments) relies on dedicated nomograms.

Chapter synthesis

In 2026, the endothelium can be regenerated (DSO/ROCK), reseeded by injection (cell therapy) or rebuilt by 3D bioprinting (Precise Bio); the stroma can be augmented (CAIRS) or replaced by a manufactured substitute (BPCDX). Purely synthetic solutions (the EndoArt® artificial endothelium, keratoprostheses) are covered in the next chapter. Donor-tissue grafting remains central, but it is no longer the only answer.