Safety Assessment of Stem Cell-Based Therapies: Current Standards and Advancing Frameworks

Toxicity studies are primarily aimed at determining the relationship between drug exposure and adverse effects, usually taking structural tissue changes at post-mortem examination as the primary endpoint. Accordingly, a key goal of toxicity studies is to determine the maximum tolerated dose of a drug for single and repeated administration. For preclinical toxicity assessment, it is advisable to study both acute and chronic toxicity. The evaluation process involves multiple layers of investigation, starting with in vivo studies that require careful monitoring of various physiological parameters. Special attention should be given to evaluating mortality rates, as they provide critical insights into the acute and chronic effects of cell transplantation [34]. In addition to behavioral and physiological examinations, comprehensive laboratory testing is essential. Blood and urine tests play a pivotal role in toxicity evaluation, providing valuable information about organ function and systemic responses. Key blood parameters that are routinely monitored include a complete blood count with differential, biochemical parameters: albumin, aspartate aminotransferase, alanine aminotransferase, alkaline phosphatase levels indicating liver metabolism, blood urea nitrogen and creatinine assessing kidney function, electrolyte balance measuring calcium, sodium, potassium and phosphate levels, metabolic markers including lipid profile (cholesterol, lipoproteins, triglycerides) and glucose [35,36].

The pathophysiological analysis forms another critical component of toxicity analysis. This involves both macroscopic and microscopic examination of tissues to identify any structural or functional abnormalities. Multi-organ toxicity assessment includes histopathological examination of all major organ systems, with particular attention paid to organs in which cellular accumulation of the drug is observed based on biodistribution studies. Standardized toxicity scoring systems ensure that adverse events are consistently evaluated across studies [37]. Histological examination of tissue samples at the transplantation site is necessary to assess cell death, immune cell infiltration, and other pathological signs. It is also useful to perform a histological examination of the liver, lungs and kidneys, regardless of the location of the transplanted cells. The choice of animal models and experimental design should reflect the intended clinical application of the cellular product to ensure relevance and reliability of the results [38,39]. The assessment of immunotoxicity includes the evaluation of both intended and unintended effects on immune system function, including cytokine profiles, lymphocyte subset analysis, and functional immune tests. This analysis is particularly important for cellular products with immunomodulatory properties [40].

The overall clinical condition of the animals must be meticulously documented, including detailed observations of weight changes, behavioral patterns, and appetite. These parameters serve as early indicators of potential adverse reactions to the cellular product [41]. All analytical methods employed in cell therapy biosafety assessment must undergo rigorous validation according to International Conference on Harmonisation (ICH) guidelines. Validation parameters include accuracy, precision, linearity, range, specificity, and robustness. For cell-specific assays, additional considerations include matrix effects from biological specimens and stability of cellular analytes under various storage and processing conditions [42]. Thus, in the study of a cell preparation containing human regulatory macrophages (Mreg_UKR), detailed clinical, pharmacokinetic, pharmacological and toxicological tests were carried out on mice with immunodeficiency (NMRI-nude), during which the biosafety of Mreg_UKR therapy was demonstrated. Simultaneously, the authors underscore the heightened significance of clinical studies in evaluating the biosafety of cell therapy [43]. Assessment of neurological toxicity requires specific protocols, especially for cellular products administered intrathecally or intracerebrally. Neurological examination, histopathological examination of brain and spinal cord tissue, and examination of cerebrospinal fluid parameters provide a comprehensive analysis of neurological biosafety [44]. In a clinical trial of immunoablative autologous hematopoietic stem cell transplantation (IAHSCT) in multiple sclerosis, evidence of transient central nervous system (CNS) toxicity was found immediately following IAHSCT [45].

An assessment of reproductive toxicity may be warranted for some cell therapy products, particularly those with the potential to spread to germ cells or to exert hormonal effects. Histopathological examination of reproductive organs and analysis of reproductive parameters provide a comprehensive biosafety profile [44,46]. These studies evaluate both male and female fertility and developmental effects from conception through adulthood, using various guidelines such as the Organization for Economic Co-operation and Development's (OECD's) Extended One-Generation Reproductive Toxicity Study (EOGRTS) [47]. In a study of reproductive biosafety of therapy with human umbilical cord mesenchymal stem cells (UC-MSCs) in Sprague-Dawley rats. Assessments made included mortality, clinical observations, body weight, food consumption, fertility parameters of male and female, litter, and fetus parameters. It was shown that very high doses of the drug led to a number of undesirable effects, while no negative impact on the offspring was shown [48].

In contrast, biosafety pharmacology studies aim to predict the likelihood that a drug will be unsafe when administered to patients at therapeutic doses and thus aim to prevent such events. As part of this task, biosafety pharmacology studies aim to predict the possible occurrence of rare adverse effects [49].

Safety pharmacology panels for cardiovascular, respiratory, and neurologic systems play a crucial role in assessing drug safety during the development process [50]. The cardiovascular safety panel includes core measurements of hemodynamic parameters, including blood pressure, heart rate variability, electrocardiography (ECG) analysis, and cardiac contractility. Triggers for expanding these evaluations include abnormal ECG findings, significant blood pressure changes, arrhythmias detection, changes in heart rate, and evidence of cardiac stress [51].

The respiratory safety panel focuses on pulmonary function tests, including respiratory rate monitoring, lung volume measurements, airway resistance assessment, and gas exchange evaluation. Expansion of these analyses is triggered by respiratory rate abnormalities, changes in lung compliance, signs of bronchoconstriction, hypoxia detection, and respiratory distress symptoms [52].

The neurologic safety panel evaluates neurologic function through motor activity monitoring, sensory function assessment, cognitive performance tests, and behavioral observations. The necessity for comprehensive neurological examinations arises in cases of altered motor function, changes in sensory perception, cognitive impairments, behavioral abnormalities, and seizure activity detection [53].

Integrated safety monitoring involves common triggers for expanded evaluation, such as unexpected adverse reactions, dose-dependent effects, species-specific responses, and clinical relevance indicators [50].

The incorporation of these diverse evaluation methods provides a comprehensive understanding of cellular product biosafety. By combining general toxicity and safety pharmacology analyses, researchers can develop a holistic view of potential risks and benefits associated with cell-based therapies.

Oncogenicity refers to the malignant transformation of recipient cells under the influence of donor cells [54]. Oncogenicity studies are designed to evaluate the capacity of cellular drug components to induce tumor transformation in recipient cells and tissues [55]. This comprehensive analysis assesses the potential risk of oncological disease development associated with cell therapy. Stem cell–derived extracellular vesicles (EVs) can deliver miRNAs, lncRNAs, mRNAs, and proteins to recipient cells, reprogramming gene expression toward oncogenic pathways, and drug resistance [56]. EVs from adipose-derived MSCs carrying lncRNA NEAT1 enhanced proliferation, migration, and gemcitabine resistance in pancreatic cancer models by modulating the miR-491-5p/Snail/SOCS3 axis, illustrating a direct, transferable oncogenic mechanism [57]. Reciprocal paracrine loops between stem cells and epithelial cells can activate β-catenin and inflammatory prostaglandin pathways, driving epithelial–mesenchymal transition and generating a cancer stem cell–like niche in surrounding tissues [58]. Disease-modified stromal contexts can skew this paracrine output toward pro-tumorigenic signaling (for example, IL-6/JAK–STAT3 activation in epithelial cells), thereby supporting metastatic traits and therapy resistance [59]. Importantly, any cell-based therapeutic product that lacks proper oncogenicity evaluation is considered potentially oncogenic [41]. Despite advancements in vitro testing, laboratory animals remain a crucial component of oncogenicity research. Similar to tumorigenicity studies, immunocompromised animals are the preferred models. However, according to the FDA, the microenvironment significantly influences tumor development. Therefore, it is recommended to administer cells via the intended route of administration for the target cellular product, rather than relying solely on subcutaneous testing. Histological analysis is typically employed to evaluate results [60]. The duration of post-administration observation in experimental animals is critical for assessing long-term consequences and potential tumor development risks in recipients [55]. In vivo research evaluated the biosafety of UC-MSCs for traumatic brain injury (TBI) therapy and found low tumorigenic potential. Tumor formation was assessed by immunohistochemistry for epidermal growth factor receptor (EGFR) variant III, a glioma-associated EGFR mutation, which was not detected in transplanted cells. Proliferation was examined via proliferating cell nuclear antigen (PCNA), showing no significant UC-MSC proliferation over 12 months, although TBI increased proliferation of neighboring neuroblasts [7]. Emerging technologies offer alternative approaches to oncogenicity assessment. Notably, microfluidic chips—or "organs-on-chips" containing patient-derived cells—show promise for in vitro oncogenicity evaluation. This approach could enable tumor formation and metastasis analysis using patient-specific cells without animal testing. However, this technology remains under development and has not yet been widely implemented in preclinical research [60].

Tumorigenicity describes the ability of transplanted cells to form tumors [61]. Literature sources emphasize the importance of conducting tumorigenicity studies for therapeutic agents containing stem cells, low-dose cells with high differentiation potential, and cells exposed to various chemical and physical modifications [62]. It has been hypothesized that the risk of stem cell tumor formation is largely due to the persistence of undifferentiated populations, since injection of undifferentiated embryonic stem cells typically results in teratoma formation. Particular attention should be paid to cells producing mitogenic and immunomodulatory factors [63]. Tumorigenicity evaluation helps determine the ability of transplanted cells to form tumors. This aspect is especially critical when working with stem cells due to their high proliferative activity [60]. At the preclinical stage, various methods are used to determine tumorigenicity, with the most reliable approach involving subcutaneous administration of cellular products to immunocompromised animals, such as athymic nude mice or rats, animals with suppressed immunity receiving drugs like cyclosporine, azathioprine, imuran, and cyclophosphamide, as well as mice with severe combined immunodeficiency (SCID) [64]. The analysis of tumor development dynamics includes monitoring the latency period of tumor growth, evaluating the frequency of tumor occurrence, measuring tumor volume and mass, assessing the presence of invasive growth and metastases, analyzing the proliferative activity of cells, and evaluating their ability to grow uncontrollably [65]. The observation period is subject to variation. However, the majority of researchers have monitored tumor growth in animals for 10–40 weeks, while the FDA recommends monitoring tumor formation in vivo for 4–7 months [64,66]. Preclinical safety studies of human embryonic stem cell–derived retinal pigment epithelial cells (hESC-RPE) for the treatment of age-related macular degeneration showed absence of malignant growth and migratory properties of subcutaneous injection of transplant in immunocompromised NOG mice and subretinal injections into albino rabbit eyes [67].

Teratogenicity represents a specific indicator related to the formation of teratomas, which are particularly characteristic of pluripotent stem cells: iPSCs and embryonic stem cells (ESCs). These teratomas are identified through the presence of immature tissue derived from the three primary germ layers: ectoderm, mesoderm, and endoderm. Histopathological analysis serves as the primary method for their detection. The assessment of teratogenicity is predominantly conducted when the target cell product originates from the pluripotent stem cells derivatives [68]. An indirect method for confirming the absence of pluripotent cells in the target product involves evaluating pluripotency markers, including octamer-binding transcription factor 3/4 (OCT3/4), SRY-box transcription factor 2 (SOX2), homeobox protein NANOG (NANOG), Krüppel-like factor 4 (KLF4), tumor rejection antigen 1-60 (TRA-1-60), tumor rejection antigen 1-81 (TRA-1-81), and stage-specific embryonic antigen-4 (SSEA-4) [69,70]. However, the classical in vivo teratoma formation test remains the only definitive method for analyzing the presence of residual pluripotent cells in the cell product. The analysis is typically performed using immunocompromised animals, with various administration routes employed, including subcutaneous, intramuscular, and direct organ injection into tissues such as kidneys, liver, and testes. The evaluation period can range from one week to several months, depending on the specific study parameters [70,71].

In research on Parkinson's disease cell therapy, striatal transplantation of iPSC-derived dopaminergic neuron progenitor cells (DNPCs) into immunodeficient mice showed no malignant changes on H&E staining and no antigen Kiel 67 (Ki67)-positive proliferation after 52 weeks; subcutaneous teratogenicity testing with DNPCs in collagen likewise yielded no tumors over 26 weeks [39]. A subsequent study employing brain-slice IHC (Ki67, Sox1, Pax6) reported absence of these markers by day 274, while deliberate admixture of undifferentiated iPSCs (1% or 10%) with DNPCs produced teratomas, underscoring the necessity of complete differentiation to mitigate teratogenic risk [72]. Additional work defining teratogenic thresholds found that adding 0.1% embryonic stem cells did not induce teratomas, as opposed to 1% and 10%. Ki67-based proliferation in transplanted cells declined from roughly 25% during the first three months to about 6% by day 266, and histopathology at days 30 and 180 showed no tumors, vascular invasion, or lesions [73]. In amyotrophic lateral sclerosis (ALS) models, transplantation of astrocyte progenitor cells with absent pluripotency markers in vitro (SSEA-4, epithelial cell adhesion molecule (EPCAM), TRA-1-60) showed no tumor formation in brain or spinal cord at 4, 17, and 39 weeks post-transplantation, supporting a favorable biosafety profile [74]. Also, Schwartz S.D. and colleagues demonstrated no evidence of tumorigenicity, teratoma formation, or spread to other body parts at subretinal transplantation of hESC-RPE into immune-deficient mice [75].

In conclusion, thorough assessment of oncogenicity, tumorigenicity, and teratogenicity is essential to ensure the biosafety of cell-based therapies, with particular emphasis on controlling undifferentiated stem cell populations and employing comprehensive preclinical testing.

The initial step in immunogenicity assessment involves analyzing the innate immune response through precise measurement of cytokine production and granzyme release from NK cells. This evaluation is performed using enzyme-linked immunosorbent assay (ELISA) techniques, which provide quantitative data on the levels of these critical immune mediators. An important aspect of NK cells activity evaluation is the study of degranulation processes through co-culturing NK and target cells. Among the critical indicators for assessment, particular attention is paid to the lysosome-associated membrane protein LAMP-1 (CD107). Thus, it was shown that LAMP 1 can be used as a marker of NK cell degranulation, in particular, suppression of LAMP1 causes inhibition of NK cell cytotoxicity due to the inability to deliver granzyme B to target cells [81]. Additionally, the cytotoxic activity of NK cells against target cells can be quantitatively measured in vitro by assessing lactate dehydrogenase release, as confirmed by recent research [82,83].

The analysis of T-cell activation traditionally relies on the mixed lymphocyte culture reaction (MLR) method. The implementation of MLR requires two components for assessing cell immunogenicity: peripheral blood mononuclear cells (PBMCs) extracted from the recipient's blood and the tested cells intended for therapeutic use. During this process, the interaction between these components is observed through co-culture system. A key indicator of the cell product's immunogenicity is the proliferative activity level exhibited by PBMCs when co-cultured with target cells. Higher proliferative activity signifies greater immunogenic potential of the cell product [84]. The immune response can be further evaluated by monitoring the expression of specific cellular markers associated with activated CD4+ and CD8+ T lymphocytes, particularly focusing on CD25 and CD45 markers [85]. In practical applications, T-cell activation assessment often overlaps with the evaluation of the immunomodulatory function of cell therapy. The study showed that a modified MLR assay was applied to evaluate the immunogenicity of iPSC-derived neural progenitor cells (NPCs), comparing autologous and allogeneic responses in parallel. Another study found that NPCs from different sources exhibited immunomodulatory properties, and the origin of the pluripotent cells did not significantly affect the immunogenicity of the NPCs [86].

The complement system plays a critical role in the immune response to cell-based therapies, making complement activation assays essential for monitoring safety and efficacy in cell therapy applications [87]. Anaphylatoxins C3a and C5a are key components in triggering inflammatory responses, modulating immune cell activity [88]. These assays are particularly important for assessing the potential for immune-mediated destruction of therapeutic cells. Complement activation assays are used in several critical areas of cell therapy, including monitoring the immune response to transplanted cells, evaluating the safety profiles of cell products, assessing potential immune-mediated cytotoxicity, investigating cell survival mechanisms, and monitoring therapeutic efficacy [89].

The application of ELISA methodology in immunogenicity analysis is not limited to the assessment of innate immunity. The study showed that, using this method, pluripotent cells exhibited higher expression of the chemokines C-C motif chemokine ligand 5 (CCL5) and C-X-C motif chemokine ligand 12 (CXCL12) than MSCs and NPCs [68]. In addition, it was demonstrated that the secretome of neural crest stem cells was profiled to quantify interferon-gamma (IFN-γ), interleukin-1β (IL-1β), interleukin-2 (IL-2), interleukin-6 (IL-6), interleukin-10 (IL-10), interleukin-12p70 (IL-12p70), and tumor necrosis factor-alpha (TNF-α), enabling assessment of both inflammatory responses and overall immunogenicity [90]. Exposure to inflammatory cytokines significantly impacts immune responses through modulation of HLA expression. The mechanisms through which cytokines influence HLA expression involve several key pathways, including direct activation of HLA gene promoters, induction of signaling cascades, regulation of transcription factors, epigenetic modifications, and alteration of protein synthesis pathways [91]. Numerous major cytokines are involved in HLA regulation. IFN-γ is the primary inducer of HLA class I and II expression [92,93]. IL-6 modulates HLA expression patterns [94]. Type I interferons influence HLA class I expression [95].

Another method for assessing the immune response is Enzyme Linked Immuno-Spot (ELISpot), which is an effective method for measuring the production of cytokines by immune cells at the level of individual cells. The popularity of this analysis has increased dramatically in recent years as researchers try to better understand immune responses in various applications. This assay is particularly relevant for repeated dosing regimens and allogeneic cell products [96].

Another crucial factor for a complete investigation of cell immunogenicity is the analysis of HLAs expressed on the cell surface. HLA typing represents the process of donor-patient matching based on the HLA system [97]. This process is commonly carried out using a well-established method known as polymerase chain reaction (PCR). The study demonstrated that the qRT-PCR technique was employed to assess HLA expression in MSCs that were under consideration for TBI therapy. The findings revealed the absence of HLA-DRA1, while HLA-DPA1 and HLA-DQA1 were detected. Notably, the cycle threshold values for MSCs were approximately 32 cycles, whereas for PBMCs, they were around 24 cycles. The authors interpreted this discrepancy as an indication of immunological tolerance [7]. Meanwhile, the active development of technologies makes it possible to select patients using various types of sequencing [98]. Another option for HLA typing is the lymphocytotoxicity test, which operates on the principle of forming an antigen–antibody complex during the interaction between serum containing antibodies to HLAs and the patient's lymphocytes [98]. Donor-specific anti-HLA antibody monitoring is another method of compatibility assessment focusing on immunoglobulins produced by the recipient's immune system against donor HLAs [99]. These antibodies play a pivotal role in transplant rejection and determining compatibility. The key objectives of monitoring include transplant rejection risk assessment, evaluation of compatibility between donor and recipient, surveillance of immune response post-transplantation, and detection of sensitization to donor antigens. The clinical significance of anti-HLA antibodies is substantial, impacting transplant outcomes in various ways. They increase the risk of acute rejection, reduce graft survival rates, necessitate adjustments in immunosuppressive therapy, and may lead to humoral rejection [100].

Autologous cells offer a distinct advantage by minimizing the risk of immunological rejection. However, this approach presents several challenges. The process involves isolating cells from the patient's own biological material, followed by an extended period of in vitro cell cultivation. These procedures are characterized by high labor intensity, significant time requirements, and considerable financial costs. At the same time, allogeneic cells make it possible to form a bank for cell therapy, which, in turn, allows scaling up the production process and minimizing the time spent on manufacturing the cell product. Moreover, the use of allogeneic cells enables the organization of a reliable biosafety verification system for the target product. However, these types of cells can cause an excessive immune response from the recipient's body [39,101,102].

It is worth emphasizing that different types of cells have different immunogenic properties. Thus, MSCs have low immunogenicity, since they lack HLA class II, which suppresses CD4+ T cells and provides immunomodulatory properties, which is of great importance for allogeneic transplantation [103]. Other types, such as HSCs, neural stem cells, and others, have more pronounced immunogenicity and are able to induce a significant immune response after transplantation [104]. Currently, methods are being developed to overcome these limitations using differentiation into the desired type of autologous iPSCs, but there remains the possibility of an immune response due to reprogramming errors [105]. On the other hand, approaches to creating hypoimmunogenic or "universal" stem cells by knocking out MHC genes using CRISPR and other modifications, such as those that target HLA-DRA1, are actively being introduced. These cells often employ specific strategies to avoid NK cells recognition, primarily through HLA-E overexpression, which binds to inhibitory receptors on NK cells, preventing their activation, and HLA-G overexpression, known for its immunosuppressive properties, binding to multiple inhibitory receptors on immune cells [106].

In conclusion, immunogenicity is a critical determinant of cell therapy biosafety and efficacy, necessitating comprehensive assessment of innate and adaptive immune responses to inform the development of both allogeneic and autologous products.

Cell labeling is one of the main methods applicable for monitoring the migration of target cells during preclinical research, with the selection of labels being determined by the research objectives and visualization techniques utilized. Based on one classification system, two primary types of labels are recognized: direct and indirect [112]. Direct labels encompass various nanoparticles and chemical reagents. These types of markers are particularly effective when conducting biodistribution studies over short-term periods (several days), as prolonged use may result in label loss due to cell proliferation processes. Indirect labels involve genetically introduced reporter genes [113]. Their advantage lies in their prolonged retention within cells, enabling extended observation periods during research. For effective distribution analysis, labels must meet several criteria: complete cellular compatibility (non-toxicity), safe elimination from the body post-cell death, sufficient stability for experimental duration, consistent retention within the cell for the required experimental period [114,115]. The method of visualizing labeled cells is also very important. Some of the most promising tools are positron emission tomography (PET) and single-photon emission computed tomography (SPECT). To obtain results with PET and SPECT, cells must be pre-labeled with radioisotopes [115]. Another method of visualizing cell biodistribution is magnetic resonance imaging (MRI). To work with this technology, target cells must be labeled with paramagnetic iron oxide particles or other similar markers. MRI allows for precise assessment of cell distribution in soft tissues at high resolution, with the generation of a three-dimensional image [115,116]. However, it is important to note that besides the aforementioned methods, there are alternative approaches for evaluating cell biodistribution.

The PCR method can be employed, in which the organs of the animal are analyzed separately at a certain time interval following cell injection. Currently, this method stands out as one of the most widely used and straightforward techniques in preclinical research implementation. PCR allows sensitive detection of transplanted cells by amplifying donor-specific genetic markers, enabling identification even when cell numbers are very low. This method provides quantitative information on cell distribution across tissues, offering high specificity and reproducibility compared to histological techniques [117]. Immunohistochemistry represents another commonly employed method, where tissue and organ sections from animals previously injected with target cells undergo antibody labeling against specific markers characteristic of the investigated cells [115]. In preclinical research, in situ hybridization technology is also used to assess cell distribution. This is a method employed to detect and localize specific nucleic acid sequences in tissue sections [118].

An example is a study on the biodistribution of oligodendrocyte progenitor cells (OPCs) after direct injection into the traumatized area of the spinal cord. The biodistribution of transplanted cells was systematically evaluated at intervals up to nine months post-transplantation in a rat model of cervical spinal cord injury. Histology, in situ hybridization, and PCR of blood, cerebrospinal fluid, and tissue samples were employed to trace the transplanted cells, while extensive histopathological examination of brain and spinal cord sections was performed to assess potential migration. These methods revealed no dissemination to peripheral organs, with cell migration largely confined to the cervical region and limited rostral or caudal extension [119]. In addition, another study demonstrated the distribution of a novel ALS therapy based on astrocyte progenitor cells (APCs) following intrathecal injection into the cerebrospinal fluid of immunocompromised NSG mice. Cell localization within the central nervous system was assessed over 39 weeks using in situ hybridization targeting the Alu Y sequence, revealing widespread but non-uniform distribution, with higher concentrations along the meninges. Extra-central nervous system biodistribution was evaluated by real-time PCR in multiple organs, including spleen, liver, kidneys, heart, lungs, bone marrow, and reproductive tissues, with no significant human DNA detected, confirming the absence of peripheral migration [74]. Moreover, the distribution of DNPCs in a Parkinson's disease model was evaluated by injecting them into the striatum of immunodeficient rats and analyzing tissues at 26-, and 39 weeks post-injection. PCR-based assessment revealed no migration beyond the cerebral hemispheres [120]. The main approaches to assessing the biosafety of cell products are presented in Figure 1.

In summary, the study of biodistribution is essential for ensuring the biosafety, efficacy, and predictability of cell-based therapies. A broad spectrum of labeling and visualization techniques, ranging from molecular approaches to advanced imaging modalities, provides researchers with the tools necessary to track cellular fate and optimize therapeutic strategies.