attempting to post the whole study
ABSTRACT
A growing number of peer-reviewed publications have reported diverse cancer types appearing in temporal association with COVID-19 vaccination or infection. To characterize the nature and scope of these reports, a systematic literature search from January 2020 to October 2025 was conducted based on specified eligibility criteria. A total of 69 publications met inclusion criteria: 66 article-level reports describing 333 patients across 27 countries, 2 retrospective population-level investigations (Italy: ~300,000 cohort, and Korea: ~8.4 million cohort) quantified cancer incidence and mortality trends among vaccinated populations, and one longitudinal analysis of ~1.3 million US military service members spanning the pre-pandemic through post-pandemic periods. Most of the studies documented hematologic malignancies (non-Hodgkin’s lymphomas, cutaneous lymphomas, leukemias), solid tumors (breast, lung, melanoma, sarcoma, pancreatic cancer, and glioblastoma), and virus-associated cancers (Kaposi and Merkel cell carcinoma). Across reports, several recurrent themes emerged: (1) unusually rapid progression, recurrence, or reactivation of preexisting indolent or controlled disease, (2) atypical or localized histopathologic findings, including involvement of vaccine injection sites or regional lymph nodes, and (3) proposed immunologic links between acute infection or vaccination and tumor dormancy, immune escape, or microenvironmental shifts. The predominance of case-level observations and early population-level data demonstrates an early phase of potential safety-signal detection. These findings underscore the need for rigorous epidemiologic, longitudinal, clinical, histopathological, forensic, and mechanistic studies to assess whether and under what conditions COVID-19 vaccination or infection may be linked with cancer.
IntroductionThe COVID-19 pandemic and the widespread deployment of novel mRNA- and viral-vector based vaccines have reshaped the landscape of human immunology [
1–
4]. Never has such a large proportion of the global population been exposed simultaneously to nucleic acid–based immunogens, lipid nanoparticle (LNP) delivery systems, and repeated booster regimens over a relatively short period. The unprecedented scale that was marshaled in response to the COVID-19 pandemic has generated and continues to generate extensive clinical, molecular, and epidemiologic data, revealing biological responses that extend beyond traditional vaccine-induced immune activation and responses. These include a spectrum of post-infection and post-vaccination neurological, autoimmune, and inflammatory syndromes, including myocarditis, immune-mediated neuropathies, autoimmune cytopenias, systemic inflammatory responses [
5–
7], as well as temporal co-occurrence with cancer diagnoses, recurrences, or unexpectedly rapid disease trajectories [
8–
11]. These events have prompted extensive clinical investigation and underscore the capacity of vaccine-induced immune activation to perturb immune homeostasis in susceptible individuals. Importantly, many of these conditions are characterized by cytokine dysregulation, altered innate and adaptive immune signaling, and tissue-specific inflammatory responses; pathways that are also implicated in tumor initiation, progression, and immune surveillance. The present review focuses specifically on cancer-related observations within this broader context of post-vaccination immune perturbation.
After nearly six years since the pandemic was recognized in early 2020, the current world’s literature addressing COVID-19 infection or vaccination and cancer remains sparse, heterogeneous, and largely limited to case reports and small case series, insufficient to support definitive conclusions regarding causation or quantification of risk. Package inserts for COVID19 vaccines posted by the Food and Drug Administration (FDA) [
12–
15] specifically state that they have not been evaluated for carcinogenicity or genotoxicity, nor have they been studied after multiple vaccine doses and boosters or in combination with subsequent SARS-CoV-2 infection.
During the COVID pandemic, it was predicted that cancer rates would rise during and after COVID due to reduced screening and reduced access to treatment during the pandemic. However, rates of cancer among younger individuals for example with early onset colon cancer have been rising for two decades [
16,
17]. Rates of cholangiocarcinoma and endometrial cancer have been rising as well. Cancer deaths exceeded 600,000 in US for 1st time in 2024 and in 2025 are predicted to rise as well [
18]. As of the writing of this review, there are no published population studies in the US with mortality or cancer incidence follow-up beyond 42 days for outcomes after Covid infection versus no Covid infection or Covid vaccinated versus not Covid vaccinated. This is in part due to lack of good quality databases that would have such information. There is a National Cancer Institute (NCI)-funded Covid and Cancer Consortium (CCC) but it has not published on this topic specifically.
Against the backdrop of limited clinical evidence and incomplete preclinical toxicology, a recent study reported that SARS-CoV-2 mRNA vaccines may actually sensitize tumors to immune checkpoint blockade [
19] prompting broad interpretation that COVID-19 mRNA vaccination may actually potentiate antitumor responses in patients with melanoma or non–small cell lung cancer (NSCLC) undergoing immune checkpoint inhibition. Moreover, in the analysis, mRNA vaccination was associated with increased Type I interferon signaling and elevated tumor PD-L1 expression. However, PD-L1 upregulation in the absence of checkpoint inhibitor therapy is generally associated with enhanced tumor immune evasion and resistance to T-cell–mediated cytotoxicity, raising questions about the biological interpretation of these findings. Although interferon-based therapies have established clinical utility in melanoma, the study did not provide comparative analyses between interferon treatment and the combination of mRNA vaccination with checkpoint blockade. Furthermore, the study did not address key limitations, alternative mechanistic explanations, or the broader clinical context necessary to fully interpret the reported effects.
This absence of evaluation of COVID19 vaccines for carcinogenicity or genotoxicity motivated a systematic review and synthesis of the available evidence from 2020–2025 concerning COVID-19 vaccination, SARS-CoV-2 infection, and cancer. Specifically, we sought to (i) categorize malignancies reported in temporal proximity to vaccination or infection, (ii) evaluate temporal and clinical patterns across tumor types for relevant signals among patients exposed to the COVID vaccines, and (iii) outline plausible immunologic and molecular mechanisms that could underlie these phenomena.
Across the published literature, we identified reports involving hematologic malignancies, including lymphomas and leukemias, solid tumors such as breast, lung, pancreatic, and glial cancers, virus-associated malignancies including Kaposi sarcoma and Merkel cell carcinoma, and rare entities such as sarcomas, melanomas, and adenoid cystic carcinomas. While the number of studies or their temporal association does not establish causation, understanding whether these associations represent coincidence, immune dysregulation, or a broader biologic effect linking infection, vaccination, and cancer development is now of pressing importance.
Importantly, regarding reported adverse events and potential risks, awareness of what has occurred, even if ultimately this proves to be extremely rare, is a necessary component of informed consent at a time when there is no longer a public health emergency from COVID-19. Cancer risk is likely based on heterogeneity among individuals, the impact of genetics, environment, and interacting social determinants of health that varies among individuals and this is an area where this article could form a foundation for future studies to refine individualized risk. As such, the goal of this article is to systematically synthesize and contextualize findings from the published literature regarding malignancies temporally associated with COVID-19 vaccination or SARS-CoV-2 infection, without attempting to estimate risk, establish causality, or inform individual clinical or vaccination decisions.
Results
This scoping review, covering the period of January 2020 until April 2025, was not designed to estimate cancer risk or incidence, nor to draw causal inferences, but rather to systematically assemble, categorize, and contextualize published reports of malignancies temporally associated with COVID-19 vaccination or SARS-CoV-2 infection. It identified 69 publications [
8,
20–
87] describing malignancies or malignant progression in temporal association with COVID-19 vaccination or SARS-CoV-2 infection, encompassing a total of 333 patients (excluding population-level studies [
8,
20]. In addition, one population-level publication which offered a longitudinal assessment of cancer incidence across the pandemic and immediate post-pandemic period was identified [
85]. Among the 69 studies, most reports were single-patient case reports or small series (55/69, 81%), with a small number of systematic or narrative reviews (3/69, 4.5%), mechanistic/experimental studies (2/69, 3%), and larger case series, multicenter, or database-level analyses (8/69, 12%) (
Table 1). Consistent with an early signal-detection phase, the underlying evidence base is therefore heavily weighted toward documenting occurrences of potentially adverse events and hypothesis-generating case-level observations rather than population-based epidemiologic studies.
Table 1: Summary of reports linking COVID-19 vaccination or infection to cancerStudy type
N% of Total (
N = 69)Comments
Case reports5072%Dominant study type; mostly single-patient descriptions
Case series57%Typically 2-several patients
Systematic/narrative reviews34%Summaries or literature syntheses
Cohort/retrospective/observational population studies812%Larger-scale data (e.g., population cohort, single center cohort)
Mechanistic/translational studies (tissue, organoids, mouse)34%Experimental or preclinical mechanistic workGeographic distributionReports originated from a wide range of countries spanning Asia, Europe, the Middle East, Africa, and North and South America. The countries with the highest number of publications were Japan (
n = 11) and the United States (
n = 11), followed by China (
n = 7) and Italy (
n = 4). Additional single-patient cases or small series were identified from Spain, South Korea, Saudi Arabia, India, Nigeria, Brazil, Turkey, Singapore, Lebanon, Egypt, Bulgaria, Taiwan, Ukraine, Iran, Russia, Greece, Austria, Germany, Poland/Ukraine, as well as multi-institutional or international collaborations. This broad geographic distribution indicates that the reported temporal associations between COVID-19 vaccination or infection and oncologic events are not confined to a particular region or healthcare system but have been observed across diverse clinical settings and diagnostic infrastructures around the globe.
Exposure types: Vaccination versus infectionMost publications identified in the search focused on oncologic events occurring after COVID-19 vaccination (56/69; 89%), with the remainder describing associations following SARS-CoV-2 infection (5/69; 7%), and SARS-CoV-2 infection with prior vaccination (7/69; 10%). One publication (1/69; 1%) did not explicitly specify whether the reported oncologic event followed vaccination, SARS-CoV-2 infection, or a combination of both exposures. These included case reports and mechanistic studies evaluating post-infectious tumor behavior, immune perturbation, or disease acceleration along with SARS-CoV-2 infection but in the absence of vaccination or associated with a SARS-CoV2 infection but with prior vaccination or boosting. The predominance of vaccination-associated case reports may reflect reporting patterns rather than comparative biological risk, and the available data lack sufficient individual-level detail to determine whether or how oncologic responses differ between infection or vaccination.
Across the published literature, reported vaccine formulations and exposure types were heterogeneous but could be grouped into broad platform categories (
Figure 1). Among vaccine-related reports, the majority involved mRNA vaccines, with approximately 56% following the Pfizer-BioNTech vaccine (BNT162b2) and 25% following the Moderna vaccine (mRNA-1273). An additional 5% involved patients who had received both Pfizer and Moderna products across different doses. Adenovirus vector vaccines represented the next largest category, including AstraZeneca (ChAdOx1/Covishield) (5.8%), Johnson & Johnson (Ad26.COV2.S) (2.9%) and the Russian, Sputnik-V (1.4%). Inactivated vaccines (e.g., Sinopharm BBIBP-CorV, CoronaVac, or other formulations) and studies in which the specific vaccine type was not reported were least represented (2.6% and 1.1%, respectively). This distribution indicates that the published literature is heavily weighted toward mRNA vaccine platforms, particularly Pfizer-BioNTech and Moderna, which together account for the vast majority of vaccine-associated reports. This pattern closely mirrors global vaccination practices where mRNA vaccines were most widely deployed. The relatively smaller representation of adenoviral vector vaccines and inactivated platforms likely reflects both their more limited use in certain regions and differential reporting practices, rather than a comparative assessment of biological risk.
![[Image: 0c6ab5847b9ad6518c727630d4c50e61.png]](https://denyignorance.com/uploader/images/0c6ab5847b9ad6518c727630d4c50e61.png)
Figure 1: Distribution of reported malignancies by COVID-19 vaccine type. Distribution of vaccine formulations among vaccinated patients with reported cancer following COVID-19 immunization. Most cases involved Pfizer-BioNTech (BNT162b2; 56%) and Moderna (mRNA-1273; 25%) vaccines, followed by AstraZeneca/ChAdOx1 (Covishield; 17%) and Johnson & Johnson/Ad26.COV2.S (8%). A small fraction of reports involved Sinovac (CoronaVac), Sinopharm (BBIBP-CorV), or other inactivated vaccines, as well as unspecified mRNA or COVID-19 vaccine types. The predominance of mRNA vaccines reflects their widespread global use during the study period.
Cancer types and clinical spectrumApproximately 43% (30/69) of publications reported lymphoid malignancies, encompassing both lymphomas and leukemias (
Figure 2 and
Table 2). These included a wide spectrum of lymphoid neoplasms such as diffuse large B-cell lymphoma (DLBCL), various T-cell lymphomas (e.g., angioimmunoblastic T-cell lymphoma, subcutaneous panniculitis-like T-cell lymphoma), chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL), and cutaneous T-cell lymphomas (CTCL). Several reports emphasized unexpectedly rapid progression, atypical presentations, or unusually aggressive courses of disease.
![[Image: 5889b544e521c31de3c996b0f38a5c3e.png]](https://denyignorance.com/uploader/images/5889b544e521c31de3c996b0f38a5c3e.png)
Figure 2: Distribution of post-vaccination and post-infection malignancies by tumor type. Distribution of reports with malignancy or tumor-like lesions temporally associated with COVID-19 vaccination, SARS-CoV-2 infection, or SARS-CoV-2 infection and vaccination. Pie charts depict the proportional representation of major cancer categories observed. (
A) Accross all studies. (
B) COVID-19 vaccination, (
C) SARS-CoV-2 infection, and (
D) combined SARS-CoV-2 infection and COVID-19 vaccination. Cancer types were consolidated into seven high-level categories. Carcinoma includes: breast cancer, prostate cancer, colon cancer, pancreatic cancer, lung cancer, Merkel cell carcinoma, GI neoplasia/polyposis. Lymphoma also includes lymphoid neoplasms, cutaneous lymphoproliferative disorders, lymphoproliferative disorder. Other includes benign tumors, pseudotumors, mixed tumors, heart tumors, inflammatory and non-specific tumors (e.g., myofibroblastic).
Table 2: Clinicopathologic spectrum of lymphomas in post-vaccination reportsLineageSubtypesKey features
T-cell lymphomasCTCL, LyP, ALCL, AITL, SPTCL, TFH-type, PCGDTCL, T-ALL, T- cellNOSDominated by cutaneous and TFH-derived entities; several at injection sites; many indolentor self-resolving (CD30[sup]+[/sup]).
B-cell lymphomasDLBCL, Follicular, MZL, CLLPrimarily DLBCL; often nodal or axillary post-mRNAvaccine; typically de novo; most treated with R-CHOP.
NK/NK-T-cell lymphomasENKL (nasal-type), NK/T overlapEBV[sup]+[/sup] nasal lesions; one partial response to SMILE + radiation; suggest EBV reactivation.
Mixed/Unspecified LPDsLarge “unspecified/other” cohort from systematic review (Cui 2024) and PCLDsAggregate data without cell-lineage resolution; largely literature or registry series.Solid tumors accounted for 41% of publications (28/69) and represented a diverse group of malignancies, including melanoma, breast cancer, lung cancer, glioblastoma and other glial tumors, sarcomas, and various organ-specific carcinomas, such as pancreatic cancer (
Figures 2 and
3). In multiple reports, the authors described unusually rapid onset, short-latency recurrence, or aggressive clinical progression for tumor types such as pancreatic adenocarcinoma and glioblastoma; features that are atypical for these cancers highlighted as notable temporal observations.
![[Image: index.php?journal=oncotarget&page=articl...5D=1080904]](https://www.oncotarget.com/index.php?journal=oncotarget&page=article&op=viewFile&path%5B%5D=28824&path%5B%5D=98181&path%5B%5D=1080904)
Figure 3: Representative examples of cancers reported in temporal association with COVID-19 vaccination. Figures were reproduced with permissions (Supplementary Table 1). Lymphoma: (
A) Axillary adenopathy and i) 18-FDG-PET/CT at baseline in the right axillary adenopathy mass and ii) in multiple axillary adenopathies and subsequent NHL diagnosis following vaccination. Image reproduced from Cavanna et al., Medicina, 2023. © MDPI. (
B) Temporal mass after her first BNT162b2 dose, with persistent lymphadenopathy on imaging. Axial computed tomography image shows (i, ii) submandibular and jugular regions. Image reproduced from Sekizawa et al., Front Med, 2022. © Frontiers. Sarcoma (
C) High-grade sarcoma arising near injection site. A 6-cm right upper-arm mass after second Moderna dose, near the prior injection site; pathology confirmed high-grade sarcoma. Image adapted with permission from Bae et al., Cureus, 2023 © Springer Nature. (
D) Classic cutaneous Kaposi’s sarcoma adapted from Li et al. Front Med, 2022 © Frontiers. A 79-year-old man developed violaceous papules on the legs after the first ChAdOx1 vaccine dose; biopsy confirmed KS. Treatment included radiotherapy and doxorubicin. Clinical images of Kaposi sarcoma (i) with dark brown macules over the left foot, (ii) the right foot and larger reddish erythematous papules on his left calf (iii, iv). Carcinoma (
E) In a 96-patient cohort, repeated booster vaccination correlated with poorer overall survival and elevated IgG4 level of pancreatic ductal adenocarcinoma. Kaplan–Meier analysis of 96 PC patients with known vaccination history and measured IgG4 levels, total IgG4 levels by number of vaccinations, and Kaplan–Meier analysis in PC patients by IgG4 levels. Image adapted with permission from Abue et al. Cancers 2025 © MDPI. (
F) A case of metastatic breast carcinoma to the skin expressing SARS-CoV-2 spike protein. Histopathology of skin metasstatis along with IHC for nucleocapsid and Spike protein. Images adapted from Sano, S., J. Derm Sci, 2025. © Elsevier. Melanoma (
G) Gross examination of specimen shows extensive intraocular hemorrhage involving both anterior and posterior chambers, accompanied by complete retinal detachment. H&E stained section shows severely degenerated, necrotic melanocytic lesion located with widespread necrosis within the melanocytic tumor. SOX10 IHC confirms melanocytic cells containing cytoplasmic melanin, interspersed among numerous SOX10-negative melanophages. Image adapted with permission from Wagle et al. Indian J Ophthalmo 2022 © Wolters Kluwer. (
H) Maximum-intensity projection PET image shows markedly increased radiotracer uptake within the left axillary and supraclavicular lymph nodes. Representative axial CT and corresponding fused PET/CT images highlight the dominant nodal conglomerate. The patient had received a COVID-19 vaccination in the left upper arm within two months prior to imaging. Image adapted from Gullotti et al. Radiol Case Rep. 2022 © Elsevier. Glioblastoma (
I) Two patients (ages 40 and 31) presented with new neurologic deficits and frontal-lobe masses shortly after mRNA vaccination. Image adapted from O’Sullivan et al. J of Neurology. 2021 © Elsevier. Other (
J) Gastrointestinal polyposis identified following COVID-19 vaccination. Image adapted with permission from Kim et al. Clin Endosc 2024 © Korean Society of Gastrointestinal Endoscopy (
K) Axillary lymphangioma in an 80-year-old woman three months after her second Pfizer-BioNTech dose; imaging showed a cystic lymphangioma. Image adapted with permission from Sasa et al. Surg Case Rep 2022 © Springer Nature.
A subset of reports described tumor formation or recurrence at or near vaccine injection sites, the deltoid region, axilla, or draining lymphatic basins, including cases where axillary lymphadenopathy coincided with solid-tumor metastasis. Virus-associated malignancies such as Kaposi sarcoma, Merkel cell carcinoma, and EBV-positive lymphomas were also identified across several reports. The remaining 16% of publications (11/69) were categorized as other or unspecified, which included mixed or indeterminate cases, non-malignant proliferations, studies referencing “cancer”, “tumor”, or “malignancy” without definitive histopathologic classification, and population-level analyses in which tumor type was not explicitly delineated.
Specific examples of cancers and their association with COVID vaccinationLymphomaCavanna et al. [
26] reports the review of a series of eight patients who developed Non-Hodgkin’s Lymphoma after COVID-19 vaccination (
Table 3), including four males and four women. Five patients were vaccinated with the BNT162b2 vaccine (Pfizer), one with the ChAdOx1 nCOV-19 vaccine (AstraZeneca, Cambridge, UK), one with mRNA 1273/Spikevax (ModernaTX) and one patient with the recombinant replication-incompetent adenovirus type 26 (Ad26) viral-vector-based COVID-19 vaccine (Janssen Pharmaceuticals, Beerse, Belgium). One of the NHL cases presented with large right axillary adenopathy shortly after COVID-19 vaccination (
Figure 3A).
Table 3: Summary of case series describing malignant lymphoma following mRNA COVID-19 vaccinationCase NGender/Age (Year)Time from Vaccination to Onset of Lymphoproliferative DisorderHistopathological ExaminationType of COVID-19 VaccineSite and Diameter of LymphadenopathyTreatment of Lymphoma1M/671 day after 1 doseDLBCLBNT162b2Left axilla 6.0 cmChemotherapy plus rituximab2F/802 days after 1 doseDLBCLBNT162b2Left axilla 4.1 cmChemotherapy plus rituximab3F/587 days after 2 doseDLBCLBNT162b2Left cervical area 4 cmRadical surgery plus radiotherapy4M/533 days after 1 doseExtranodal NK/T-cell lymphomaBNT162b2Erosive lesions upper lip up to 5 mmChemotherapy plus radiotherapy5M/517 days after 1 doseEBV-positive DLBCLChAdox1 nCOV-19Mediastinal mass 5 cmRituximab6F/28“A few days after 1 dose”SPTCLAd26 viral-vector- basedInjection site, upper armCyclosporine plus prednisone7F/801 day after 1 doseEMZLBNT162b2Right temporal massNo treatment8M/7610 days after the booster dosePC-ALCLmRNA-1273[sup]*[/sup]Right arm upper-external surface 6 cmNo treatmentTable reproduced from Cavanna et al., Medicina, 2023. © MDPI. Abbreviations: ALCL: anaplastic large-cell lymphoma; DLBCL: diffuse large B-cell lymphoma; EBV: Epstein-Barr virus; EMZL: extranodal marginal zone lymphoma; PC-ALCL: primary cutaneous anaplastic large-cell lymphoma; SPTCL: subcutaneous panniculitis-like T-cell lymphoma.[sup] *[/sup]The two previous vaccination doses were BNT162b2.)
Sekizawa et al. [
28] describe a case of marginal zone B-Cell lymphoma in an 80-year-old Japanese woman who presented with a right temporal mass that appeared the morning after she was administered her first mRNA COVID-19 vaccination (BNT162b2) (
Figure 3B). The mass gradually decreased in size but persisted over 6 weeks after her first vaccination (3 weeks after her second vaccination). At her first visit, ultrasound revealed the size of the mass to be 28.5 Å~ 5.7 mm, and computed tomography revealed multiple lymphadenopathies in the right parotid, submandibular, jugular, and supraclavicular regions. This case brings up the possibility that an initial mass may not be composed entirely of cancer cells and may have an element of a host response that may limit the progression depending on immune or other factors. In this case, the patient had marginal zone B-cell lymphoma after BNT162B2 COVID-19 vaccination.
SarcomaBae et al. [
21] reported the development of high grade sarcoma after the second dose of the Moderna vaccine. A 73-year-old female with a past medical history of hypertension, hyperlipidemia, and renal angiomyolipoma status post resection in 2019 presented with worsening right upper arm swelling for the past two weeks. She noticed the swelling two to four days after receiving her second dose of the Moderna vaccine within 1 cm from the prior injection site. Physical examination was remarkable for a 6 cm, circular, mobile, soft mass present in the right upper arm. (
Figure 3C). Li et al. [
23] reported the development of classic cutaneous Kaposi’s sarcoma in a 79-year-old male following the first dose of the ChAdOx1 nCov-19 vaccine, without prior SARS-CoV-2 infection or history of HIV infection. The patient developed multiple reddish-blue papules on his legs and feet, confirmed as KS through histopathology (
Figure 3D). Treatment included radiotherapy and sequential chemotherapy with doxorubicin. The potential reactivation of latent HHV-8 by the vaccine is suggested through mechanisms involving the SARS-CoV-2 spike protein and adenovirus vector, which may induce immune responses and inflammatory pathways.
Carcinoma
Abue et al. [
32] describe a case series of 96 patients with the diagnosis of pancreatic ductal adenocarcinoma (
Figure 3E). Repeated COVID-19 booster vaccinations were associated with worse overall survival in the patients with pancreatic cancer. Analysis revealed that high levels of IgG4, induced by vaccination, correlate with a poor prognosis. Sano [
36] described an 85-year-old woman who presented with an asymptomatic skin lesion in the right chest within one month immediately after the 6th dose of (Pfizer-BioNTech) vaccination. The patient had been diagnosed with right breast cancer two years prior and underwent partial mastectomy, hormone therapies, and was deemed to be in remission. The lesion was confirmed as a skin metastasis deemed to have developed through potential local recurrence at surgical margins (
Figure 3F).
Melanoma
Wagle et al. [
56] described a 49-year-old Indian male who developed rapidly progressive vision loss one day after receiving a second dose of the BNT162b2 mRNA COVID-19 vaccine (Pfizer–BioNTech, USA). Ophthalmologic exam revealed secondary angle-closure glaucoma, bullous retinal detachment, and extensive intraocular hemorrhage. Ocular imaging and confirmed magnetic resonance imaging (MRI) revealed an ill-defined heterogeneous subretinal lesion, with histopathology confirming necrotic uveal melanoma (
Figure 3G). Gullotti et al. [
55] also described an otherwise healthy 53-year-old man who presented with ipsilateral axillary lymphadenopathy and associated discomfort shortly after receiving a COVID-19 vaccine. Fine-needle aspiration performed within two months of vaccination revealed metastatic melanoma, and subsequent 18F-FDG PET/CT imaging demonstrated intensely hypermetabolic axillary and supraclavicular lymphadenopathy without identification of a primary tumor (
Figure 3H).
Glioblastoma
Tosun et al. [
29] reported a 40-year-old man presenting with left hemiparesis. He had received COVID-19 vaccination 3 weeks before. Brain MRI showed a central cystic necrotic lesion with indistinct borders in the right frontal lobe as mild peripheral contrast enhancement surrounded by smaller nodular lesions. O Sullivan et al. [
84] also describe a 31-year-old female who first noted a slight weakness of her right leg about 7 days after receiving the first dose of a COVID-19 mRNA vaccine (Comirnaty[sup]®[/sup]BioNTech Manufacturing GmbH, Germany). She initially reported slight drowsiness and headache without fever following vaccination, which resolved within 24 h. Following the administration of the second intramuscular dose of the vaccination, 21 days after the first, the preexisting weakness of the right leg rapidly worsened and was accompanied by severe headache and night chills. Neurological examination on day 28 showed a mild central paresis of the right leg and numbness of the plantar surface of the foot (
Figure 3I).
Other
Kim et al. [
31] describe two cases of gastrointestinal polyposis (Cronkhite–Canada syndrome) shortly after administration of an mRNA booster vaccine for COVID19. Both showed numerous erythematous gastric and colonic polyps with villous atrophy throughout the small intestine (
Figure 3J). The authors note that the timing, autoimmune features, and steroid responsiveness raise the possibility that mRNA vaccination may trigger Cronkhite–Canada syndrome in genetically susceptible individuals, warranting clinical vigilance. Sasa et al. [
33] report on axillary lymphangioma following COVID-19 in a Japanese woman in her 80s who received a second injection of the Pfizer-BioNTech COVID-19 vaccine in her left deltoid muscle in 2021 (
Figure 3K). She had a history of right breast cancer (T1N0M0) and had undergone breast-conserving surgery and sentinel node biopsy in her 70’s. Postoperative follow-up examinations were continued, and no sign of recurrence, including in the left axial region, was observed until 2021. There was no evidence of trauma to the left axial region. Her early adverse reaction following vaccination was mild pain at the inoculation site on the day of vaccination and the following day. However, 3 months after the second vaccination, she noticed left axillary swelling.
De novo disease versus recurrence or progressionMost publications, including all the examples above, described de novo malignancies or apparent “unmasking” or activation of previously subclinical disease. A smaller subset focused predominantly on recurrence, progression, or metastatic reactivation in patients with a documented cancer history. An additional 13 publications reported mixed cohorts, including both new diagnoses and recurrences or provided explicit quantification of both categories. Only one publication did not clearly distinguish between new-onset and recurrent disease.
Taken together, these patterns indicate that the observed signal in the literature is not restricted to recurrence or flare of known malignancies. Rather, a substantial proportion of reports involve first-time cancer diagnoses temporally associated with COVID-19 vaccination or SARS-CoV-2 infection, highlighting the need to evaluate potential mechanisms that could contribute to disease initiation, unmasking, or acceleration.
Timing of onset
Across the included studies, the timing of cancer onset following COVID-19 vaccination varied substantially, indicating that latency was not confined to a single early window. Approximately half of the case reports described diagnoses occurring within 2–4 weeks of vaccination, with some reported as early as 7–14 days. However, many reports also documented longer intervals, including diagnoses at 2–3 months, 4–6 months, and beyond eight months after vaccination. Importantly, reports with short intervals are inherently more likely to be recognized and published as temporally notable.
In addition, in many reports describing diagnoses within the first month, the event occurred after a second dose or booster, complicating attribution to any specific exposure and precluding definition of a uniform latency period. Multicenter analyses frequently characterized latency as variable, spanning weeks to months, and several reviews or population-level studies reported mean onset intervals of approximately 8–9 weeks.
Tumor growth rates vary significantly among tumor types from the fastest growing lymphomas and leukemias to slower growing solid tumors [
87–
92]. Accordingly, while a subset of published cases report diagnoses within weeks of vaccination, the broader literature reflects a continuum of reported latencies over several months, often in the context of cumulative exposure. These observations are therefore best interpreted as descriptive and hypothesis-generating, underscoring the need for standardized latency definitions and systematic evaluation in appropriately controlled studies.
Population-level and registry-based studies
Three large-scale population-level analyses provided broader epidemiologic context to complement the case-based literature. Two retrospective population-level investigations, one in Italy [
20] and one in South Korea [
8], quantified cancer incidence and mortality trends among vaccinated populations. Kim et al. [
8] analyzed approximately 8.4 million individuals between 2021 and 2023 to assess 1-year cumulative cancer incidence following COVID-19 vaccination using the South Korean National Health Insurance Service database. The authors reported statistically significant associations between vaccination and six specific cancers, including thyroid (HR 1.35), gastric (HR 1.34), colorectal (HR 1.28), lung (HR 1.53), breast (HR 1.20), and prostate cancer (HR 1.69) using propensity score matching and multivariable Cox proportional hazards models. Associations varied by vaccine platform, with mRNA vaccines linked to thyroid, colorectal, lung, and breast cancers, and cDNA/adenoviral vaccines associated with thyroid, gastric, colorectal, lung, and prostate cancers; heterologous vaccination was associated with thyroid and breast cancer. Stratified analyses suggested effect modification by sex and age, and booster-dose analyses identified increased risks for gastric and pancreatic cancer. The authors emphasized that despite adjustment for measured confounders, residual confounding, detection bias, and limited follow-up preclude causal inference, and that the findings should be interpreted as epidemiologic associations warranting further study rather than evidence of vaccine-induced cancer risk.
Acuti Martellucci et al. [
20] evaluated associations between SARS-CoV-2 vaccination, all-cause mortality, and hospitalization for cancer using multivariable Cox proportional hazards models in a population-wide retrospective cohort study of 296,015 residents of the Pescara province in Italy followed for up to 30 months (June 2021–December 2023). Hospitalization for cancer of any site was found to be modestly higher among vaccinated individuals compared to unvaccinated (≥1 dose: HR 1.23, 95% CI 1.11–1.37; ≥3 doses: HR 1.09, 95% CI 1.02–1.16), with site-specific increases observed primarily for colorectal (HR 1.35), breast (HR 1.54), and bladder cancer (HR 1.62) after ≥1 dose, and for breast and bladder cancer after ≥3 doses. These associations varied by sex, prior SARS-CoV-2 infection, vaccine type, and lag time between vaccination and outcome, and were attenuated or reversed when a longer minimum latency of 365 days was applied. The analyses adjusted for age, sex, prior SARS-CoV-2 infection, and multiple comorbidities (including cardiovascular disease, diabetes, COPD, kidney disease, and prior cancer), but lacked information on key behavioral and healthcare-utilization confounders such as smoking, cancer screening, and healthcare-seeking behavior. The authors explicitly note that residual confounding, healthy-vaccine bias, detection bias, and reliance on hospitalization data as a proxy for cancer incidence limit causal interpretation, and they characterize the findings as preliminary and hypothesis-generating rather than evidence of vaccine-induced cancer risk. Both studies provide early, population-level associations rather than causal estimates and underscore the importance of long-term follow-up and molecular correlation to distinguish true biological effects from health-system or behavioral confounders.
In addition to these population-level studies, a recent US Armed Forces Health Surveillance Division (AFHSD) report was also identified that presented population-level analyses of non-Hodgkin lymphoma (NHL) incidence among active-duty U.S. service members from 2017 through 2023 [
85]. The U.S. Department of Defense (DoD) mandated COVID-19 vaccination for all active-duty service members (~1.3 million) beginning in late 2020, with near-universal compliance achieved by mid-2020; this cohort offers a rare longitudinal view of cancer incidence across this transition. Using data from the Defense Medical Surveillance System (DMSS), the authors calculated annual incidence rates (IRs) per 100,000 person-years and categorized cases by lymphoma subtype and the 2017–2020 interval largely represents a pre-vaccine baseline, whereas 2021–2023 reflects a fully vaccinated, post-pandemic cancer incidence [
86] (
Figure 4).
![[Image: index.php?journal=oncotarget&page=articl...5D=1080905]](https://www.oncotarget.com/index.php?journal=oncotarget&page=article&op=viewFile&path%5B%5D=28824&path%5B%5D=98181&path%5B%5D=1080905)
Figure 4: Annual incidence rates of non-Hodgkin lymphoma (NHL) subtypes among active-component U.S. service members, 2017–2023. Figure adapted from Russell et al. [
85] using Defense Medical Surveillance System data demonstrating rise in specified/unspecified NHL and mature T/NK-cell subtypes. Vertical lines denote key timepoints: the onset of the COVID-19 pandemic (early 2020) and the beginning of the Department of Defense vaccine mandate (late 2020–early 2021).
Notably, a rise in mature T/NK-cell lymphomas began across the 2020–2021 transition which spans the period of COVID-19 infection and the beginning of widespread vaccination in the military. Beginning in 2021, a ~50% increase in specified/unspecified and non-follicular NHL subtypes, accompanied by a persistently elevated incidence of mature T/NK-cell lymphomas relative to pre-pandemic years was observed. Notably, the authors did not attribute the observed changes in NHL incidence to vaccination or infection, and the analysis was not designed to establish causality at the individual level. Changes in diagnostic practices, healthcare access and utilization, and pandemic-related disruptions to routine medical care cannot be excluded from this time-trend analysis as with others conducted during the pandemic period. However, these findings provide descriptive temporal trends within a unique and highly structured population, providing an epidemiologic framework for future controlled analyses.
Taken together, these population-level analyses combined with the case-based literature indicate that a cancer signal warrants further prospective evaluation to determine whether COVID-19 vaccination confers any measurable cancer risk or merely reflects surveillance and reporting biases.
Materials and MethodsA comprehensive search of the world’s literature was conducted using PubMed, Scopus, Web of Science, Google Scholar, and React19 between January 2020 and April 2025. Eligible publications included case reports, case series, cohort or population-level analyses, systematic reviews, and mechanistic or preclinical studies that described either (i) new-onset, recurrent, or rapidly progressive malignancy temporally associated with COVID-19 vaccination or SARS-CoV-2 infection, or (ii) experimental evidence implicating vaccine or infection-induced immune perturbations in oncogenic, proliferative, or metastatic processes.
Initial searches in PubMed using conventional keyword combinations such as “COVID-19 vaccine and cancer,” “vaccination and cancer,” “COVID-19 vaccine and tumor,” or cancer-specific terms paired with “COVID-19 vaccine” yielded little to no indexed results. Even when known case reports were used as anchors for “similar articles,” PubMed returned no related entries. This highlighted a structural limitation in standard indexing pathways and necessitated a broader, more strategic search approach.
A general web-based search (e.g., Google) returned an autogenerated AI summary when queried for the terms “COVID vaccine and cancer” indicating that major health agencies, including the Centers for Disease Control and Prevention (CDC) and the National Cancer Institute (NCI), recommend COVID-19 vaccination for individuals with cancer and assert that the vaccines are considered safe for this population and are not believed to cause cancer or precipitate recurrence. Therefore, an expanded search strategy was implemented using combinations of general and tumor-specific terms, including: “COVID-19,” “SARS-CoV-2,” “spike,” “vaccination,” “vaccine,” “tumor,” “cancer,” “neoplasia,” “malignancy,” “recurrence,” “progression,” “lymphoma,” “leukemia,” “melanoma,” “glioma,” “adenocarcinoma,” “sarcoma,” “Kaposi,” “Merkel cell,” “cardiac”, and related descriptors. Databases were searched using Boolean operators, varied term order, and MeSH/non-MeSH variants to overcome incomplete tagging or atypical indexing of case reports.
Studies were included irrespective of patient age, sex, geographic region, cancer histology, or vaccine platform (mRNA, viral-vector, or inactivated). Exclusion criteria consisted of commentaries, opinion correspondence, purely theoretical articles lacking clinical or experimental data, and duplicate case entries across publications. Studies labeled as “COVID-associated” or “COVID-related”, particularly for cardiac tumors ultimately described patients who tested negative for SARS-CoV-2 [
93]. For methodological consistency, we excluded such reports from the infection-focused section of the analysis, as the absence of virologic confirmation precludes attributing the observed malignancy to active or recent infection. Reference lists of systematic reviews and larger case compilations were manually screened to identify secondary citations not captured in the primary search. All included articles were independently cross-referenced in PubMed when possible, to confirm indexing status and ensure completeness.
Mechanistic hypotheses linking COVID-19 vaccination or infection to oncogenic events
The case studies and emerging population-level data described above may represent an early signal of a possible association between vaccination or infection and cancer that warrants further investigation. This raises the question: if there is an association, what might be the mechanistic basis for it?
Viruses can cause cancer [
94–
97]. The relationship between viral infection and cancer has been well-documented for Human Papilloma Virus (HPV) that causes cervical cancer, head and neck cancer, as well as anal cancer that is increased among HIV-infected individuals. Hepatitis B Virus (HBV) and Hepatitis C Virus (HCV) cause liver cancer. Epstein Barr Virus (EBV) causes nasopharyngeal cancer, Burkitt’s Lymphoma, and other cancers. The human herpes virus KSHV/HHV-8 causes Kaposi’s sarcoma, the Human T-cell Leukemia Virus (HTLV-1) causes adult T-cell leukemia or lymphoma, and the Merkle Cell Virus (MCV) causes Merkle cell skin cancer. Several viruses are suspected of causing cancer including SV40 (mesothelioma, primary brain and bone cancers, among others) and HCMV (glioblastoma, medulloblastoma, breast, colon and prostate cancer). HIV is strongly associated with Kaposi’s sarcoma, cervical cancer, lymphoma, anal cancer, and other malignancies, largely though immunosuppression and co-infection with oncogenic viruses. It has been known for decades that viral proteins target host tumor suppressors such as p53 and Rb, suppress the immune system, and activate oncogenic signals.
In addition, the COVID mRNA vaccines work by instructing the target cells to produce the SARS-CoV-2 spike protein. This occurs by introducing a synthetic, modified mRNA (mod-mRNA) which incorporates non-natural pseudouridine into its coding region to prolongs the stability of the mRNA beyond that of natural mRNA. Introduction of the mod-RNA is accomplished using lipid-based transfection in the form of lipid nanoparticles (LNPs). The result is highly efficient transfection of the mod-mRNA into target cells with biochemical and pharmacological behavior different from naturally occurring mRNA. Consequently, the mod-RNA is transcribed into the foreign spike protein (as well as other frameshifted protein products), which elicits a robust immune response [
98–
102]. Given the stability of pseudouridine modified mRNA, along with the residual DNA in the mRNA vaccine formulations [
103–
108], the mRNA vaccines are delivering exogenous genetic material (DNA and RNA (in the form of engineered nucleic acids)) into a patient’s cells. The COVID19 mRNA vaccines produce Spike protein that is encoded by a stable mRNA and has been found to be long-lived in the human body [
109,
110]. These nucleic acid elements have been reported to contribute to Post-Covid Vaccine Syndrome (PCVS/PVS) [
110,
111]. Thus, these vaccines fit the definition of gene therapy [
112,
113]. Despite this, there are efforts by the EU to modify the definition of gene therapy to exempt mRNA vaccines from this category [
114].
While there are no studies demonstrating a direct causal mechanism by which the mRNA vaccines induce cancer, cumulative molecular effects from persistent spike protein [
115,
116], the immune activation and inflammation from repeated vaccination [
117–
119], or the potential for genomic integration events [
120] might contribute to events that could in theory manifest in cancers following vaccination or infection. Given the rapid onset of aggressive and rare tumors from the literature, cancers arising weeks to months after vaccination would be perhaps more consistent with mechanisms involving tumor promotion rather tumor initiation
per se. However, mechanisms involving initiation are also considered. Here we present least three biologically plausible mechanisms that might explain an association between COVID-19 vaccination and cancer; two of them overlapping with covid infection, immune dysfunction and spike protein biology, and reactions due to DNA impurities restricted to vaccination.
Immune dysregulation
The rapid appearance of cancer, the anatomical proximity of the tumors to vaccine sites, and the histologic signatures of inflammation the support immune mechanisms that promote the progression of latent clones rather than de novo carcinogenesis. We hypothesize two interrelated processes: localized inflammation and modulation of the tumor microenvironment with transient functional immunosuppression that relaxes immune surveillance. Might account for hyperprogression of latent or occult cancer cells (
Figure 5).
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