Table 1.
Overview of injury models presented in the review.
| Organ | Model Organism | Injury Model | Type of Injury | Mechanism of Regeneration | Characteristics | References |
|---|---|---|---|---|---|---|
| Heart | Zebrafish | Ventricular resection | Surgical | Proliferation from pre-existing myocytes | - | [11] |
| Cryoinjury | Surgical | Proliferation from pre-existing myocytes | Clinically relevant to mammalian infarcts with massive cell death | [13] | ||
| Mouse | Ventricular resection | Surgical | Proliferation from pre-existing myocytes | Fully regenerates a functional myocardium in 1–2 months without scarring | [11,12] | |
| Myocardial infarction | Surgical | Proliferation from pre-existing myocytes | Left anterior descending coronary artery occluded with a nylon suture | [25] | ||
| Liver | Zebrafish | Partial hepatectomy | Surgical | Hepatocyte-driven | Clinically relevant | [26] |
| APAP overdose | Chemical | BEC-driven regeneration | Paracetamol overdose | [26] | ||
| Nitroreductase (NTR)-mediated ablation | Genetic/Chemical | Hepatocyte-driven BEC-driven regeneration |
Tg(fabp10a:CFP-NTR) | [27,28,29] | ||
| Mouse | CDE diet | Chemical | BEC-driven regeneration | Ethionine, a toxic analog of methionine, in association with choline deficiency, leads to hepatocyte death and liver inflammation | [30] | |
| Ctnnb1 hepatocyte KO | Genetic | BEC-driven regeneration | Represses hepatocyte proliferation—in combination with an injury model | [29] | ||
|
Mdm2 deletion (hepatocyte-specific) |
Genetic | BEC-driven regeneration | AhCreMdm2flox/floxInducible, repress hepatocyte proliferation | [30] | ||
| Beta cell/Pancreas | Zebrafish | NTR-mediated ablation | Genetic/Chemical | Beta cell proliferation;alpha cell transdifferentiation; Neogenesis from ductal progenitors |
Tg(ins:CFP-NTR) In cells expressing NTR, reduces non-toxic pro-drug into cytotoxic products causing targeted cell apoptosis |
[31,32,33,34] |
| Mouse | Pancreatic Duct Ligation (PDL) | Surgical | Neogenesis from ductal progenitors | Induces acinar cell death and acute inflammation without destruction of beta cells | [35,36,37] | |
| Streptozotocin (STZ) | Chemical | Beta cell proliferation; Neogenesis from ductal progenitors |
Toxic glucose analogue that enters into beta cells via the GLUT2 transporter causing their death | [31,38] | ||
| Diphtheria Toxin Analogue (DTA) | Genetic/Chemical | Alpha cell transdifferentiation (adult only) Delta cell transdifferentiation (neonatal only) |
Tg(RIP:DTR) The toxin enters in cells expressing the DTR and inhibits protein synthesis, leading to cell apoptosis. Here targeted in beta cells with the Rat Insulin Promoter (RIP). |
[39,40] | ||
| Spinal Cord | Zebrafish | Spinal cord transection | Surgical | Glial bridge | Complete cutting of the vertebral column | [41] |
| Mouse | Laminectomy and spinal cord hemisection | Surgical | - | Hemisection leading to complete paralysis of the ipsilateral limb | [42] | |
| Brain | Zebrafish | Stab-lesion assay | Surgical | Regeneration from radial cells | Injury in the telencephalon parenchyma | [43] |
| B42 mediated injury | Surgical/Chemical | Regeneration from radial cells | Alzheimer’s-disease-like | [44] | ||
| Mouse | AD-like model | Genetic | No regeneration | APP/PS1dE9 transgenic | [45] | |
| Retina | Zebrafish | Needle poke | Surgical | From Muller cells | - | [46] |
| Optic nerve lesion | Surgical | From Muller cells | - | [47] | ||
| Mouse | NMDA | Chemical | From Muller cells | - | [46,48] | |
| Excessive light | Surgical | From Muller cells | - | [46] | ||
| AD-like model | Genetic | No regeneration | APP/PS1dE9 transgenic | [45] |