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Prognosis

Prognosis is the likely outcome or course of a disease, injury, or illness, encompassing the predicted progression, chance of recovery, or potential for recurrence.^[1] In medicine, it serves as a forecast based on clinical evidence to guide treatment decisions, patient counseling, and long-term planning.^[2] Several factors influence the accuracy and determination of a prognosis, including the specific type and stage of the condition, the patient's overall health, age, comorbidities, and response to treatments.^[2] Genetic and biological characteristics of the disease, as well as demographic elements like sex and ethnicity, also play significant roles in shaping these predictions.^[2] Prognostic assessments draw from extensive medical research, population statistics, and survival rates to provide informed estimates.^[2] Prognoses are often categorized by levels such as excellent, good, fair, or poor, reflecting the anticipated recovery or survival prospects.^[2] Terms like "guarded" may indicate uncertainty due to limited information, while projections can be expressed in time frames (e.g., five-year survival) or as best- and worst-case scenarios.^[2] These evaluations are not fixed and can evolve with new diagnostic data, therapeutic advancements, or changes in the patient's condition.^[2] Beyond clinical settings, prognosis extends to broader health trajectories, informing not only survival but also quality of life and functional status.^[3] It empowers patients by offering realistic expectations, facilitating informed choices about interventions like palliative care or aggressive therapies.^[2] Accurate prognostication relies on integrating individual patient data with evidence from prognostic studies, which analyze outcomes across diverse populations.^[3]

Definition and Fundamentals

Core Definition

In medicine, prognosis refers to the predicted course, duration, and likely outcome of a disease, injury, or health condition, based on current medical knowledge and evidence.^[2] It provides an informed estimate of how the condition may progress, including the potential for recovery, remission, or deterioration, and is essential for guiding treatment decisions and patient counseling.^[4] The term originates from the Greek prognōsis, meaning "foreknowledge," derived from pro- ("before") and gignōskein ("to know"), underscoring its role in anticipating future health trajectories through clinical foresight.^[5] Unlike a diagnosis, which identifies and confirms the presence of a specific disease or condition through examination and testing, prognosis focuses on future expectations rather than current identification.^[6] It also differs from a general forecast or prediction, as it is grounded in medical specificity, incorporating factors like disease stage and response to therapy, rather than broad speculation.^[7] Prognoses are often categorized by time frame or outlook; for instance, a short-term prognosis might assess recovery within weeks or months, while a long-term one evaluates outcomes over years.^[2] Favorable prognoses suggest a high likelihood of positive resolution, such as full recovery, whereas unfavorable ones indicate risks of progression or complications.^[4] These assessments typically rely on established prognostic indicators to inform accuracy.^[4]

Historical Context in Medicine

The concept of prognosis emerged as a fundamental aspect of medical practice in ancient Greece through the Hippocratic Corpus, a collection of approximately 60-70 medical texts compiled around 400 BCE and attributed to Hippocrates of Cos and his followers. These works elevated prognosis to one of the core arts of medicine, alongside diagnosis and treatment, emphasizing the physician's role in predicting disease outcomes based on careful observation of symptoms, patient history, and environmental influences rather than supernatural causes. Prognostication was deemed more valuable than therapy in some contexts, as it allowed physicians to advise on the likely course of illness and prepare patients accordingly; for instance, the text Prognostic details signs like facial color, breathing, and sputum to forecast recovery or death. The Aphorisms, another key component, offer concise prognostic rules, such as the observation that laborious sleep signals a deadly symptom, while restorative sleep indicates improvement.^[8]^[9] In the medieval era, Islamic scholars preserved and expanded Greek medical traditions, prominently integrating prognosis with humoral theory in systematic treatises. Avicenna (Ibn Sina), a Persian polymath, synthesized these ideas in his Canon of Medicine (completed in 1025 CE), a comprehensive encyclopedia that became the standard medical reference in Europe and the Islamic world for centuries. The work's first book outlines the four humors—blood, phlegm, yellow bile, and black bile—as central to health, with prognosis involving the assessment of humoral imbalances to predict disease progression and outcomes; for example, excess black bile was linked to melancholy and poor prognosis if untreated. Avicenna stressed empirical signs alongside humoral analysis for accurate forecasting, influencing prognostic practices by providing structured methods to evaluate temperament, pulse, urine, and symptoms, thereby bridging ancient observation with more organized medieval scholarship.^[10]^[11] The Renaissance (14th-17th centuries) marked a pivotal shift toward empirical methods in medicine, with anatomists like Andreas Vesalius and William Harvey prioritizing direct observation over astrological or purely theoretical predictions. Vesalius' De Humani Corporis Fabrica (1543) relied on human dissections to correct Galenic errors, enabling more precise understandings of anatomy that informed prognostic judgments on surgical risks and disease effects. Harvey's Exercitatio Anatomica de Motu Cordis et Sanguinis in Animalibus (1628) demonstrated blood circulation through vivisections and experiments, replacing humoral speculations with mechanistic explanations that improved predictions of cardiovascular outcomes. This emphasis on verifiable evidence gradually diminished reliance on astrology-influenced prognostication prevalent in medieval texts. By the 18th century, Enlightenment figures furthered this transition, advocating probabilistic and observational approaches; for instance, British clinicians like George Fordyce promoted critical evaluation of evidence in An Attempt to Improve the Evidence of Medicine (1783), fostering evidence-based prognostic reasoning that laid foundations for modern clinical practice.^[12]^[13]

Methodological Foundations

Prognostic Indicators

Prognostic indicators encompass a range of biological, clinical, and pathological markers that inform the anticipated course and outcome of diseases, particularly in oncology and chronic conditions. These indicators are essential for stratifying patients into risk groups and guiding therapeutic decisions, drawing from established categories that include clinical observations, laboratory measurements, imaging findings, and histopathological assessments. By evaluating these markers, clinicians can estimate survival probabilities and disease progression, though their interpretation requires context-specific validation from large-scale studies. Clinical prognostic indicators primarily involve observable symptoms and vital signs that reflect a patient's overall functional status and physiological stability. For instance, the Eastern Cooperative Oncology Group (ECOG) performance status scale evaluates a patient's ability to perform daily activities, with higher scores (indicating greater impairment) strongly correlating with reduced progression-free survival and overall survival in advanced cancer cohorts.^[14] Vital signs, such as elevated respiratory rates or hypotension, also serve as early harbingers of deterioration in acutely ill patients, predicting higher mortality risks in conditions like sepsis or palliative care settings.^[15] Symptoms like unexplained weight loss or fatigue further contribute to prognostic models by signaling systemic disease burden, as evidenced in multicenter evaluations of hospitalized patients.^[16] Laboratory-based indicators focus on quantifiable biomarkers in blood or other fluids that signal disease activity or response to therapy. Prostate-specific antigen (PSA) levels exemplify this category in prostate cancer, where elevated or rising PSA post-treatment predicts recurrence and poorer long-term outcomes independent of other factors.^[17] Similarly, elevated lactate dehydrogenase (LDH) levels in non-Hodgkin lymphoma patients indicate increased tumor burden and aggressive disease, associating with reduced response to chemotherapy and shorter survival durations across histological subtypes.^[18] These biomarkers are routinely integrated into risk stratification, with thresholds derived from prospective cohort analyses showing their independent prognostic value when adjusted for stage and comorbidities.^[19] Imaging indicators utilize radiological techniques to visualize structural changes, such as tumor dimensions assessed via magnetic resonance imaging (MRI), which provide non-invasive prognostic insights. In cervical cancer, MRI-measured tumor size greater than 4 cm correlates with diminished disease-specific survival and higher recurrence rates, outperforming clinical palpation in accuracy.^[20] These metrics help delineate local invasion and response to neoadjuvant therapy, informing adjustments in treatment intensity based on volumetric reductions observed in follow-up scans.^[21] Histopathological indicators derive from tissue analysis and are pivotal for detailed disease classification. The tumor-node-metastasis (TNM) staging system, developed by the American Joint Committee on Cancer, categorizes malignancies by primary tumor extent (T), regional lymph node involvement (N), and distant metastasis (M), directly linking higher stages to worse prognosis across solid tumors like lung and breast cancer.^[22] For example, in small cell lung cancer, TNM stages effectively delineate survival differences in real-world cohorts, with stage IV patients exhibiting median survival under 12 months compared to over 24 months for stage I.^[23] Pathological grading within TNM further refines predictions by incorporating cellular differentiation and mitotic activity.^[24] In multifactorial prognostic assessment, these indicators are weighted and combined based on evidence from longitudinal cohort studies, where relative contributions are quantified through multivariate analyses to enhance predictive accuracy beyond single markers. For instance, tumor-related factors like TNM stage often carry greater weight than host-related clinical signs in oncology models, as demonstrated in comprehensive reviews of prognostic factor integration. This approach allows for personalized risk profiles, such as in older adults where combining ECOG status with laboratory biomarkers improves mortality forecasts over univariate assessments.^[25] Despite their utility, prognostic indicators exhibit limitations, including substantial variability in their predictive strength across disease types and populations, necessitating disease-specific validation to avoid overgeneralization. Moreover, isolated use often underperforms compared to integrated models, as single indicators like LDH may overlook confounding influences, underscoring the need for multimodal data fusion in clinical practice.^[26] Overinterpretation of these markers without rigorous cohort-derived evidence can also lead to biased decision-making, highlighting ongoing challenges in standardization.^[27]

Statistical and Modeling Techniques

Statistical and modeling techniques form the quantitative backbone of prognostic assessment in medicine, enabling the derivation of survival probabilities and risk estimates from clinical data. These methods process prognostic indicators—such as patient demographics, biomarkers, and disease characteristics—into predictive models that account for time-to-event outcomes, often handling censored data where the event of interest (e.g., death or recurrence) is not observed for all subjects. Central to these approaches is survival analysis, which focuses on the time until an adverse event occurs, providing tools to estimate and compare survival distributions across patient groups.^[28] A foundational concept in survival analysis is the survival function, which quantifies the probability that an individual survives beyond a given time t. Mathematically, it is expressed as

S(t) = \exp\left(-\int_0^t \lambda(u) \, du\right),

where \lambda(u) represents the hazard function, or the instantaneous rate of the event occurring at time u given survival up to that point. This non-increasing function decreases from 1 to 0 as t increases, reflecting the cumulative risk over time; the integral in the exponent captures the cumulative hazard H(t) = \int_0^t \lambda(u) \, du, allowing for flexible modeling of varying risks.^[29] For non-parametric estimation of the survival function from observed data, the Kaplan-Meier estimator is widely used, particularly for time-to-event data with censoring. It constructs a step function by multiplying conditional survival probabilities at each observed event time, providing an intuitive visualization via Kaplan-Meier curves that compare survival across cohorts without assuming an underlying distribution. Introduced in 1958, this method remains a staple for initial exploratory analysis in prognostic studies due to its simplicity and robustness.^[30] To incorporate covariates and quantify their impact on survival, semi-parametric models like the Cox proportional hazards model extend these techniques. The model assumes that the effects of predictors are multiplicative on the hazard scale, formulated as

h(t \mid X) = h_0(t) \exp(\beta^T X),

where h_0(t) is the baseline hazard function (unspecified), X are the covariates, and \beta are the regression coefficients yielding hazard ratios \exp(\beta_j) that indicate relative risk changes per unit increase in X_j. Developed in 1972, the Cox model has revolutionized prognostic modeling by enabling risk stratification while avoiding parametric assumptions about the baseline hazard, with applications spanning oncology and cardiology.^[31] Prognostic indices aggregate multiple indicators into composite scores or visual tools for clinical risk assessment. Scoring systems, such as the Acute Physiology and Chronic Health Evaluation II (APACHE II), assign points to physiological variables, age, and comorbidities to predict hospital mortality in intensive care patients, with scores ranging from 0 to 71 correlating to rising risk probabilities. Nomograms, graphical representations of regression models, allow users to plot covariate values along axes to derive personalized survival estimates, often outperforming traditional staging in cancer prognosis by integrating continuous variables.^[32]^[33] Advancements in machine learning have introduced data-driven approaches to handle high-dimensional and nonlinear relationships in prognostic datasets, surpassing traditional models in predictive accuracy for complex scenarios. Random forests, ensemble methods combining multiple decision trees, excel at feature selection and reducing overfitting, yielding robust survival predictions by averaging hazard estimates across trees. Neural networks, particularly deep learning variants, capture intricate interactions through layered architectures, enabling end-to-end learning from electronic health records for tasks like recurrence risk in oncology, though they require large datasets to mitigate interpretability challenges. Recent reviews highlight their integration with survival analysis, such as random survival forests, achieving superior calibration in multicenter studies.^[34]^[35]

Prognostic Tools and Estimation

Types of Prognostic Estimators

Prognostic estimators encompass a range of tools used to quantify the probability of disease progression, complications, or mortality, often integrating clinical, laboratory, and demographic data. These estimators are broadly classified into risk scores, staging systems, and predictive models, each tailored to particular diseases or patient populations to facilitate clinical decision-making.^[36] Risk scores are simplified algorithms that aggregate multiple risk factors into a single numerical value to estimate short- or long-term outcomes. A prominent example is the Framingham Risk Score, developed to predict the 10-year risk of coronary heart disease events such as myocardial infarction or coronary death in adults without prior cardiovascular disease. It incorporates variables like age, sex, total cholesterol, HDL cholesterol, systolic blood pressure, smoking status, and diabetes, assigning points to each to yield a total score that corresponds to risk categories ranging from low (<10%) to high (>30%). This score has been widely adopted in primary care for guiding preventive interventions.^[36] Staging systems provide a structured classification of disease extent, correlating anatomical spread with expected survival and treatment response. The American Joint Committee on Cancer (AJCC) TNM staging system is a cornerstone for oncology, evaluating tumors based on size (T), lymph node involvement (N), and metastasis (M) to assign stages from 0 (in situ) to IV (advanced). For instance, in breast cancer, stage I indicates a small tumor without nodal spread, associated with >90% 5-year survival, while stage IV signifies distant metastasis with poorer prognosis. The AJCC system, updated periodically, integrates these elements to standardize prognosis across cancer types and inform therapeutic strategies.^[37] Predictive models employ mathematical formulas derived from statistical analyses to forecast outcomes using laboratory and clinical parameters. The Model for End-Stage Liver Disease (MELD) score exemplifies this approach for assessing mortality risk in patients with advanced liver disease awaiting transplantation. The formula is:

\text{MELD} = 3.78 \times \ln(\text{serum bilirubin (mg/dL)}) + 11.2 \times \ln(\text{INR}) + 9.57 \times \ln(\text{serum creatinine (mg/dL)}) + 6.43

where values are capped (e.g., creatinine at 4 mg/dL) to avoid extremes; higher scores (>30) indicate greater 3-month mortality risk, up to 70% or more. Developed from survival data in cirrhotic patients, MELD prioritizes organ allocation based on urgency.^[38] Disease-specific estimators further refine predictions for targeted conditions, such as community-acquired pneumonia. The CURB-65 score, a validated tool for assessing severity and 30-day mortality, assigns one point each for confusion, urea >7 mmol/L, respiratory rate ≥30/min, blood pressure (systolic <90 mmHg or diastolic ≤60 mmHg), and age ≥65 years; scores of 0-1 suggest low risk (<3% mortality, suitable for outpatient management), while ≥3 indicates high risk (>17% mortality, warranting hospitalization). This simple bedside tool integrates readily available indicators to guide antibiotic and admission decisions. Digital tools enhance accessibility and personalization of these estimators through software applications. PredictMD.jl, an open-source Julia package, enables the development and deployment of machine learning-based predictive models for clinical outcomes, automating workflows from data preprocessing to model validation. It supports integration of diverse datasets, such as electronic health records, to generate individualized prognosis estimates, for example, in predicting postoperative complications. Such platforms facilitate real-time calculations and scenario testing in clinical settings.^[39] These estimators often integrate prognostic indicators—such as biomarkers or vital signs—with underlying statistical techniques like logistic regression or survival analysis to produce reliable forecasts. For instance, risk scores like Framingham combine additive point systems derived from Cox proportional hazards models, while predictive models like MELD use continuous variables in logarithmic transformations for precision. This synthesis allows clinicians to layer multiple data sources, improving the granularity of prognosis without requiring advanced computational expertise.^[38]^[36]

Validation and Accuracy Assessment

Validation of prognostic tools involves rigorous testing to ensure their reliability and applicability in clinical settings. Internal validation techniques, such as k-fold cross-validation, assess model performance by partitioning the development dataset into subsets, training the model on k-1 subsets, and testing on the remaining subset, repeating this process k times to estimate generalizability and reduce bias from single splits.^[40] Discrimination, the ability to distinguish between individuals who experience the event and those who do not, is commonly evaluated using receiver operating characteristic (ROC) curves, where the area under the curve (AUC) quantifies overall performance, with values closer to 1 indicating better discrimination.^[41] Calibration, which measures the agreement between predicted probabilities and observed outcomes, is visualized through calibration plots that compare predicted risks against observed event rates, ideally forming a straight line at 45 degrees for perfect calibration; deviations highlight systematic over- or under-prediction.^[42] Key performance metrics include sensitivity (true positive rate) and specificity (true negative rate), which evaluate the model's ability to correctly identify event occurrences and non-occurrences, respectively, often balanced via ROC analysis to optimize thresholds for clinical use.^[41] For survival models, the concordance index (C-index), also known as Harrell's C, serves as a primary measure of discrimination, defined as the proportion of all possible patient pairs where the predicted survival times align with the observed order:

C = \frac{\text{number of concordant pairs}}{\text{total number of comparable pairs}}

Here, concordant pairs are those where the patient with the higher predicted risk has a shorter observed survival time, accounting for censoring; a C-index of 0.5 indicates random prediction, while values approaching 1 demonstrate strong predictive ordering. Despite these methods, challenges persist in prognostic model validation. Overfitting occurs when models perform well on training data but poorly on new data due to excessive complexity, often mitigated through regularization or validation techniques, yet it remains a common issue in high-dimensional datasets.^[43] External validation, testing models on independent datasets from different populations, is essential for confirming generalizability but is frequently underutilized; for instance, systematic reviews of cancer recurrence models reveal that many nomograms exhibit diminished accuracy outside their development cohorts, with C-indices dropping by 0.05-0.10 in external tests due to variations in patient demographics or treatment practices.^[44] Studies on ovarian cancer nomograms have similarly shown moderate external performance, underscoring the need for multi-center validation to address these limitations.^[45] Regulatory frameworks have evolved to address validation for AI-based prognostic tools, particularly post-2020. The U.S. Food and Drug Administration (FDA) emphasizes robust clinical validation in its 2021 AI/ML-Based Software as a Medical Device (SaMD) Action Plan, requiring premarket submissions to include performance metrics like sensitivity, specificity, and calibration, alongside external validation to demonstrate safety and effectiveness across diverse populations. Updated guidelines, including the 2024 finalized Predetermined Change Control Plans, mandate lifecycle management for adaptive AI models, ensuring ongoing re-validation as algorithms evolve to maintain accuracy in prognostic applications such as risk stratification for chronic diseases.

Influencing Factors

Patient-related variables play a crucial role in determining prognosis across various medical conditions, encompassing demographic characteristics, lifestyle behaviors, genetic predispositions, and physiological responses that interact to influence disease outcomes. These factors help clinicians tailor prognostic assessments to individual patients, accounting for personal attributes that can either mitigate or exacerbate the course of illness. Demographic factors such as age and sex significantly impact prognosis in chronic diseases. Advanced age is associated with poorer outcomes due to reduced physiological reserve and higher vulnerability to complications, as evidenced in studies of cardiovascular and respiratory conditions where older patients exhibit increased mortality risks. Sex differences also modulate prognosis; for instance, in heart failure, male sex predicts higher mortality in older patients, while females may experience distinct trajectories influenced by hormonal and biological variances. Comorbidities further compound these effects, with tools like the Charlson Comorbidity Index providing a weighted scoring system to quantify the cumulative impact of concurrent conditions on one-year mortality risk, originally validated in longitudinal studies of diverse patient cohorts.^[46] Higher scores on this index correlate with elevated risks in conditions ranging from cancer to infectious diseases, enabling stratified prognostic predictions. Lifestyle and behavioral elements, including smoking status, treatment adherence, and socioeconomic factors, are modifiable variables that directly affect prognosis. Smoking consistently worsens outcomes across multiple diseases by promoting inflammation and vascular damage; epidemiological data indicate it increases the risk of coronary heart disease mortality by 2 to 4 times and impairs recovery in infectious and pulmonary conditions.^[47] Poor adherence to prescribed treatments leads to suboptimal health outcomes, with meta-analyses showing that adherent patients, even to placebo regimens, experience better survival and reduced complications compared to non-adherent individuals. Socioeconomic status influences prognosis through barriers to care access; lower status is linked to higher mortality rates in critical illnesses and cancers, as individuals face delays in diagnosis and treatment due to financial and logistical constraints.^[48] Genetic and physiological factors introduce inherent variability in host responses that shape prognosis. Host genetics, such as BRCA1/2 mutations, confer specific risks and outcomes in cancers; in breast cancer, these mutations are associated with higher rates of contralateral disease (up to 40% at 10 years) but may predict better responses to certain therapies like PARP inhibitors.^[49] Immune response variability, driven by genetic polymorphisms and host immunity profiles, serves as a prognostic marker; robust immune infiltration, as quantified by tools like Immunoscore, correlates with improved survival in solid tumors by enhancing anti-tumor activity, while deficient responses predict poorer outcomes.^[50] Holistically, these patient-related variables modify baseline disease prognosis by interacting with pathological processes, amplifying risks in comorbid or low-adherence scenarios while offering opportunities for intervention in modifiable areas like smoking cessation. For example, a scoping review of physician prognostic judgments highlights how age, sex, and comorbidities cluster to influence overall predictions, underscoring the need for integrated assessments that briefly consider disease-specific elements without overshadowing individual traits.^[51] This multifaceted approach ensures more accurate, personalized prognostic evaluations in clinical practice.

Disease and Environmental Factors

Disease-specific characteristics, such as stage, grade, and subtype, profoundly influence prognosis across various malignancies by reflecting the extent of tumor spread, aggressiveness, and biological behavior. In breast cancer, tumor stage at diagnosis remains a significant predictor of overall survival, with advanced stages correlating to reduced five-year survival rates even in the era of targeted therapies. Similarly, histologic grade, which assesses tumor differentiation and proliferation, independently impacts survival endpoints; higher-grade tumors in endometrial carcinoma, for instance, are associated with increased recurrence risk and poorer outcomes. Subtypes further modulate prognosis, as exemplified by HER2 status in breast cancer, where HER2-positive tumors historically conferred a worse prognosis due to aggressive growth but now achieve over 90% early-stage survival with anti-HER2 therapies like trastuzumab.^[52]^[53]^[54]^[55] Environmental factors external to the patient, including access to healthcare, exposure to pollutants, and infectious agents, can alter disease trajectories and outcomes by delaying intervention or exacerbating pathology. Limited access to timely care, often tied to socioeconomic disparities, leads to later-stage diagnoses and inferior survival; for example, lower socioeconomic status is linked to reduced screening uptake and higher mortality across cancers due to barriers in treatment initiation.^[56] Exposure to air pollutants, such as particulate matter (PM10), worsens prognosis in respiratory and other cancers by promoting inflammation and metastasis; a 2024 study found that long-term exposure increases all-cause mortality by 28% (HR = 1.28, 95% CI = 1.02–1.62) per 5 μg/m³ increment in PM10 among individuals with colorectal cancer.^[57] Infectious agents like human papillomavirus (HPV) and human immunodeficiency virus (HIV) modify outcomes in associated cancers—HPV persistence drives cervical cancer progression, while HIV co-infection accelerates immunosuppression and raises cervical cancer risk through enhanced viral oncogenesis.^[58]^[59] Interactions between disease characteristics and treatments further shape prognosis, particularly through response variability that can confer resistance and limit efficacy. In aggressive lymphomas, such as diffuse large B-cell lymphoma, chemotherapy resistance—often driven by genetic rearrangements like MYC/BCL-2—results in refractory disease and dismal two-year overall survival rates of 20-40%, underscoring the need for novel targeted agents.^[60] Epidemiological disruptions, like the COVID-19 pandemic, have indirectly worsened prognoses by causing care delays; for instance, postponed surgeries and treatments in early-stage cancers led to tumor upstaging and an estimated excess of thousands of attributable deaths annually due to diagnostic and therapeutic interruptions.^[61]^[62]

Clinical Applications

Communication of Prognosis

Effective communication of prognosis in clinical settings involves balancing clarity, empathy, and accuracy to support patient understanding and decision-making. Clinicians often employ numerical strategies, such as stating "5-year survival rate of 70%," which provide concrete data but can be misinterpreted without context, or verbal approaches like "good chance of recovery," which may foster hope but risk vagueness. Decision aids, including visual tools like survival curves or interactive apps, enhance comprehension by illustrating probabilities and personalizing information based on patient variables.^[63] These methods align with recommendations from the American Society of Clinical Oncology (ASCO), which emphasize eliciting patient preferences early and using shared decision-making to tailor discussions.^[64] Challenges in conveying prognosis include articulating inherent uncertainties, such as variable disease trajectories, without eroding trust or instilling undue fear. Poor handling of uncertainty—through avoidance or overly optimistic framing—can lead to false hope, delaying realistic planning, while cultural differences may influence preferences for directness, with some patients favoring family mediation.^[65]^[66] ASCO guidelines advocate for "ask-tell-ask" techniques: inquiring about patient understanding, providing information responsively, and confirming comprehension to mitigate these issues.^[64] The psychological effects of prognosis communication significantly influence patient well-being, with empathetic, patient-centered delivery reducing anxiety and enhancing informed consent compared to directive styles. For instance, explicit discussions of prognosis correlate with lower distress when framed positively alongside uncertainties, promoting adaptive coping.^[67]^[63] Conversely, ambiguous or pessimistic conveyance can heighten anxiety, underscoring the need for training in skills like normalization of emotions to support psychological adjustment.^[68]

End-of-Life and Palliative Integration

In the context of end-of-life care, prognostic tools such as the Palliative Prognostic (PaP) score play a critical role in determining the appropriate timing for hospice referrals. The PaP score integrates factors including performance status, clinical symptoms (e.g., anorexia and dyspnea), and white blood cell count to stratify patients into three risk groups based on 30-day survival probabilities: greater than 70% for low-risk, 30-70% for medium-risk, and less than 30% for high-risk patients.^[69] Validation studies have confirmed its accuracy in terminally ill populations, with observed 30-day survival rates of approximately 82% in the low-risk group, 53% in the medium-risk group, and 10% in the high-risk group, enabling clinicians to initiate hospice services when survival is estimated at weeks to months.^[70] This prognostic stratification supports timely transitions to hospice, optimizing resource allocation and aligning care with the patient's anticipated decline. Prognosis informs key palliative applications, particularly advance care planning (ACP) and symptom management tailored to the disease trajectory. In ACP, patients and families discuss goals of care informed by prognostic estimates, facilitating decisions on interventions like resuscitation or mechanical ventilation that align with expected survival and quality of life; this process enhances patient autonomy and reduces unwanted treatments at life's end.^[71] For instance, when prognosis indicates limited life expectancy, ACP conversations often prioritize comfort over aggressive therapies, leading to documented advance directives that guide care during acute exacerbations.^[72] Similarly, symptom management in palliative care is adjusted to the anticipated trajectory, such as escalating opioid titration for pain in progressive decline or prophylactic interventions for foreseeable complications like dyspnea in advanced respiratory disease, thereby maintaining comfort as functional status deteriorates.^[73] These applications ensure that care remains proactive and patient-centered, minimizing suffering throughout the end-of-life phase. Ethical considerations in integrating prognosis with end-of-life care center on decisions to withhold or withdraw life-sustaining treatments in cases of poor prognosis, balanced against principles of autonomy and non-maleficence. Withholding treatments, such as mechanical ventilation or dialysis, is ethically justified when the prognosis for meaningful recovery is dismal and the intervention would only prolong dying without restoring quality of life, as determined through shared decision-making with patients or surrogates.^[74] This approach avoids futile care, respecting the patient's values while preventing undue burden on families and resources.^[75] A related tension arises between the patient's right to know their prognosis—to exercise informed autonomy in planning—and therapeutic privilege, where disclosure might be temporarily withheld if it risks severe psychological harm, such as precipitating decompensation in a frail individual.^[76] However, therapeutic privilege is narrowly applied, requiring multidisciplinary consultation, and full disclosure is generally prioritized to foster trust and enable meaningful end-of-life discussions.^[77] Recent international guidelines underscore the importance of prognostic awareness in global palliative care integration. The 2024 American Society of Clinical Oncology (ASCO) guidelines recommend routine palliative care referrals at diagnosis for cancers with poor prognosis (e.g., advanced lung cancer), emphasizing early prognostic communication to support advance planning and symptom control worldwide.^[78] This aligns with broader efforts, such as the World Health Organization's ongoing framework for palliative care, which promotes prognostic-informed strategies to address unmet needs in low- and middle-income countries, the majority of whom live in low- and middle-income countries.^[79] These updates highlight the need for culturally sensitive prognostic discussions to enhance equity in end-of-life care delivery.^[80]

Evolution and Future Directions

Historical Development

The 19th century marked a pivotal shift in prognostic practices through foundational advances in pathology and clinical medicine. Rudolf Virchow's seminal work, Cellular Pathology (1858), established that diseases originate from alterations in cells rather than systemic imbalances, enabling physicians to base prognoses on histopathological examinations of tissues for more precise predictions of disease progression and outcomes.^[81] This cellular approach transformed prognosis from speculative judgment to evidence derived from microscopic analysis, influencing fields like oncology where tissue grading became essential for forecasting survival.^[82] In the late 1800s, William Osler further emphasized clinical integration in prognosis through his textbook The Principles and Practice of Medicine (1892), which systematically included dedicated sections on prognosis for each disease, combining bedside observations, symptoms, and pathology to inform realistic expectations and treatment decisions.^[83] The 20th century saw the formalization of prognostic tools through staging systems and statistical methods. In 1932, pathologist Cuthbert Dukes introduced the first staging classification for colorectal cancer, categorizing cases by tumor invasion depth and lymph node status (A, B, C stages), which standardized predictions of surgical success and five-year survival rates, setting a precedent for site-specific prognostication.^[84] Following World War II, survival analysis gained prominence in medicine, driven by post-war interests in reliability engineering and clinical trials; techniques like the Kaplan-Meier estimator (1958) allowed for non-parametric estimation of survival probabilities over time, revolutionizing prognostic accuracy in chronic diseases by accounting for censored data.^[85] A key milestone was the Union for International Cancer Control's (UICC) adoption of the TNM staging system in the 1950s, originally developed by Pierre Denoix in the 1940s to assess tumor size (T), nodal involvement (N), and metastasis (M); this anatomically based framework provided a universal prognostic benchmark, with revisions such as the 8th edition in 2017 incorporating molecular factors for refined predictions.^[86] In the late 20th and early 21st centuries, evidence-based medicine (EBM) and computational advances elevated prognostic rigor. The widespread use of randomized controlled trials (RCTs), popularized from the mid-20th century onward, underpinned EBM's emergence in the 1990s, enabling systematic synthesis of trial data to develop validated prognostic models that improved outcome forecasting beyond anecdotal experience.^[87] By the 2010s, the rise of big data analytics integrated vast electronic health records, genomic datasets, and machine learning algorithms to generate personalized prognoses, enhancing predictive power for disease trajectories and treatment responses in real-time clinical settings.^[88] These developments built upon ancient prognostic traditions, evolving from qualitative assessments to data-driven precision.

Emerging Trends and Challenges

Recent advancements in artificial intelligence (AI) have revolutionized prognostic estimation in medicine, particularly through deep learning models applied to radiology imaging for outcome prediction. For instance, deep learning algorithms integrated with chest X-ray analysis have demonstrated significant improvements in physician accuracy for detecting abnormalities associated with poor prognosis, achieving approximately 13% higher sensitivity in identifying critical conditions like pneumonia or cardiac issues when used as decision support tools.^[89] Similarly, AI-enhanced radiomic nomograms in oncology have outperformed traditional clinical models in predicting tumor progression and survival, with studies showing enhanced prognostic precision for various cancers.^[90] Complementing these, next-generation sequencing (NGS) enables comprehensive genomic profiling for precision prognostic predictions, identifying actionable mutations that refine risk stratification in advanced cancers. ESMO guidelines from 2024 recommend NGS for patients with metastatic solid tumors to guide targeted therapies, and such profiling improves survival forecasts.^[91] Real-world data indicate that NGS integration has led to increased precision therapy adoption in clinical settings.^[92] In 2025, AI advancements include machine learning models for early disease detection before symptoms appear and integration of large language models for personalized prognostic forecasting.^[93] Despite these innovations, significant challenges persist, including biases in AI datasets that undermine prognostic reliability. Underrepresentation of minority groups in training data has been identified as a primary source of algorithmic bias, leading to lower predictive accuracy for non-White populations in healthcare AI models; a 2024 review found that such biases affect up to 82% of cardiovascular prognostic tools across racial and ethnic lines.^[94] Additionally, data privacy concerns under regulations like GDPR and HIPAA complicate AI deployment in prognostic applications, as the processing of sensitive health data for model training risks breaches and requires stringent anonymization techniques. The WHO has emphasized that AI systems handling personal health information must incorporate robust privacy-preserving methods, such as federated learning, to comply with global standards and prevent unauthorized access.^[95] Techniques like differential privacy and secure multi-party computation are emerging to mitigate these issues, though their implementation remains uneven in prognostic tools.^[96] Equity issues exacerbate these challenges, with studies revealing disparities in prognostic accuracy across socioeconomic groups, particularly in AI-driven models. Low-income patients experience higher error rates in AI prognostic predictions due to socioeconomic biases embedded in datasets, which often overlook access barriers and environmental factors influencing outcomes. In cancer care, socioeconomic status correlates with inferior survival forecasts, as lower SES groups face delayed diagnostics and underrepresented data, widening gaps in prognostic equity; for example, breast cancer mortality disparities persist between socioeconomic groups.^[97] Looking ahead, future directions include the development of real-time prognostic applications integrated with wearable devices for dynamic health monitoring. AI-powered wearables are enabling predictive analytics by analyzing continuous physiological data, such as heart rate variability and activity levels, to forecast disease exacerbations in real time, with potential applications in chronic conditions like heart failure.^[98] This integration promises personalized, adaptive prognostic updates, though it necessitates addressing scalability and interoperability challenges to ensure broad clinical adoption.^[99]

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(prog-NO-sis) The likely outcome or course of a disease; the chance of recovery or recurrence. More InformationMissing: authoritative sources
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Prognosis - an overview | ScienceDirect Topics
Prognosis is a description of the probable course or prediction of the outcome of a health condition over time. Important to prognosis is consideration and ...
[5]
Prognosis - Etymology, Origin & Meaning
Originating in the 1650s from Greek prognōsis meaning "foreknowledge," prognosis refers to the predicted course and likely outcome of a disease or ...<|control11|><|separator|>
[6]
Diagnosis vs. Prognosis: What's The Difference? - Merriam-Webster
In prep, the main difference is temporal: a diagnosis involves on-site examination and a prognosis is a prediction of what's to come.
[7]
"Prognosis" vs. "Diagnosis" – What's The Difference? - Dictionary.com
May 12, 2022 · In general usage, diagnosis refers to an assessment of what the problem is with something, while prognosis can refer to any prediction. What ...
[8]
Utility of Hippocrates' prognostic aphorism to predict death in ... - NIH
Dec 15, 2014 · One of the hippocratic aphorisms on prognosis stated that good appetite and good cognition were favourable prognostic factors. Poor cognition ...
[9]
The Air of History: Early Medicine to Galen (Part I) - PMC - NIH
The most common cure for maladies was probably the amulet or magic spell rather than medical prescriptions alone since many illnesses tended to be regarded as ...
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Reflections on Avicenna's impact on medicine: his reach beyond the ...
This report focuses on Avicenna's advancements in the medical field, and how there is more to the history of medicine than Hippocrates and the western ...Missing: prognosis | Show results with:prognosis
[11]
The Place of Avicenna in the History of Medicine - PMC - NIH
Medicine is one of the scientific dimensions of influence by Avicenna which dominated the world of medical science for at least six centuries (11th to 17th ...Missing: prognosis | Show results with:prognosis
[12]
Medicine from Galen to the Present: A Short History - PMC - NIH
THE RENAISSANCE Doctors such as Andreas Vesalius and William Harvey influenced by earlier cultures began to experiment and to develop new ideas about anatomy ...Missing: empirical | Show results with:empirical
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EVIDENCE BASED MEDICINE: AN OVERVIEW - PMC
Publications in the 18th century calling for a more critical evidence-based approach to medicine included an “attempt to improve the evidence of medicine” by ...Missing: transition | Show results with:transition
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Association of Performance Status With Survival in Patients ... - NIH
Feb 11, 2021 · In this cohort study of 74 patients, those with ECOG performance status of at least 2 had significantly lower disease control, progression-free survival, and ...
[15]
Vital Signs in Palliative Care: A Scoping Review - MDPI
Sep 20, 2023 · This review highlights that measuring vital signs for patients with cancer who are receiving palliative care may be of some benefit in determining prognosis.
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Prognostic factors for predicting severity and mortality in hospitalized ...
Jan 25, 2022 · Vital signs at presentation represent an important indication of severity, used to decide on the therapeutic plan and to monitor patients who ...3 Results · 3.2 Vital Signs And... · 4 Discussion
[17]
Prognostic and predictive biomarkers in prostate cancer - NIH
Prognostic markers aim to evaluate objectively the patient's overall outcome, such as the probability of cancer recurrence after standard treatment. The ...
[18]
The utility of lactate dehydrogenase in the follow up of patients with ...
High LDH activity at the time of lymphoma diagnosis reflects increased tumor bulk and predicts a less favorable prognosis irrespective of the histologic subtype ...<|separator|>
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Serum lactate dehydrogenase (LDH) as a prognostic index for non ...
Normal values of LDH were associated with a better response to therapy and a longer survival, independent of histological type and clinical stage.
[20]
Prognostic impact of tumor size reduction assessed by magnetic ...
Dec 2, 2022 · Moreover, tumor size estimated by clinical palpation or using MRI measurements is an important prognostic factor in cervical cancer (20, 21).
[21]
What MRI-based tumor size measurement is best for predicting long ...
Jun 17, 2022 · MAX imaging ≥ 4.0 cm represents the optimal cutoff for predicting long-term disease-specific survival in cervical cancer.
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TNM Classification - StatPearls - NCBI Bookshelf - NIH
The TNM Classification is a system for classifying a malignancy. It is primarily used in solid tumors and can assist in prognostic cancer staging.Definition/Introduction · Issues of Concern · Clinical Significance
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Prognostic Value of Clinical Staging According to TNM in Patients ...
Conclusions. TNM staging seems to define prognosis in patients with SCLC in the real-world setting, particularly for those patients with earlier disease.
[24]
Tumor, node, metastasis (TNM) staging system for lung cancer
Oct 6, 2025 · The TNM system combines features of the tumor into stage groups that correlate with prognosis and are often linked to treatment recommendations.
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Prognostic Indices for Older Adults: A Systematic Review
Jan 11, 2012 · We reviewed 21 593 titles to identify 16 indices that predict risk of mortality from 6 months to 5 years for older adults in a variety of clinical settings.
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https://www.effectivehealthcare.ahrq.gov/sites/default/files/pdf/methods-guidance-tests-prognostic_methods.pdf
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Overinterpretation and misreporting of prognostic factor studies in ...
Oct 24, 2018 · Our study provides evidence of frequent overinterpretation of findings of prognostic factor assessment in high-impact medical oncology journals.Missing: indicators | Show results with:indicators
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Understanding survival analysis: Kaplan-Meier estimate - PMC - NIH
Kaplan-Meier estimate is one of the best options to be used to measure the fraction of subjects living for a certain amount of time after treatment.
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[PDF] Lecture 5: Survival Analysis 5.1 Survival Function
The survival function S(t) of this population is defined as. S(t) = P(T1 > t)=1 − F(t). Namely, it is just one minus the corresponding CDF. Although this ...
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Full article: Edward L. Kaplan and the Kaplan-Meier Survival Curve
May 18, 2018 · Edward L Kaplan (1920–2006) and Paul Meier (1924–2011) published an innovative statistical method to estimate survival curves when including incomplete ...
[31]
Regression Models and Life‐Tables - Cox - 1972
This paper analyzes censored failure times, using explanatory variables and a hazard function to estimate regression coefficients.
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APACHE II: A severity of disease classification system
This paper presents the form and validation results of APACHE II, a severity of disease classification system. APACHE II uses a point score based upon ...
[33]
How To Build and Interpret a Nomogram for Cancer Prognosis
Mar 10, 2008 · This guide provides a nonstatistical audience with a methodological approach for building, interpreting, and using nomograms to estimate cancer prognosis.
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Methodological conduct of prognostic prediction models developed ...
Apr 8, 2022 · Machine learning methods include neural networks, support vector machines and random forests. Machine learning is often portrayed to offer ...
[35]
New horizons in prediction modelling using machine learning in ...
Sep 23, 2024 · This paper serves as an introductory guide for health researchers and readers interested in prediction modelling and explores how these technologies support ...
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Prediction of coronary heart disease using risk factor categories
A simple coronary disease prediction algorithm was developed using categorical variables, which allows physicians to predict multivariate CHD risk in patients ...Missing: original | Show results with:original
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Cancer Staging | Has Cancer Spread | Cancer Prognosis
Sep 10, 2024 · The AJCC TNM (and similar) staging systems are used most often to determine the stage of a person's cancer, which in turn might be used to help ...Cancer can be staged at... · What goes into the stage: The... · Other staging systems
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A model to predict survival in patients with end-stage liver disease
The MELD scale is a reliable measure of mortality risk in patients with end-stage liver disease and suitable for use as a disease severity index to determine ...Missing: original paper
[39]
PredictMD - Uniform interface for machine learning in Julia
PredictMD is a free and open-source Julia package that provides a uniform interface for machine learning. GitHub repository: bcbi/PredictMD.jl.
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Evaluation of clinical prediction models (part 1): from development to ...
Jan 8, 2024 · The process of k-fold cross validation entails splitting the data into “k” equal sized groups. A model is developed in k-1 groups, and its ...
[41]
Evaluation of clinical prediction models (part 2) - The BMJ
Jan 15, 2024 · Five key steps are involved: obtaining a suitable dataset, making outcome predictions, evaluating predictive performance, assessing clinical usefulness, and ...
[42]
Calibration: the Achilles heel of predictive analytics - BMC Medicine
Dec 16, 2019 · We summarize how to avoid poor calibration at algorithm development and how to assess calibration at algorithm validation, emphasizing balance ...
[43]
There is no such thing as a validated prediction model - BMC Medicine
Feb 24, 2023 · It follows that prediction models are never truly validated. This does not imply that validation is not important.
[44]
Systematic review of prognostic models for predicting recurrence ...
A lack of external validation is a common problem in the predictive modelling landscape and many more models are developed than are externally validated.
[45]
External validation of three prognostic models for overall survival in ...
Nov 19, 2013 · The purpose of this study was to validate and compare the performance of three prognostic models for overall survival in patients with advanced-stage ...Missing: challenges | Show results with:challenges
[46]
A new method of classifying prognostic comorbidity in longitudinal ...
The objective of this study was to develop a prospectively applicable method for classifying comorbid conditions which might alter the risk of mortality for ...
[47]
The relationship between socioeconomic status and health - PubMed
Individuals of lower socioeconomic status, however, generally have faced higher mortality rates than individuals of higher status.Missing: prognosis | Show results with:prognosis
[48]
the role of prognostic and predictive immune markers in cancer
The immune contexture, quantified by Immunoscore, is a parameter for prognosis. The host-immune reaction may determine response to therapy.Missing: affecting | Show results with:affecting
[49]
Factors Influencing Physician Prognosis: A Scoping Review - PubMed
Dec 22, 2022 · Factors influencing prognosis were clustered in 4 categories: patient-related factors (such as age, gender, race, diagnosis), physician-related ...
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In modern times, how important are breast cancer stage, grade and ...
Feb 1, 2021 · These results show that tumour size and nodal status, as well as IHC subtype and grade, are important independent predictors of breast cancer ...
[51]
The Impact of Tumor Grade on Survival End Points and Patterns of ...
This study aimed to determine the impact of tumor grade on patterns of recurrence and survival end points in patients with endometrioid carcinoma.
[52]
HER2-Positive Breast Cancer Guide | BCRF
Currently, survival rates exceed 90 percent in HER2-positive breast cancer that is diagnosed early and treated with chemotherapy and dual antibody therapy.
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HER2 status in breast cancer: changes in guidelines and ...
Nov 6, 2019 · HER2 amplification is a poor prognostic factor associated with a high rate of recurrence and mortality, and is a predictive factor for response ...
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Socioeconomic Status and Access to Healthcare - PubMed Central
Jun 18, 2020 · In a variety of contexts, lower SES is associated with reduced access to care, poorer health outcomes, and increased mortality and morbidity as ...
[55]
Health inequalities in cancer care: a literature review of pathways to ...
Sep 26, 2024 · This literature review discusses current health disparities in cancer care in the United Kingdom, spanning access to services, diagnosis, and outcomes.
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Impact of ambient air pollution on colorectal cancer risk and survival
Apr 16, 2024 · This study investigates the associations between air pollution and colorectal cancer (CRC) risk and survival from an epigenomic perspective.
[57]
HPV and Cancer - NCI
May 9, 2025 · HPV infection causes cells to undergo changes. If not treated these cells can, over time, become cancer cells. Once high-risk HPV infects ...
[58]
The impact of HPV/HIV co-infection on immunosuppression ... - NIH
Feb 5, 2025 · HIV-induced immunosuppression promotes the persistence of high-risk HPV infection and increased the progression to cervical cancer.
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Drug-Resistance Mechanism and New Targeted ... - PubMed Central
Feb 25, 2023 · Such patients usually have a poor prognosis, and the 2-year overall survival (OS) is only 20% ~ 40%. MYC and BCL-2 and/or BCL-6 rearrangements ...
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The long-lasting impacts of the COVID-19 pandemic on population ...
Dec 14, 2024 · COVID-19 infection interference could decrease cancer survival in two ways: a) an indirect effect, whereby the infection leads to treatment ...
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Delays and Disruptions in Cancer Health Care Due to COVID-19 ...
Feb 22, 2021 · The studies identified 38 different categories of delays and disruptions with impact on treatment, diagnosis, or general health service.
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The Effect of Prognostic Communication on Patient Outcomes in ...
Apr 23, 2020 · This systematic review aimed to offer up-to-date, evidence-based guidance on prognostic communication in palliative oncology.
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Patient-Clinician Communication: American Society of Clinical ...
Sep 11, 2017 · This guideline provides guidance to oncology clinicians on how to communicate effectively so as to optimize the patient-clinician relationship, ...
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Communicating prognostic uncertainty in potential end-of-life contexts
Jul 12, 2016 · Prognostic uncertainty was often poorly communicated, if at all. Inappropriate techniques included information being cloaked in confusing ...
[65]
Review article Communicating uncertainty in cancer prognosis
Individualized prognostic information can be complex and challenging to communicate [1,6]. In particular, the inherent uncertainties of prognostic information ...
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Effects of patient‐centered communication on anxiety, negative ...
Apr 5, 2017 · Patient-centered communication makes a difference in patients' experience, insofar that they report feeling less anxious and more trustful ...
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Effects of prognostic communication strategies on emotions, coping ...
Mar 27, 2024 · We aimed to investigate effects of prognostic communication strategies on emotions, coping, and appreciation of consultations in advanced cancer.Methods · Results · DiscussionMissing: verbal | Show results with:verbal
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Prognostic tools or clinical predictions: Which are better in palliative ...
Apr 28, 2021 · PaP scores classify patients into three risk groups based on a 30-day survival probabilities of less than 30%; between 30–70%; and more than 70% ...<|separator|>
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Development and Validation of the PaP Score Nomogram for ...
May 19, 2022 · According to the PaP score, median survival times were 64 days in group A (30-day survival probability, 82.0%), 32 days in group B (30-day ...
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Underlying goals of advance care planning (ACP): a qualitative ...
Mar 6, 2020 · Through ACP, patients will be informed about their illness and know about their prognosis, enabling health care professionals to prepare ...<|separator|>
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Implementing advance care planning in palliative and end of life care
Mar 28, 2024 · This review suggests that community nurses' experience and competence are associated with the effective implementation of ACP with palliative patients.
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Conceptualising effective symptom management in palliative care
Feb 4, 2022 · We present a novel qualitative data-derived model of effective symptom management in specialist palliative care.
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Withholding and Withdrawing Life-Sustaining Treatment - AAFP
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Ethical aspects of limiting end-of-Life treatment of adult patients at ...
Jul 1, 2025 · Decisions on treatment limitation include withholding and withdrawing life‑sustaining treatment ... poor quality of life prognosis. Withholding ...
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Therapeutic privilege - PMC - NIH
Therapeutic privilege refers to the act of withholding information by a clinician, with the underlying notion that the disclosure of this information would ...
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Minors' Right to Know and Therapeutic Privilege | Journal of Ethics
Exercising therapeutic privilege also risks undermining trust in the physician-patient relationship. One risk of nondisclosure is the patient's discovering the ...
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Palliative Care for Patients With Cancer: ASCO Guideline Update
May 15, 2024 · Routine palliative care referrals may be more advisable at diagnosis in poor prognosis cancers (eg, lung cancer without actionable driver ...
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Palliative care - World Health Organization (WHO)
Aug 5, 2020 · Palliative care is an approach that improves the quality of life of patients (adults and children) and their families who are facing problems ...
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Prognostic Awareness in Adult Oncology and Palliative Care
Feb 5, 2020 · Communicating prognosis clearly and empathically can foster accurate prognostic awareness in patients with advanced cancer and their family members.
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Rudolf Virchow - PMC - NIH
Rudolph Virchow (1821–1902). Virchow was one of the 19th century's foremost leaders in medicine and pathology. He was also a public health activist, social ...
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Virchow's Contribution to the Understanding of Thrombosis and ...
He was one of the first physicians to examine disease at the cellular level, arguing that the origin of disease was caused by cellular pathology. One area that ...Missing: prognosis | Show results with:prognosis
[82]
Prognosis: the “missing link” within the CanMEDS competency ...
May 13, 2014 · Osler's textbook described each disease under seven categories: etiology, presentation, pathology, diagnosis, therapy, prognosis, and ...
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From Dukes-MAC Staging System to Molecular Classification
Aug 21, 2022 · Dukes proposed in 1932 the first staging system of CRC, starting with the rectum and then for colorectal segments [5,6].
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Survival analysis in clinical trials: Basics and must know areas - PMC
Probably it originated centuries ago, but only after World War II a new era of survival analysis has emerged, being stimulated by an interest in the reliability ...Missing: post | Show results with:post
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UICC and the TNM Classification of Malignant Tumours
Aug 28, 2023 · The TNM (“Tumour”, “Nodes”, “Metastases”) cancer staging system was developed by Prof. Pierre Denoix at the Institute Gustave-Roussy in France ...Missing: 2017 revision
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Evidence-Based Medicine: History, Review, Criticisms, and Pitfalls
Feb 21, 2023 · Its formal origin dates back to the mid-nineteenth century, and since then, it has continued to evolve.Missing: transition | Show results with:transition
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Benefits and challenges of Big Data in healthcare - NIH
Nov 18, 2019 · Big Data have the potential to yield new insights into risk factors that lead to disease. There is the possibility to engage with the individual ...
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Deep learning improves physician accuracy in the comprehensive ...
Oct 24, 2024 · Physicians showed significant improvements in detecting abnormalities on chest X-rays when aided by the AI system compared to when unaided ( ...
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Clinical utility of artificial intelligence models in radiology
Oct 30, 2025 · A deep learning radiomic nomogram developed by Dong et al. outperformed standard clinical N stages, tumor size, and clinical models in ...
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Recommendations for the use of next-generation sequencing (NGS ...
May 27, 2024 · Recommendations for the use of next-generation sequencing (NGS) for patients with advanced cancer in 2024: a report from the ESMO Precision Medicine Working ...
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Real-World Data: Implementation and Outcomes of Next-Generation ...
A study in France evaluating NGS across multiple cancer types found that 8% of participants received targeted therapy post-genomic profiling (a 3% increase ...
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Systematic review of artificial intelligence biases across racial and ...
In this study, we found that 82 % of existing AI models demonstrated different accuracy across racial and ethnic groups in the cardiovascular domain. For ...
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WHO outlines considerations for regulation of artificial intelligence ...
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Privacy-preserving artificial intelligence in healthcare: Techniques ...
This study summarizes the state-of-the-art approaches for preserving privacy in AI-based healthcare applications.
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Socioeconomic Bias in Healthcare AI: How Zip Code Data Reveals ...
Jul 31, 2025 · Healthcare AI systems show 35% higher error rates for low-income patients. Learn how socioeconomic bias in algorithms perpetuates health ...
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Racial and Socioeconomic Disparity in Breast Cancer Mortality - NIH
May 13, 2025 · Unfortunately, there is a significant disparity in mortality rates between different ethnic and socioeconomic groups, which reflects a clear ...
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The Future of Personalized Healthcare: AI-Driven Wearables for Real
Jul 8, 2025 · AI-powered wearables offer benefits such as continuous monitoring, improved diagnostic accuracy, personalized healthcare, and remote patient ...Missing: prognosis | Show results with:prognosis<|separator|>
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The Future of Predictive Analytics and Wearables - Sequenex
Oct 15, 2024 · Modern wearables offer real-time data on vital signs such as blood glucose levels, heart rhythms, and oxygen saturation. These advancements ...Missing: prognostic | Show results with:prognostic