The prevalence of FIP exhibits an age-dependent pattern, with higher rates observed among the middle-aged and elderly populations, as reported in previous studies (19, 25, 26). Notably, the onset of the fifth decade appears to be a critical time point when an increase in pancreatic fat fraction is commonly observed (27). Furthermore, it has been demonstrated that middle-aged men are at a higher risk of developing FIP than their younger counterparts (8). FIP also increases in middle-aged and elderly women compared to young women, and the risk ratio was 6.60 (95% CI: 0.92–47.49) and 19.11 (95% CI: 2.57–142.28), respectively. Post-climacteric women have a higher risk of FIP than pre-climacteric women (28). The cause of age-related pancreatic fat build-up is unclear, but atherosclerosis and reduced blood flow may contribute (29). FIP is more prevalent in individuals of East/Southeast/South Asian heritage, less common in Black African individuals, and intermediate in European or Latin American individuals (30).

Adipose tissue is an endocrine organ that communicates with other organs in the body and contains adipocytes and other tissue cells. When body weight increases, adipose tissue storage capacity is exceeded, leading to a relocation of fat in non-adipose organs, such as the liver, skeletal muscle, and pancreas (21). In obesity, a hormonal microenvironment disorder causes an increase in macrophage infiltration into fat tissue. This leads to a chronic low-inflammatory state characterized by pro-inflammatory cytokine release and fat accumulation in distal organ tissues (23, 31). In animal studies, obese mice with leptin insufficiency had a higher pancreas weight. They exhibited greater intra-lobular and total pancreatic fat content and elevated levels of pro-inflammatory mediators such as tumor necrosis factor-alpha (TNF-α) and interleukin-1β (IL-1β).

Additionally, pancreatic tissue triglyceride composition was significantly higher in the progeny of obese dams than in the progeny of thin dams, indicating that exposure to an obesogenic environment shortly after birth can lead to FIP. The study revealed a previously unknown fatty pancreatic phenotype associated with obesity, which suggests that maternal obesity can program a pancreatic phenotype similar to non-alcoholic fatty liver disease (NAFLD) (32). Obesity and insulin resistance play essential roles in pancreatic adipocyte infiltration, which can lead to FIP (22). Although old studies have reported T2DM as the cause of FIP (5, 33), recent studies have found that FIP is associated with T2DM development (34, 35). FIP can often be cured by reducing weight (36).

Diet may play a pivotal role in initiating FIP in experimental animal models. In a rat model, prolonged exposure to a high-fat diet resulted in adipose tissue build-up within pancreatic acinar cells, triggering a cascade culminating in tissue fibrosis and injury (37). Similar observations were made in mice fed a high-fat diet, which displayed FIP characteristics and MS markers, including insulin resistance (38). The impact of high-fat diets on pancreatic physiology appears to involve intricate interactions between saturated and unsaturated fatty acids along with overall fat content. This suggests that dietary fats' specific composition and quantity influence pancreatic impairment (39). Oleic acid, an unsaturated fatty acid, emerged as a determinant influencing individual variations in pancreatic triglyceride accumulation, underscoring the significance of dietary fat composition (40).

In humans, a study involving 11 individuals with T2DM revealed that a low-calorie diet significantly reduced pancreatic fat content (FIP) by creating a negative energy balance, implying its relevance to T2DM-associated pancreatic fat (41). A trial comparing Mediterranean (rich in unsaturated fats) and low-fat diets among individuals with abdominal obesity or dyslipidemia, including T2DM cases, reported significantly lower FIP prevalence with the Mediterranean diet (42). These findings underscore the potential of diet to influence pancreatic fat content and metabolic health, particularly in individuals with T2DM.

A prospective study involved three distinct cohorts, totaling 120,877 US women and men, all of whom were initially free from chronic illnesses and not obese. The follow-up periods extended from 1986 to 2006, 1991 to 2003, and 1986 to 2006. In each successive 4-year interval, participants exhibited an average weight gain of 3.35 lbs, ranging from the 5th to the 95th percentile (−4.1 to 12.4 lbs). When examining augmented daily servings of individual dietary constituents, the alteration in weight over 4 years was most notably linked to the consumption of potato chips (1.69 lb), potatoes (1.28 lb), sugar-sweetened beverages (1.00 lb), unprocessed red meats (0.95 lb), and processed meats (0.93 lb). Considering obesity's established association with a significant risk for FIP, it is plausible that meat consumption may contribute to the development of FIP (43).

NAFLD is a condition with excessive fat build-up in hepatocytes and is prevalent in approximately 30% of the general population. FIP has been increasingly recognized as a condition that can occur with NAFLD. A study that included post-mortem material from 80 patients found that total pancreatic fat is a major determinant of the presence of NAFLD. Specifically, intra-lobular pancreatic adipose build-up was associated with non-alcoholic steatohepatitis (NASH), as reported in a prior investigation (22). Furthermore, a study that employed transabdominal ultrasonography (TUS) to assess the relationship between NASH and FIP found that over 50% of individuals with NASH exhibited concurrent FIP. FIP was observed at various stages in 51.2% of NASH patients and 14% of normal individuals (44). In another prospective study, it was observed that nearly 80% of NASH patients also developed FIP. Hepatic steatosis, in particular, was significantly associated with FIP (45).

Moreover, a retrospective study used proton density fat fraction (PDFF) and MRI to evaluate the extent of pancreatic fat in individuals with NAFLD confirmed by biopsy. The average MRI-PDFFs for the liver and pancreas were 18.7% and 5.7%, respectively. T2DM patients had a significantly higher association (12.2% vs. 4.8%) than non-T2DM patients (46).

A systematic review and meta-analysis found that FIP was associated with a more than 2.5-fold higher co-prevalence of NAFLD and a substantial positive correlation between pancreatic and liver fat content in an uncorrected analysis of healthy individuals (13).

Hemochromatosis is a genetic disorder that causes systemic iron overload due to reduced hepcidin or hepcidin-ferroprotein binding levels, leading to iron accumulation in parenchymal cells in the liver, pancreas, and heart (47). In the pancreas, this can cause function dysregulation, fibrosis, and tissue replacement with fat (48). Studies have shown a correlation between hemochromatosis and fat accumulation in the pancreas, which may contribute to the development of FIP (49–51).

FIP has been associated with hepatitis B, reovirus, and HIV. An autopsy report revealed that a 52-year-old Japanese woman with cirrhosis caused by chronic hepatitis B also had FIP, indicating a possible correlation between chronic hepatitis B or extensive hepatic lesions and FIP (52). An animal study found that after the third week of reovirus infection, there was a fatty replacement of some necrotic tissue in the pancreas, suggesting a potential relationship between reovirus and FIP (34). HIV has also been linked to FIP, which can directly harm the pancreas (34, 52).

Studies suggest that long-term alcohol intake can contribute to the development of FIP. An animal study found that alcohol consumption in the long term promotes pancreatic cholesteryl ester build-up and induces FIP (53). Furthermore, a human histopathological examination has observed fat storage in pancreatic acinar cells in patients who consume more than 30 g/day of ethanol (54). Another study reported that alcohol consumption of more than 14 g/week can lead to FIP (34, 48).

Abnormal lipid metabolism induced by Cushing syndrome or steroid therapy has been identified as a contributing factor to the development of FIP. A case report study demonstrated a significant association between the administration of cortisone or its analogs and the occurrence of FIP in affected patients (48). FIP is frequently observed in individuals with HIV-1 undergoing antiretroviral therapy (55).

During the HAART era, FIP has become a prevalent clinical consequence. Reports have indicated that changes in body composition occur with the introduction of HIV protease inhibitors (HAARTs). These changes involve a seemingly increased redistribution of fat, including a relative increase in abdominal fat with peripheral lipoatrophy. These changes caused peripheral lipoatrophy and increased circulating lipids, leading to excess fatty acids deposited in pancreatic cells (56).

According to an animal study, Rosiglitazone leads to FIP by increasing pancreatic bulk, fat entrapment, acinar degeneration, and the invasion of inflammatory cells (57). A clinical case report study of an individual with pancreatic head malignancy found total fat substitution of the pancreas following a chemoradiotherapy regimen that included Gemcitabine and radiotherapy after excluding the fatty replacement in the pancreatic bed before the therapy; hence, Gemcitabine may cause FIP (58).

PDO has been investigated concerning FIP. Post-mortem and case report studies have reported an association between PDO due to intraductal calculus or pancreatic cancer and the development of FIP (33, 59, 60). However, an animal study showed that simple closure of the pancreatic duct only resulted in fibrosis and not FIP due to insufficient inflammatory cell infiltration. These findings were reversed with pancreatic juice drainage, indicating that more arterial occlusion was necessary to induce FIP (61). Therefore, chronic ischemia caused pancreatic damage, limited cell necrosis, and the formation of a reaction zone, which led to chronic pancreatitis and, ultimately, FIP.

Several genetic abnormalities have been identified as causing FIP, among other conditions. FIP is a late-stage pancreatic disease observed in individuals with cystic fibrosis, and it is primarily caused by a deficiency or malfunction of the cystic fibrosis transmembrane conductance regulator (CFTR) protein in the pancreatic duct epithelium (PDE) (62). The CFTR protein functions as a chloride and bicarbonate channel on the apical surface of epithelial cells, including those in the pancreas. CFTR malfunction leads to reduced bicarbonate secretion from the PDE, causing an acidic small intestine environment, thickened mucus production, and PDO, ultimately resulting in FIP (63).

In Western countries, Schwachman-Diamond syndrome (SDS) ranks second in prevalence among exocrine pancreatic genetic disorders, following cystic fibrosis. The disorder is commonly associated with exocrine pancreatic dysfunction, which can lead to the development of FIP (64, 65).

Johanson-Blizzard syndrome is an uncommon genetic disorder associated with exocrine pancreatic insufficiency (EPI) (66). This disorder is distinguished by congenital EPI, which stems from histological variances in the pancreatic buds during embryonic development and can lead to uneven fatty infiltration (67, 68). Radiological examination of the pancreas in non-diabetic children with carboxyl-ester lipase (CEL) gene mutations revealed structural changes indicating fat build-up. It confirmed previous research on EPI in CEL-mediated disease in all mutant carriers over 5 years old (69).

A recent study on twins found that the impact of hereditary factors on FIP detected by CT was limited. Upon controlling for various factors, the statistical significance of the association with FIP was exclusively detected in monozygotic twins but not in dizygotic twins (70).

The severe malnutrition condition of kwashiorkor may play a role in the development of FIP, according to a case report study of an 11-year-old boy who presented with clinical and pathological features of kwashiorkor for over 2 years and was diagnosed with FIP (34). Therefore, kwashiorkor may contribute to the development of FIP.

It has been established that FIP directly impacts the pancreatic parenchyma and is linked with parenchymal damage in acute pancreatitis, specifically in the adipose tissue enveloping the acinar cells of the pancreas (99, 100). A human study revealed that deceased adipocytes were surrounded by an area of necrotic parenchyma, with the most severe damage observed near the dead adipose tissue. This peri-fat acinar necrosis, characterized by the presence of macrophages (CD68-positive), is an antemortem event and was found to be more common in patients with acute pancreatitis, especially those with severe forms of the disease, compared to controls. It was also the most frequently observed type of necrosis in post-mortem samples. Another type of necrosis observed was isolated acinar necrosis, which occurs in pancreatic parenchyma away from the adipose tissue. However, this type of necrosis was significantly less common than peri-fat acinar necrosis in severe acute pancreatitis. The presence of FIP contributes to increased morbidity and mortality in patients with severe acute pancreatitis (101).

MS is a growing clinical and societal concern worldwide due to changing lifestyles characterized by high-calorie, high-fat diets and low physical activity levels. A recent study revealed that the group with FIP had a significantly higher prevalence of MS than the control group, along with a greater number of MS markers (P < 0.05). Furthermore, FIP showed a strong association with MS, as evidenced by four studies involving 611 individuals with FIP, of whom 265 had MS, compared to 2,051 non-FIP individuals, of whom 361 had MS. The presence of FIP was significantly correlated with a higher incidence of MS, with a relative risk of 2.37 (95% CI: 2.07–2.71; P < 0.001), indicating a 137% increased likelihood of developing metabolic syndrome in individuals with FIP (20).

In addition, a prospective study demonstrated that patients with FIP were over three times more likely to receive an MS diagnosis than those without FIP (OR 3.13, P = 0.004). This study also explored the relationship between FIP and increasing MS risk factors and whether a higher BMI could largely explain the correlation between FIP and MS. The findings revealed that each additional MS risk factor, such as BMI >30 kg/m², T2DM, HTN, or hyperlipidemia, increased the risk of FIP by 37% (5).

FIP has been implicated in the development of cardiovascular diseases (CVD), including atherosclerosis. FIP has been found to occur not only in individuals with general obesity but also in those without established pancreatic disease. It has been strongly associated with diabetes and severe widespread atherosclerosis (102, 103). FIP has been linked to a higher prevalence of carotid artery plaques and increased vascular rigidity in individuals who are not overweight. Nonetheless, no significant associations were found in obese individuals (104).

Studies have also shown that FIP is linked with augmented epicardial adipose tissue and aortic intima-media thickness, which are markers of clinical atherosclerosis. FIP was strongly associated with a 3-fold increased risk of developing aortic intima-media thickness and a 16-fold increased risk of developing epicardial adipose tissue (105). Furthermore, FIP has been correlated with the severity of coronary artery stenosis in individuals with T2DM, suggesting that it may be a predictor of coronary artery stenosis in this population. A higher incidence of complex coronary artery lesions was found in patients with acute coronary syndrome (ACS) and FIP. A significant and independent positive correlation was observed between FIP and the Syntax (SX) score, a well-established angiographic scoring system considering lesion characteristics and coronary anatomy (106).

The pathophysiological mechanisms underlying the association between FIP and coronary atherosclerosis involve the secretion of pro-inflammatory factors by adipose tissue in the pancreas, consequently resulting in endothelial dysfunction and metabolic abnormalities. The severity of fat accumulation in the pancreas has also been correlated with the severity of coronary arteriosclerosis. These findings suggest that FIP may be a potential contributor to CVD, particularly in individuals who are not overweight (107).

HTN is a significant global health issue associated with the risk of heart, brain, kidney, and other organ disorders, and it is the leading cause of death worldwide.

A study involving 55 non-diabetic human pancreas donors revealed that donors with a history of HTN had higher pancreatic fat and islet fat content, regardless of gender. These findings suggest that a previous history of HTN may independently contribute to increased pancreatic fat content and islet fat content (108). HTN is known to cause small vessel constriction and a reduction in microvascular density, leading to decreased tissue perfusion (109). Hypoxia and hypoxia-inducible factors have been linked to alterations in lipid metabolism and intracellular lipid accumulation in cultured cells and organs such as the liver and pancreatic islets (110, 111). Consequently, HTN may contribute to persistent tissue hypoxia, leading to lipid accumulation and pancreatic islet dysfunction.

On the other hand, a meta-analysis study reported a 67% increased risk of HTN associated with FIP (13). However, a prospective study showed a non-statistically significant trend toward an association between HTN and FIP (5). In a cross-sectional retrospective study involving 65 children with NAFLD, FIP was 1.28 times more likely to cause HTN (OR 1.28, 95% CI: 1.01–1.62) when examining potential risk factors for HTN in children with NAFLD (112).

T2DM is projected to become the sixth leading cause of mortality by 2030, with obesity and physical inactivity being significant contributors to its development, and it is crucial to understand their impact on the pancreas and associated morbidity.

The build-up of ectopic fat in non-adipose tissues, such as the pancreas, due to metabolic overload of adipose tissue may result in lipotoxicity, insulin resistance, and inflammation, leading to glucose metabolic disturbances and T2DM. The build-up of fat in pancreatic endocrine cells plays a crucial role in the pathogenesis of T2DM (113). FIP has been implicated in the pathogenesis of T2DM, even independent of NAFLD, with evidence suggesting that it may be associated with beta-cell failure independent of insulin resistance (114, 115). However, other studies have reported that NAFLD patients with FIP have increased insulin resistance, impaired glucose parameters, and higher rates of prediabetes and diabetes than those with NAFLD alone (116). In an animal study, pancreatic fat build-up was observed before the onset of hyperglycemia in obese Zucker diabetic fatty mice (117). A cross-sectional study also reported a significantly higher prevalence of T2DM in FIP patients compared to non-FIP patients (12% vs. 5%) (7).

In some studies, pancreatic fat content, measured by various methods such as MRS, MRI, and CT, is higher in individuals with T2DM than in non-diabetic subjects. However, some studies using CT or post-mortem examinations have reported no difference in pancreatic fat content, and the discrepancies in findings are due to differences in measurement accuracy (116).

A meta-analysis study revealed that individuals with FIP had a 108% higher risk of developing T2DM. Another meta-analysis of six studies showed that individuals with FIP had a significantly increased relative risk of developing T2DM (RR 2.08; 95% CI: 1.44–3.00; P = 0.001). Some studies have also reported a significant association between FIP, insulin resistance, and beta-cell dysfunction (20).

Recently, a 10-year prospective cohort study involving 631 participants found that those with FIP had a significantly higher incidence of T2DM than those without FIP (33.3% vs. 10.4%; P < 0.001). FIP was independently associated with an increased hazard ratio of 1.81 for incident T2DM. Furthermore, the risk of developing incident T2DM was significantly increased by 7% for every 1% increase in pancreatic fat, with a hazard ratio of 1.07 (35).

However, recent studies have shown that T2DM may be reversible with bariatric surgery and dietary energy intake restriction, which can improve beta-cell activity and reduce pancreatic fat content.

The role of FIP, particularly the first-phase insulin response, may be crucial in glucose metabolism and beta-cell failure, and different susceptibility thresholds to pancreatic fat build-up may be determinants of beta-cell dysfunction (118).

Pancreaticoduodenectomy (PDE) is currently the preferred treatment for pancreatic cancer. However, one of the most significant complications of PDE is PF. Early detection and management of potential risk factors for PF are crucial. FIP has been identified as a significant risk factor for PF (119). Studies have shown that patients with PF have significantly greater intra-lobular, inter-lobular, and total pancreatic fat than non-PF patients.

Moreover, the risk of PF becomes considerable when the percentage of fatty infiltration exceeds 10% (26, 119). In a retrospective study, 40 patients with PF and 40 without PF were selected and matched for age, sex, pancreatic pathology, surgeon, and type of surgery. Compared to non-PF patients, those with PF demonstrated a considerable increase in intra-lobular, inter-lobular, and total pancreatic fat content (P < 0.001). An inverse correlation was observed between PF and fibrosis, blood vessel density (P < 0.001), and a small PD. A soft pancreatic texture is also deemed a risk factor for PF formation, potentially owing to augmented fat build-up, which can impede anastomosis and heighten the likelihood of perioperative pancreatitis (120, 121).

A meta-analysis of 11 studies involving 2484 individuals found that FIP was significantly associated with the occurrence of the PF (OR = 3.75; 95% CI: 1.64, 8.58; P = 0.002; I² = 78). Overall, the evidence suggests that FIP is a critical risk factor for PF and should be carefully managed during PDE to reduce the incidence of PF (119). The exact mechanism by which FIP promotes PF development is unknown. Nonetheless, researchers propose that a soft pancreas is more susceptible to ischemia and damage during restoration, and the exocrine function can worsen tissue damage (122).

Pancreatic transplantation has become increasingly successful, and as a result, the number of individuals awaiting pancreatic transplantation has risen. FIP is an essential criterion in determining the viability of donor pancreata for transplantation. Although many pancreas from overweight donors can be transplanted successfully, certain transplant surgeons avoid using the pancreas with significant FIP since the surgery is technically more challenging. However, a more objective measurement could help avoid discarding suitable organs for transplant. In the case of pancreatic transplantation, the presence of pancreatic lobules with associated ducts and blood arteries loosely separated from the primary pancreas recommends that all cut-away fatty pancreatic tissue be ligated to prevent pancreatic leaks and bleeding after transplantation. Careful hemostasis after fat removal minimizes the chance of hematoma leading to infection, especially when anticoagulation is indicated, even minor anticoagulation. To prevent fat necrosis, octreotide should be administered prior to revascularization and continued until the pancreatitis is resolved, rather than late after surgery. Flushing and cooling should be used to maximize graft preservation and avoid autolysis (78).

PDAC is a highly lethal cancer worldwide (123, 124). The late presentation and lack of early-stage biomarkers make early identification of PDAC challenging. Additionally, the retroperitoneal location of the pancreas facilitates the spread of PDAC to nearby organs and blood vessels, and non-specific features further complicate early detection (125).

PDAC typically arises from precursor lesions such as acinar-ductal metaplasia (ADM), pancreatic intraepithelial neoplasia (PanIN), intraductal papillary mucinous neoplasia (IPMN), mucinous cystic neoplasia, and atypical flat lesions (126, 127). The most common genetic alteration in PDAC is the KRAS mutation, which is detected in more than 90% of cases and is an early event in low-grade PanIN 1A lesions (126). Obesity is a significant risk factor for PDAC (128, 129), and increased pancreatic adiposity contributes to PDAC development from FIP (130). Animal studies have shown that obesity and hyperlipidemia enhance FIP, leading to the progression of N-nitrosobis(2-oxopropyl)amine (BOP)-induced PDAC and the upregulation of adipocytokines and cell proliferation-related genes in the pancreas (131). Thus, local adipocytokine production from adipose tissues in an adipose tissue-rich milieu is linked to the development of PDAC.

PanIN, which affects small pancreatic ducts, may contribute to localized pancreatitis and promote the development of neoplasms. FIP is linked to the development of PanIN, and it is the most significant risk factor for precancerous pancreatic lesions, according to a retrospective study with an odds ratio of 17.86 [4.94–88.12], independent of age and diabetes status (132).

A case–control study of patients who had surgical intervention for PDAC found that increased pancreatic fat enhanced PDAC propagation and mortality. Fat-induced aberrant local cytokine production and toxic fatty acids have been shown to play a role in tumor proliferation, invasion, and angiogenesis (133). Additionally, persistent overproduction of reactive oxygen species can cause and accelerate mutagenesis alterations that contribute to the development and progression of PDAC (134). These mechanisms and the generation of growth factors by adipocytes are likely to hasten the spread of cancer cells to the lymphatics and local lymph nodes. FIP affects the tumor microenvironment, accelerates tumor progression, and leads to the early death of individuals with PDAC (135).

Polycystic ovary syndrome (PCOS) is the most prevalent endocrine disorder impacting women during their reproductive years (136). Osman et al. found that FIP was identified in 38.0% of patients with PCOS, significantly higher than the 12.0% of FIP cases detected in healthy controls (1). On the other hand, a recent study on adolescents did not find a relationship between FIP and PCOS (137). Notably, Osman et al. found that age was independently associated with the development of FIP in PCOS patients, suggesting that the metabolic interactions between PCOS and FIP may take longer to become evident in younger patients. The complex connection between FIP and PCOS reveals the intersection of metabolic and endocrine issues. Ongoing research could transform our grasp of these conditions and lead to innovative treatments.