Submitted Successfully!
To reward your contribution, here is a gift for you: A free trial for our video production service.
Thank you for your contribution! You can also upload a video entry or images related to this topic.
Version Summary Created by Modification Content Size Created at Operation
1
Paolo Cotogni
 + 4395 word(s) 4395 2021-04-06 10:40:11 |
2 format correct
Conner Chen
 Meta information modification 4395 2021-04-07 07:32:50 |

Video Upload Options

We provide professional Video Production Services to translate complex research into visually appealing presentations. Would you like to try it?
No, upload directly Yes

Confirm

Are you sure to Delete?
Yes No
Cite
If you have any further questions, please contact Encyclopedia Editorial Office.
Cotogni, P. Nutritional Support and Cancer. Encyclopedia. Available online: https://encyclopedia.pub/entry/8488 (accessed on 18 November 2024).
Cotogni P. Nutritional Support and Cancer. Encyclopedia. Available at: https://encyclopedia.pub/entry/8488. Accessed November 18, 2024.
Cotogni, Paolo. "Nutritional Support and Cancer" Encyclopedia, https://encyclopedia.pub/entry/8488 (accessed November 18, 2024).
Cotogni, P. (2021, April 06). Nutritional Support and Cancer. In Encyclopedia. https://encyclopedia.pub/entry/8488
Cotogni, Paolo. "Nutritional Support and Cancer." Encyclopedia. Web. 06 April, 2021.
Nutritional Support and Cancer
Edit
This entry is adapted from the peer-reviewed paper 10.3390/nu13020306

The role of nutritional support for cancer patients in palliative care is still a controversial topic. In the past, there has been limited collaboration between oncologists, clinical nutrition specialists, and palliative care physicians involved in the care of advanced cancer patients. Collaboration has been made more complex by the fact that, while it is clear what nutritional support is, there is no common or shared definition, not so much of palliative care, but of what constitutes a person who needs palliative care. In fact, there is no consensus in the literature on the definition of the palliative care patient because of the ambiguity in the common use in medicine of the adjective palliative. For many years, efforts have been made to find a screening tool to identify patients in need of palliative care in the hospital setting, as this would be very useful in both Internal Medicine and, in particular, Medical Oncology.

oncology nutritional status nutritional support

1. Cancer Patients in Palliative Care

According to Global Cancer Observatory (GLOBOCAN) estimates, about 18.1 million new cancer patients and 9.6 million cancer-related deaths occurred in 2018 worldwide. Many patients are now cured or are living longer with metastatic disease due to advances in diagnostics and treatments [1].

In recent years, patients with advanced cancer were defined as those with distant metastases, late-stage disease, and/or with prognosis of 6 to 24 months. Now, thanks to treatment advances, these patients live for multiple years, and many cancers are transforming into chronic diseases.

Palliative care patient have a neoplasm not responsive to curative treatment (World Health Organization-WHO, 1990) or a life-threatening disease (WHO, 2012). However, palliative care is not synonymous with EoL care or terminal care. By origin, the term “palliative” is derived from the Latin word “pallium” meaning “mask” or “cloak”. This etymology indicates what palliative care essentially is: cover or masking the symptoms and the effects of incurable disease for alleviating or reducing suffering [2][3][4].

Cancer is a systemic, complex, and heterogeneous disease. The cancer diagnosis, the disease itself, and the sequelae of cancer treatments are important stress factors for patients and their family. Cancer-related physical symptoms, together with psychological distress, social, and spiritual needs arising in the course of the disease, severely affect the patient’s and family’s life. Patients with advanced, incurable cancer often experience a symptom burden (including pain, dyspnea, fatigue, weight loss, and depression), emotional, social, existential, and spiritual suffering over the course of disease. Cancer symptoms depend on the stage, type of cancer, age, general condition of the patient, and many other factors. These symptoms impair the patient’s daily routine and quality of life (QoL) [5].

Moreover, in relation to the type of cancer, patients receive different types of treatments (chemotherapy, immunotherapy, radiotherapy, surgery, and other anticancer treatments) which lead to side effects, toxicities, and in some cases, permanent impairment resulting in disability. Symptom control is an essential part of cancer treatment, and more studies show positive effects of integrating palliative care early in oncology care to better address patients’ needs.

Palliative care is focused on symptoms and disease stress control for all cancer patients. The goal is to improve QoL for both the patient and the family, especially when disease-modifying interventions are not available. The WHO has proposed the following definition of palliative care: “Palliative care is an approach that improves the QoL of patients and their families facing the problems associated with life-threatening illness, through the prevention and relief of suffering by means of early identification and impeccable assessment and treatment of pain and other problems, physical, psychosocial and spiritual” [3][4].

A few systematic reviews concluded that early palliative care in patients with advanced cancer significantly improved patients’ QoL and could decrease symptom intensity. For this reason, oncology societies are committed to integrating palliative care into oncology.

The American Society of Clinical Oncology (ASCO) suggested the palliative care integrated early into oncology care is helpful for patients and families and complements the anticancer treatments [6][7][8][9]. The European Society of Medical Oncology (ESMO) proposed the term “patient-centered care” to defined care that aims to optimize the comfort, function, and social support of the patients and their families at all stages of the illness. To offer optimal patient-centered care for patients with advance cancer, the integration of supportive care and palliative care in oncology is necessary [10][11]. The Italian Association of Medical Oncology (AIOM), according to ESMO and ASCO programs, recommends an early integration of palliative care in cancer treatments. Additionally, due to the prevalence of severe and multiple symptoms, patients with advanced cancer can be referred to interdisciplinary palliative care teams [12][13].

2. Impact of Disease and Treatments on Nutritional Status in the Cancer Patient

Cachexia and anorexia have been invoked as “cancer’s covert killer” [14], and clinical data suggest that about 20–30% of deaths are attributable to malnutrition rather than cancer [15]. Malnutrition including muscle wasting, on the other hand, are recognized as common consequences of anticancer treatments. Whether these processes are reversible is a matter of debate, with the pathophysiological mechanisms involved being increasingly studied.

Cachexia is a multifactorial syndrome resulting from host factors, cancer type and stage, and treatment modalities. In pre-clinical stages, hormonal dysregulation and metabolic abnormalities occur as a result of the cancer microenvironment and chronic inflammatory state: insulin resistance, increased proteolytic activity, and lipolysis [16][17]. In later stages, a negative protein and energy balance derived from metabolic derangements results in progressive functional impairment with clinical manifestations characterized by hypophagia, early satiety, fatigue, and wasting.

Involuntary weight loss has been considered the hallmark of cachexia for at least 40 years and has been well recognized as an independent prognostic factor in cancer patients over the past 15 years [16][18]. In spite of the increasing prevalence of overweight and obesity in advanced cancer, ranging from 40% to 60% [19][20], it has been observed that almost 50% of patients are at nutritional risk and 13% are malnourished and have worse outcomes [21]. A grading system based on body mass index (BMI) and weight loss was proposed accordingly, comparing the impact on mortality of lower versus higher initial BMI: the highest risk category is patients with low initial BMI and high weight loss. These results show that a single cut-off of weight change for defining cachexia is misleading, since subgroups of patients with different degrees of risk can be defined [19].

It follows that changes in body weight are an imprecise means of appraising nutritional deterioration, whereas altered body composition is now acknowledged as the key feature to reveal the progression from malnutrition to cachexia. Important findings have been reported using magnetic resonance imaging and computed tomography to assess body composition in cancer patients. It has been noted that loss of muscle mass (sarcopenia) is particularly related to poorer tolerance to chemotherapy, increased risk of postoperative complications, deterioration of QoL, and survival [22][23][24][25]. Recent clinical literature suggests that intramuscular adipose tissue infiltration is another important and negative prognostic factor, as indicated by low muscle attenuation (radiodensity) on computed tomography [22][26][27]. Muscle steatosis, characterized by intramyocellular lipids, has been associated with poor muscle quality [28]. Moreover, visceral adiposity correlates with decreased treatment response and survival in many cancers and is associated with weight loss and muscle mass loss, as recently reviewed [29].

It has been noted that sarcopenia does not only result from cancer per se but can also be induced by chemotherapy. Iatrogenic sarcopenia is characterized by poor muscle quality which in turn results in a change in the volume of distribution of drugs, altered pharmacokinetics, and consequently increased toxicity. Sarcopenia has also been shown to correlate both with decreased response to chemotherapy and worse outcomes, in a troubling vicious circle [26][27].

The negative impact of sarcopenia on outcome also occurs in surgical patients, which is a risk factor for perioperative and postoperative complications [30][31][32]. Therefore, for frail patients with unresectable cancer, less invasive procedures are suitable in the elective setting, while palliative surgery is sometimes necessary for acute presentations, such as gastrointestinal obstruction, perforation, and bleeding. In recent years, conditions considered incurable such as peritoneal carcinomatosis have been more often subjected to cytoreductive surgery combined with hyperthermic intraoperative chemotherapy. Best practice for management comprises both pre-operative preconditioning with immunonutrition and postoperative early nutritional support [33].

Due to treatment-related side effects, surgery and chemotherapy cannot be undertaken as often as theoretically required for metastatic cancer patients, so radiation therapy (RT) is a commonly used alternative on their clinical journey [34]. Moreover, RT is often used in the palliative setting to obtain local cancer control and to mitigate symptoms. However, acute reactions to RT include mucositis, dysphagia, pain, vomiting, and diarrhea that may reduce adherence to treatment, necessitating aggressive nutritional intervention to enable patients to complete the course of treatment. Selection of eligible patients for palliative RT is challenging, as they may not benefit from treatment if their lifespan is too short to experience benefits from RT, or they may discontinue therapy early [35].

Head and neck cancers were associated with early discontinuation of palliative RT in a recent review; other predictive factors were low Karnofsky performance status (KPS) and long treatments courses [36]. Furthermore, for many patients with head and neck cancers, oral nutrition alone has been found to be inadequate to meet caloric requirements during courses of RT and/or chemoradiotherapy due to oral mucositis, making tube feeding necessary [37]. Gastrointestinal mucositis is a common consequence of fractionated abdominal irradiation, but it is probably under-reported due to being a clinical diagnosis. While its effects on food intake and absorption are well recognized, treatment and prevention strategies are limited, and clinical data on relative nutritional assessment are scant [38].

Whatever the etiopathogenesis, the functional decline in cancer patients is characterized by exacerbations of the disease in the last year of their life [39]. This clinical pattern was translated in a model of “catabolic crisis” with different clinical events related to disease progression or treatment, with a negative impact on nutritional status, with intercurrent phases of recovery in between crises. According to this model, no return to the previous functional baseline is observed during each recovery phase [40].

Recent clinical data seem to corroborate that “anabolic potential” can occur under certain conditions at defined phases of disease for advanced cancer patients [41]. Muscle gain has been related to stable disease, and it may represent response to successful cancer therapy. This highlights the importance of recognizing therapeutic windows for intervention before a refractory cachexia is established [42].

3. Dietary Counseling and Oral Nutrition Supplementation

In advanced cancer patients, preserving nutritional status may be a relevant concern during the palliative care phase. Even when the disease can no longer be cured, patients may survive for a reasonable amount of time (several months or years). In this context, nutritional status deficits may impair performance status, QoL, tolerance to palliative anticancer treatments, and survival. Therefore, patients with decreased oral intake require nutritional treatment in order to maintain nutritional status and meet the energy and protein needs [43].

Indeed, in the last phases of life, characterized by refractory cachexia with weight loss and deterioration of physical condition, nutritional care should be focused on recommending foods that the patient can tolerate and prefers to eat (“comfort feeding”), with the aim of ensuring a better QoL and alleviating symptoms [44].

The first goal of nutritional treatment is to preserve oral nutrition by minimizing food-related discomfort and maximizing food enjoyment through strategies including dietary counseling by a dietitian or other healthcare professionals, food fortification, and oral nutritional supplements (ONS) [45][46].

According to ESPEN guidelines, counseling is the first approach within a nutritional treatment, aimed at managing symptoms (appetite loss, nausea, early satiety, taste and smell changes, constipation, dysphagia, and psychosocial factors) and encouraging the intake of foods and drinks that are better tolerated, thus considering food intolerances and allergies, diet history, current meal pattern, and any changes in taste or smell that can affect preferences [43][47].

Dietary recommendations should be provided in order to optimize energetic and protein intake through modifications in food quality, size of portions, timing and splitting of meals throughout the day, and consistency adaptation. [44]

In this context, measures should be commensurate with the nutritional needs and predominant symptoms of each patient as part of a personalized and tailored nutritional treatment, such as that summarized in Table 1.

Table 1. Dietary recommendations according to nutritional impact symptoms.

Symptoms Dietary Recommendations
Appetite loss,
anorexia
  • Minimize eating effort by preferring high energy and protein foods through small and frequent snacks throughout the day.
  • High caloric liquid meals may be useful.
Taste and smell changes
  • Adjust diet in accordance with new taste preferences and by avoiding foods that may evoke aversion, such as those with an intense odor (roast meat, fish).
  • Prefer mildly flavored foods. Cold foods are generally less odorous.
  • If the oral mucosa is not sensitive, use salt, herbs, spices, and seasonings.
Nausea and
vomiting
  • Prefer small and frequent snacks throughout the day (crackers, biscuits) in order to avoid stomach emptying.
  • Take advantage of times when the patient feels less fatigued, or between cycles of chemotherapy.
  • Less odorous and cold foods may be better tolerated.
Oral mucositis, pain
  • Prefer soft, creamy, or liquid foods, and avoid hard ones that could damage the oral membrane (nuts, hard fruit, crusts, hard baked goods).
  • Prefer foods at room temperature, and avoid hot dishes and beverages. Ice cold foods and fluids may be pleasant.
  • Avoid extreme tastes, such as spicy and acidic foods, citrus fruits, and very salty products.
Oropharyngeal
dysphagia
  • Chopping or grinding and moisturizing food (adding cream, gravy, or sauce) allows an adequate thickness to be achieved to facilitate swallowing.
  • Add a thickener to viscous foods in order to prevent choking.
  • Avoid mixed consistency foods due to their high choking risk.
Esophageal
dysphagia
  • Transit of bolus throughout the esophagus can be favored by chopping finely and dipping foods in liquids (drinks, gravy, or sauces).
  • Chewing well and eating slowly and mindfully are recommended precautions, such as small and frequent meal consumption.
Constipation
  • An adequate liquid and fiber intake is aimed at preventing dehydration.
  • Although 30–40 g of fibers per day is the goal for healthy subjects, this result is difficult to achieve in practice.
  • Variate different types of fibers.

Moreover, patients should be made aware that healthy eating guidelines are no longer appropriate in their clinical conditions, and dietary restrictions should be avoided, as they limit food intake and enjoyment.

ONS find their use when nutritional requirements cannot be met by dietary counseling and food fortification. High-energy (>1.22 kcal/mL) and high-protein (>20% protein-derived energy) ONS allow the optimization of the caloric and protein supplies within a reduced volume, and special formulas could be advantageous in selected patients, such as semi-elemental products in malabsorption conditions [48]. According to a meta-analysis by Lee et al., the association of ONS administration and dietary advice seems to be more effective than ONS alone in relation to nutritional and functional outcomes (weight and fat-free mass gain/maintenance, QoL function score improvements) [49]. In the context of ONS, n-3 fatty acid-enriched formulas could provide some results in terms of weight gain and improvement in lean body mass, nutritional intake, and QoL [45][50]. However, such evidence appears to be limited by study heterogeneity in terms of cachexia stage, cancer site and stage, concomitant anticancer treatments, and endpoint measures [45].

4. Enteral Nutrition

Artificial nutrition (AN) can be integrated within a palliative care program when a positive influence on QoL is expected, and the risk of dying from malnutrition is higher than due to cancer progression [43][51]. ESPEN guidelines suggest that enteral nutrition (EN) should be first considered whenever the gastrointestinal tract is functional and oral nutrition remains inadequate despite nutritional interventions (counseling and ONS) [43].

EN is most frequently used in palliative care patients with head and neck or upper gastrointestinal cancers. In these patients, the primary indication for starting EN is oropharyngeal/esophageal dysphagia or gastric obstruction/dismotility, due to mechanical and functional factors related to the disease but also to palliative chemo- and/or radiotherapy induced side effects [52].

In a patient with a life expectancy of several weeks or months who is unable to fulfil more than 60% of their daily energetic needs in the long term through oral intake, it is a useful strategy to gain early gastrointestinal access. Among gastric devices, percutaneous endoscopic gastrostomy (PEG) is the gold standard, while radiologically inserted gastrostomy (RIG) or eventually surgical gastrostomy should be performed when an endoscopically guided tube cannot be placed. Long-term jejunal access (endoscopic or surgical jejunostomy) may be an option in the case of gastric obstruction/dismotility. Placement of a nasogastric tube (NGT) or nasojejunal tube (NJT) can be considered when short-term EN is expected (usually up to 6 weeks) and/or survival is uncertain [53].

In head and neck cancer patients who are unable to swallow, the use of an enteral route via NGT or gastrostomy may be a suitable strategy in order to achieve nutritional support in the setting of home care [52]. According to a recent study, evaluating the impact of home artificial nutrition (HAN) on performance status and survival in palliative cancer patients, EN, with dysphagia as the main indication, can maintain/improve the KPS and prolong mean survival up to 22.1 weeks (considering that death from starvation usually occurs within 2 months in healthy subjects, or even before in advanced cancer patients, without nutritional support) [54][55].

In esophageal cancer patients, PEG tends to grant a better nutritional status than self-expandable metal stent, and it is an independent factor associated with overall survival [56]. In these patients, endoscopically assisted NGT is also a feasible, low complication rate, palliative option for nutritional support, since it allows us to increase energy intake, serum albumin, median survival, and reduce hospitalization compared with nil per os [57]. However, Yu et al. indicate a slightly worse QoL in esophageal cancer patients using NGT feeding compared with the percutaneous route during chemoradiation therapy [58]. On comprehensive evaluation, it is reasonable to consider PEG as the preferred choice for long-term nutrition support in palliative esophageal cancer patients.

When EN is contraindicated or unfeasible, due to stenosis, sub-obstruction/obstruction, dysmotility, peritoneal carcinomatosis, malabsorption, abdominal pain, or intolerance and severe discomfort, parenteral nutrition (PN) should be considered [43].

Thus, in order to choose the optimal nutritional access, multidisciplinary clinical evaluation is strongly recommended, taking into account not only the primitive and secondary tumor locations (gastrointestinal vs. extragastrointestinal) and their direct/indirect effects on the digestive tract but also the patient’s overall clinical condition including cancer prognosis, nutritional status, performance status, QoL, potential effects of nutrition support, and the patient’s and his/her relatives’ wishes and expectations [43]Table 2. summarizes the preferential nutritional routes in different cancer sites.

Table 2. Preferential nutritional routes in different cancer sites.

Tumor Site Preferential Nutritional Route Comment
Head, neck EN Choose access according to the expected AN duration:
  • short-term EN: NGT
  • long-term EN: PEG
(RIG or SG when endoscopic procedure is not feasible)
Chest: Esophagus, lung EN Choose access according to the expected AN duration:
  • short-term EN: NGT
  • long-term EN: PEG
(RIG or SG when endoscopic procedure is not feasible)
  • Self-expandable metal stents: lower survival benefit than PEG
Stomach EN/PN Choose access according to the expected AN duration:
  • short-term EN: NJT
  • long-term EN: PEJ
(SJ when endoscopic procedure is not feasible)In presence of bowel sub-obstruction/obstruction, peritoneal carcinomatosis, severe gastrointestinal symptoms, or EN intolerance:
  • consider PN
Pancreas, biliary tract, colon-rectum, uterus, ovary, bladder, prostate PN In presence of bowel sub-obstruction/obstruction, peritoneal carcinomatosis, severe gastrointestinal symptoms:
  • consider PN
Others malignancies (e.g., brain, breast, blood) EN/PN Choose access according to the expected AN duration:
  • short-term EN: NGT or NJT (if gastric dysmotility)
  • long-term EN: PEG or PEJ (if gastric dysmotility)
(RIG or SG or SJ when endoscopic procedure is unfeasible)In presence of bowel sub-obstruction/obstruction, peritoneal carcinomatosis, severe gastrointestinal symptoms, or EN intolerance:
  • consider PN

Legend: AN: artificial nutrition; EN: enteral nutrition; PN: parenteral nutrition; NGT: nasogastric tube; NJT: nasojejunal tube; PEG: percutaneous endoscopic gastrostomy; PEJ: percutaneous endoscopic jejunostomy; RIG: radiologically inserted gastrostomy; SG: surgical gastrostomy; SJ: surgical jejunostomy.

5. Parenteral Nutrition

Regarding nutritional support of patients with cancer, the ESPEN guidelines recommend “In a patient undergoing curative anticancer drug treatment, if oral food intake is inadequate despite counselling and ONS, supplemental enteral or, if this is not sufficient or possible, parenteral nutrition” [43]. However, when curative treatments are no longer available for unresectable locally advanced or metastatic disease, the goal of anticancer treatment is palliative [59]. In fact, chemotherapy is often intended as palliative therapy for patients with advanced cancer [60] because of the expected survival benefit [61]. In these patients, nutritional support should be offered and implemented considering the expected benefit on chemotherapy tolerance and consequently the potential benefit on survival [55].

In addition, ESPEN guidelines strongly recommend HAN, both enteral and parenteral, in cancer patients with persistent insufficient oral intake of nutrients or malabsorption in suitable patients [43].

With regard to the question of the route for delivering AN, this dispute is now over. Indeed, EN and PN are not competitors; conversely, EN and PN have specific indications and contraindications [62]. However, there are many factors that can negatively impact the delivery of EN in advanced cancer patients. Specifically, EN may not be able to meet nutritional needs in cancer patients with extensive bowel resections, high output ileostomy or intestinal fistula, as well as the presence of nutrition impact symptoms (nausea, vomiting, diarrhea, abdominal pain, and constipation due to peritoneal carcinomatosis). Orrevall et al. showed that nausea, vomiting, and gastrointestinal obstructions were the most common indications for PN in palliative patients [63].

A relevant question is the following: when is home parenteral nutrition (HPN) appropriate and suitable in patients without further anticancer treatments? Since 2009, ESPEN guidelines have stated that it is not a contraindication for HPN that oncologic treatment has been stopped [64]. For many years, clinicians have questioned whether all patients with advanced, incurable cancers should ever be sent home with PN [65]. ESPEN guidelines recommend proposing nutritional therapy in those not receiving anticancer treatments after considering, together with the patient, the prognosis and both the expected benefit on QoL and potential survival as well as the burden associated with HAN for them and their caregivers [43].

According to the classification of cancer cachexia [16], refractory cachexia is characterized by a low performance status (Eastern Cooperative Oncology Group-ECOG score 3 or 4) and a life expectancy of less than 3 months. At this stage of the disease trajectory, the cancer patient does not respond to anticancer treatments, just as he/she does not respond to AN aimed at reversing cachexia. This expert opinion is supported by data reporting that cancer patients within 90 days of death have a low probability that nutritional intervention will be able to stop or reserve cachexia [11].

Concerning the ethical aspect of this choice, there has been much debate about whether or not to feed the palliative cancer patient [66]. Denial of this treatment option elicits the following question, “Does this mean I’m going to starve to death?” [67]. This ethical dilemma represents a controversial issue. Indeed, despite the limited benefits, providing AN to cancer patients who are in their last weeks of life is a frequent practice [68].

Referring to the principles of bioethics and ESPEN guidelines [43], the prescription of HAN should be discussed with the patient respecting his/her autonomy and, as also required by law, his/her choice or advance directive to refuse AN.

Regarding clinical appropriateness, HPN is not recommended in patients with worsening clinical conditions (severe organ dysfunction or uncontrolled symptoms), low KPS (<50) or poor ECOG score (≥3), short estimated life expectancy, and patient refusal [62].

Prognosis is obviously an important conditioning issue. ESPEN guidelines have recommended that PN should be considered if the expected survival of cancer patient is greater than 2–3 months [69]. Indeed, predicting survival in incurable cancer patients is not easy, and validated scoring systems should be used [70].

Cancer patients on HPN are not all the same depending on whether or not they are receiving chemotherapy and receiving supplemental or total PN. In a large prospective study analyzing the clinical characteristics and predictive factors of survival of adult cancer patients receiving HPN, it was found that incurable patients receiving total PN were more frequently severely malnourished, more frequently had KPS <70, and had a higher grade of inflammation [71]. As a result, a four-fold lower survival was observed in these patients compared with in the cohort receiving chemotherapy and supplemental PN.

For palliative cancer patients receiving HPN, one of the most important elements that should be monitored is the need to adjust the prescription of HPN as well as when to wean off or discontinue this therapy [72].

Change in QoL represents another crucial issue in patients with cancer receiving HPN. Clinicians should identify cancer patients who might benefit from HPN and balance the potential advantages with HPN without prolonging life in those with no chance of improvement [73]. In a longitudinal study in advanced cancer patients, even those not receiving anticancer treatment, HPN was shown to significantly improve global QoL, physical, role, and emotional functioning [74]. Conversely, several studies identified that worsened QoL was associated with receipt of palliative chemotherapy in patients with advanced cancer at the EoL [59][75].

Sometimes, the use of HPN in cancer patients has been ruled out by clinicians concerned about the risk of complications (bloodstream infection, venous thrombosis, and catheter-related mechanical complications) from handling the central venous access device for HPN infusion. As a matter of fact, if carefully managed, HPN can be safely provided even to advanced cancer patients recording a low rate of complications [76].

Finally, an important question is whether there is evidence of a potential survival benefit depending on HPN in incurable cancer patients. However, there are two methodological difficulties in carrying out a controlled trial in malnourished cancer patients. First, it is not ethically acceptable to have a control group of patients with chronic insufficient food intake (aphagic or severely hypophagic) who receive no nutritional support. Second, in patients receiving both chemotherapy and HPN, there is no evidence of a possible survival advantage exclusively induced by HPN.

In a recent study, the authors attempted to eliminate these two methodological biases. The aim of this study was to compare the survival of malnourished cancer patients in palliative care, eligible for HPN according to guideline recommendations, who received HPN with a homogenous group of patients, equally eligible for HPN, who did not receive HPN but artificial hydration (AH) for logistic reasons or due to patient refusal [77]. Survival of the two groups showed a statistically significant difference favoring patients on HPN who had a median overall survival three times higher than that of the cohort who received AH (4.3 versus 1.5 months, respectively). This increase in median survival (2.8 months) is the same (2.7 months) as that found in cancer patients in the group receiving early palliative care compared with those in the standard care group [9].

References

  1. Bray, F.; Ferlay, J.; Soerjomataram, I.; Siegel, R.L.; Torre, L.A.; Jemal, A. Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J. Clin. 2018, 68, 394–424.
  2. Van Mechelen, W.; Aertgeerts, B.; De Ceulaer, K.; Thoonsen, B.; Vermandere, M.; Warmenhoven, F.; Van Rijswijk, E.; De Lepeleire, J. Defining the palliative care patient: A systematic review. Palliat. Med. 2013, 27, 197–208.
  3. Sepúlveda, C.; Marlin, A.; Yoshida, T.; Ullrich, A. Palliative Care: The World Health Organization’s global perspective. J. Pain Symptom Manag. 2002, 24, 91–96.
  4. Palliative Care-World Health Organization. Available online: (accessed on 5 December 2020).
  5. Bubis, L.D.; Davis, L.; Mahar, A.; Barbera, L.; Li, Q.; Moody, L.; Karanicolas, P.; Sutradhar, R.; Coburn, N.G. Symptom Burden in the First Year After Cancer Diagnosis: An Analysis of Patient-Reported Outcomes. J. Clin. Oncol. 2018, 36, 1103–1111.
  6. Ferrell, B.R.; Temel, J.S.; Temin, S.; Alesi, E.R.; Baldoni, T.A.; Basce, E.M.; Firn, J.I.; Paice, J.A.; Peppercorn, J.M.; Phillips, T.; et al. Integration of Palliative Care Into Standard Oncology Care: American Society of Clinical Oncology Clinical Practice Guideline Update. J. Clin. Oncol. 2017, 35, 96–112.
  7. Osman, H.; Shrestha, S.; Temin, S.; Ali, Z.V.; Corvera, R.A.; Ddung, H.D.; De Lima, L.; Estevez-Diz, M.D.P.; Ferris, F.D.; Gafer, N.; et al. Palliative Care in the Global Setting: ASCO Resource-Stratified Practice Guideline. J. Glob. Oncol. 2018, 4, 1–24.
  8. Isenberg, S.R.; Aslakson, R.A.; Smith, T.J. Implementing Evidence-Based Palliative Care Programs and Policy for Cancer Patients: Epidemiologic and Policy Implications of the 2016 American Society of Clinical Oncology Clinical Practice Guideline Update. Epidemiol. Rev. 2017, 39, 123–131.
  9. Temel, J.S.; Greer, J.A.; Muzikansky, A.; Gallagher, E.R.; Admane, S.; Jackson, V.A.; Dahlin, C.M.; Blinderman, C.D.; Jacobsen, J.; Pirl, W.F.; et al. Early palliative care for patients with metastatic non-small-cell lung cancer. N. Engl. J. Med. 2010, 363, 733–742.
  10. Jordan, K.; Aapro, M.; Kassa, S.; Ripamonti, C.I.; Scotté, F.; Strasser, F.; Young, A.; Bruera, E.; Herrstedt, J.; Keefe, D.; et al. European Society for Medical Oncology (ESMO) position paper on supportive and palliative care. Ann. Oncol. 2018, 29, 36–43.
  11. Kaasa, S.; Loge, J.H.; Aapro, M.; Albreht, T.; Anderson, R.; Bruera, E.; Brunelli, C.; Caraceni, A.; Cervantes, A.; Currow, D.C.; et al. Integration of oncology and palliative care: A Lancet Oncology Commission. Lancet Oncol. 2018, 19, e588–e653.
  12. Zagonel, V.; Torta, R.; Franciosi, V.; Brunello, A.; Biasco, G.; Cattaneo, D.; Cavanna, L.; Corsi, D.; Farina, G.; Fioretto, L.; et al. Early Integration of Palliative Care in Oncology Practice: Results of the Italian Association of Medical Oncology (AIOM) Survey. J. Cancer 2016, 7, 1968–1978.
  13. Zagonel, V.; Franciosi, V.; Brunello, A.; Biasco, G.; Broglia, C.; Cattaneo, D.; Cavanna, L.; Corsi, D.; Farina, L.; Fioretto, L.; et al. Position paper of the Italian Association of Medical Oncology on early palliative care in oncology practice (Simultaneous Care). Tumori 2017, 103, 9–14.
  14. Davis, M.P.; Dickerson, D. Cachexia and anorexia: Cancer’s covert killer. Support. Care Cancer 2000, 8, 180–187.
  15. Ottery, F.D. Cancer cachexia: Prevention, early diagnosis, and management. Cancer Pract. 1994, 2, 123–131.
  16. Fearon, K.; Strasser, F.; Anker, S.D.; Bosaeus, I.; Bruera, E.; Fainsinger, R.L.; Jatoi, A.; Loprinzi, C.; MacDonald, N.; Mantovani, G.; et al. Definition and classification of cancer cachexia: An international consensus. Lancet Oncol. 2011, 12, 489–495.
  17. Argilés, J.M.; Busquets, S.; Stemmler, B.; Lopez-Soriano, F.J. Cachexia e sarcopenia: Mechanism and potential targets for interventions. Curr. Opin. Pharmacol. 2015, 22, 100–106.
  18. DeWys, W.D.; Begg, C.; Lavin, P.T.; Band, P.R.; Bennett, J.M.; Bertino, J.R.; Cohen, M.H.; Douglass, H.O., Jr.; Engstrom, P.F.; Ezdinli, E.Z.; et al. Prognostic effect of weight loss prior to chemotherapy in cancer patients. Eastern Cooperative Oncology Group. Am. J. Med. 1980, 69, 491–497.
  19. Martin, L.; Senesse, P.; Gioulbasanis, I.; Antoun, S.; Bozzetti, F.; Deans, C.; Strasser, F.; Thoresen, L.; Jagoe, R.T.; Chasen, M.; et al. Diagnostic Criteria for the Classification of Cancer-Associated Weight Loss. J. Clin. Oncol. 2014, 33, 90–99.
  20. Ní Bhuachalla, É.B.; Daly, L.E.; Power, D.G.; Cushen, S.J.; MacEneaney, P.; Ryan, A.M. Computed tomography diagnosed cachexia and sarcopenia in 725 oncology patients: Is nutritional screening capturing hidden malnutrition? J. Cachexia Sarcopenia Muscle 2018, 9, 295–305.
  21. Gioulbasanis, I.; Martin, L.; Baracos, V.E.; Thézénas, S.; Koinis, F.; Senesse, P. Nutritional assessment in overweight and obese patients with metastatic cancer: Does it make sense? Ann. Oncol. 2015, 26, 217–221.
  22. Ryan, A.M.; Prado, C.M.; Sullivan, E.S.; Power, D.G.; Daly, L.E. Effects of weight loss and sarcopenia on response to chemotherapy, quality of life, and survival. Nutrition 2019, 67–68, 110539.
  23. Blauwhoff-Buskermolen, S.; Versteeg, K.S.; de van der Schueren, M.A.; den Braver, N.R.; Berkhof, J.; Langius, J.A.; Verheul, H.M. Loss of muscle mass during chemotherapy is predictive for poor survival of patients with metastatic colorectal cancer. J. Clin. Oncol. 2016, 34, 1339–1344.
  24. Lieffers, J.R.; Bathe, O.F.; Fassbender, K.; Winget, M.; Baracos, V.E. Sarcopenia is associated with postoperative infection and delayed recovery from colorectal cancer resection surgery. Br. J. Cancer 2012, 107, 931–936.
  25. Daly, L.E.; Ní Bhuachalla, É.B.; Power, D.G.; Cushen, S.J.; James, K.; Ryan, A.M. Loss of skeletal muscle during systemic chemotherapy is prognostic of poor survival in patients with foregut cancer. J. Cachexia Sarcopenia Muscle 2018, 9, 315–325.
  26. Bozzetti, F. Forcing the vicious circle: Sarcopenia increases toxicity, decreases response to chemotherapy and worsens with chemotherapy. Ann. Oncol. 2017, 28, 2107–2118.
  27. Bozzetti, F. Chemotherapy-Induced Sarcopenia. Curr. Treat. Options Oncol. 2020, 21, 7.
  28. Petersen, K.F.; Shulman, G.I. New insights into the pathogenesis of insulin resistance in human using magnetic resonance spectroscopy. Obesity 2006, 14, 34–40.
  29. Dev, R.; Bruera, E.; Dalal, S. Insuline resistance and body composition in cancer patients. Ann. Oncol. 2018, 29, 18–26.
  30. Nishimura, J.M.; Ansari, A.Z.; D’Souza, D.M.; Moffatt-Bruce, S.D.; Merritt, R.E.; Kneuertz, P.J. Computed tomography-assessed skeletal muscle mass as a predictor of outcomes in lung cancer surgery. Ann. Thorac. Surg. 2019, 108, 1555–1564.
  31. Choi, M.H.; Yoon, S.B.; Lee, K.; Song, M.; Lee, I.S.; Lee, M.A.; Hong, T.H.; Choi, M.G. Preoperative sarcopenia and post-operative accelerated muscle loss negatively impact survival after resection of pancreatic cancer. J. Cachexia Sarcopenia Muscle 2018, 9, 326–334.
  32. Ma, B.W.; Chen, X.Y.; Fan, S.D.; Zhang, F.M.; Huang, D.D.; Li, B.; Shen, X.; Zhuang, C.L.; Yu, Z. Impact of sarcopenia on clinical outcomes after radical gastrectomy for patients without nutritional risk. Nutrition 2019, 61, 61–66.
  33. Raspé, C.; Flöther, L.; Schneider, R.; Bucher, M.; Piso, P. Best practice for perioperative management of patients with cytoreductive surgery and HIPEC. Eur. J. Surg. Oncol. 2017, 43, 1013–1027.
  34. Chowdhry, S.M.; Chowdhry, V.K. Cancer cachexia and treatment toxicity. Curr. Opin. Support. Palliat. Care 2019, 13, 292–297.
  35. Gripp, S.; Mjartan, S.; Boelke, E.; Willers, R. Palliative radiotherapy tailored to life expectancy in end-stage cancer patients: Reality or myth? Cancer 2010, 116, 3251–3256.
  36. Puckett, L.L.; Luitweiler, E.; Potters, L.; Teckie, S. Preventing discontinuation of radiation therapy: Predictive factors to improve patient selection for palliative treatment. J. Oncol. Pract. 2017, 13, 782–791.
  37. Nugent, B.; Lewis, S.; O’Sullivan, J.M. Enteral feeding methods for nutritional management in patients with head and neck cancers being treated with radiotherapy and/or chemotherapy. Cochrane Database Syst. Rev. 2013.
  38. Arends, J. How to feed patients with gastrointestinal mucositis. Curr. Opin. Support. Palliat. Care 2018, 12, 168–173.
  39. Lunney, J.R.; Lynn, J.; Foley, D.J.; Lipson, S.; Guralnik, J.M. Patterns of functional decline at the end of life. JAMA 2003, 289, 2387–2392.
  40. Laviano, A.; Di Lazzaro, L.; Koverech, A. Nutrition support and clinical outcome in advanced cancer patients. Proc. Nutr. Soc. 2018, 77, 388–393.
  41. Prado, C.M.; Sawyer, M.B.; Ghosh, S.; Lieffers, J.R.; Esfandiari, N.; Antoun, S.; Baracos, V.E. Central tenet of cancer cachexia therapy: Do patients with advanced cancer have exploitable anabolic potential? Am. J. Clin. Nutr. 2013, 98, 1012–1019.
  42. Aversa, Z.; Costelli, P.; Muscaritoli, M. Cancer-induced muscle wasting: Latest findings in prevention and treatment. Ther. Adv. Med. Oncol. 2017, 9, 369–382.
  43. Arends, J.; Bachmann, P.; Baracos, V.; Barthelemy, N.; Bertz, H.; Bozzetti, F.; Fearon, K.; Hütterer, E.; Isenring, E.; Kaasa, S.; et al. ESPEN guidelines on nutrition in cancer patients. Clin. Nutr. 2017, 36, 11–48.
  44. General Nutrition and Dietary Treatment Nation-wide guideline, Version: 3.0. Integraal kankercentrum Nederland 2017. Available online: (accessed on 5 December 2020).
  45. Blackwood, H.A.; Hall, C.C.; Balstad, T.R.; Tora, S.; Solheim, T.S.; Fallon, M.; Haraldsdottir, E.; Laird, B.J. A systematic review examining nutrition support interventions in patients with incurable cancer. Support. Care Cancer. 2020, 28, 1877–1889.
  46. Gillespie, L.; Raftery, A.M. Nutrition in palliative and end-of-life care. Br. J. Community Nurs. 2014, S15–S20.
  47. Day, T. Managing the nutritional needs of palliative care patients. Br. J. Nurs. 2017, 26, 1151–1159.
  48. De van der Schueren, M.A.E. Use and effects of oral nutritional supplements in patients with cancer. Nutrition 2019, 67-68, 110550.
  49. Lee, J.L.C.; Leong, L.P.; Lim, S.L. Nutrition intervention approaches to reduce malnutrition in oncology patients: A systematic review. Support. Care Cancer 2016, 24, 469–480.
  50. Sánchez-Lara, K.; Turcott, J.G.; Juárez-Hernández, E.; Nuñez-Valencia, C.; Villanueva, G.; Guevara, P.; De la Torre-Vallejo, M.; Mohar, A.; Arrieta, O. Effects of an oral nutritional supplement containing eicosapentaenoic acid on nutritional and clinical outcomes in patients with advanced non-small cell lung cancer: Randomised trial. Clin. Nutr. 2014, 33, 1017–1023.
  51. Caccialanza, R.; Pedrazzoli, P.; Cereda, E.; Gavazzi, C.; Pinto, C.; Paccagnella, A.; Beretta, G.D.; Nardi, M.; Laviano, A.; Zagonel, V. Nutritional support in cancer patients: A position paper from the Italian society of medical oncology (AIOM) and the Italian society of artificial nutrition and metabolism (SINPE). J. Canc. 2016, 7, 131–135.
  52. Cocks, H.; Ah-See, K.; Capel, M.; Taylor, P. Palliative and supportive care in head and neck cancer: United Kingdom National Multidisciplinary Guidelines. J. Laryngol. Otol. 2016, 130, 198–207.
  53. Bischoff, S.C.; Austin, P.; Boeykens, K.; Chourdakis, M.; Cuerda, C.; Jonkers-Schuitema, C.; Lichota, M.; Nyulasi, I.; Schneider, S.M.; Stanga, Z.; et al. ESPEN guideline on home enteral nutrition. Clin. Nutr. 2020, 39, 5–22.
  54. Ruggeri, E.; Giannantonio, M.; Agostini, F.; Ostan, R.; Pironi, L.; Pannuti, R. Home artificial nutrition in palliative care cancer patients: Impact on survival and performance status. Clin. Nutr. 2020, 39, 3346–3353.
  55. Bozzetti, F. Nutritional support of the oncology patient. Crit. Rev. Oncol. Hematol. 2013, 87, 172–200.
  56. Song, J.H.; Ko, J.; Min, Y.W.; Kim, K.; Lee, H.; Min, B.; Lee, J.H.; Rhee, P.; Kim, J.J. Comparison between Percutaneous Gastrostomy and Self-Expandable Metal Stent Insertion for the Treatment of Malignant Esophageal Obstruction, after Propensity Score Matching. Nutrients 2020, 12, 2756.
  57. Yang, C.W.; Lin, H.H.; Hsieh, T.Y.; Chang, W.K. Palliative enteral feeding for patients with malignant esophageal obstruction: A retrospective study. BMC Palliat. Care 2015, 14, 58.
  58. Yu, F.J.; Shih, H.Y.; Wu, C.Y.; Chuang, Y.S.; Lee, J.Y.; Li, H.P.; Fang, P.T.; Tsai, D.L.; Chou, S.H.; Wu, I.C. Enteral nutrition and quality of life in patients undergoing chemoradiotherapy for esophageal carcinoma: A comparison of nasogastric tube, esophageal stent, and ostomy tube feeding. Gastrointest. Endosc. 2018, 88, 21–31.
  59. Akhlaghi, E.; Lehto, R.H.; Torabikhah, M.; Sharif Nia, H.; Taheri, A.; Zaboli, E.; Yaghoobzadeh, A. Chemotherapy use and quality of life in cancer patients at the end of life: An integrative review. Health Qual. Life Outcomes 2020, 18, 332.
  60. Archer, V.R.; Billingham, L.J.; Cullen, M.H. Palliative chemotherapy: No longer a contradiction in terms. Oncologist 1999, 4, 470–477.
  61. Von Hoff, D.D.; Ervin, T.; Arena, F.P.; Chiorean, E.G.; Infante, J.; Moore, M.; Seay, T.; Tjulandin, S.A.; Ma, W.W.; Saleh, M.N.; et al. Increased survival in pancreatic cancer with nab-paclitaxel plus gemcitabine. N. Engl. J. Med. 2013, 369, 1691–1703.
  62. Cotogni, P. Enteral versus parenteral nutrition in cancer patients: Evidences and controversies. Ann. Palliat. Med. 2016, 1, 42–49.
  63. Orrevall, Y.; Tishelman, C.; Permert, J.; Lundström, S. A national observational study of the prevalence and use of enteral tube feeding, parenteral nutrition and intravenous glucose in cancer patients enrolled in specialized palliative care. Nutrients 2013, 5, 267–282.
  64. Staun, M.; Pironi, L.; Bozzetti, F.; Baxter, J.; Forbes, A.; Joly, F.; Jeppesen, P.; Moreno, J.; Hébuterne, X.; Pertkiewicz, M.; et al. ESPEN Guidelines on Parenteral Nutrition: Home parenteral nutrition (HPN) in adult patients. Clin. Nutr. 2009, 28, 467–479.
  65. Hoda, D.; Jatoi, A.; Burnes, J.; Loprinzi, C.; Kelly, D. Should patients with advanced, incurable cancers ever be sent home with total parenteral nutrition? A single institution’s 20-year experience. Cancer 2005, 103, 863–868.
  66. Bozzetti, F. The patient with incurable aphagic cancer: To feed or not to feed? Nutrition 2001, 17, 676–677.
  67. Whitworth, M.K.; Whitfield, A.; Holm, S.; Shaffer, J.; Makin, W.; Jayson, G.C. Doctor, does this mean I’m going to starve to death? J. Clin. Oncol. 2004, 22, 199–201.
  68. Raijmakers, N.J.; van Zuylen, L.; Costantini, M.; Caraceni, A.; Clark, J.; Lundquist, G.; Voltz, R.; Ellershaw, J.E.; van der Heide, A.; OPCARE9. Artificial nutrition and hydration in the last week of life in cancer patients. A systematic literature review of practices and effects. Ann. Oncol. 2011, 22, 1478–1486.
  69. Bozzetti, F.; Arends, J.; Lundholm, K.; Micklewright, A.; Zurcher, G.; Muscaritoli, M. ESPEN guidelines on parenteral nutrition: Non-surgical oncology. Clin. Nutr. 2009, 28, 445–454.
  70. Bozzetti, F.; Cotogni, P.; Lo Vullo, S.; Pironi, L.; Giardiello, D.; Mariani, L. Development and validation of a nomogram to predict survival in incurable cachectic cancer patients on home parenteral nutrition. Ann. Oncol. 2015, 26, 2335–2340.
  71. Cotogni, P.; Monge, T.; Passera, R.; Brossa, L.; De Francesco, A. Clinical characteristics and predictive factors of survival of 761 cancer patients on home parenteral nutrition: A prospective, cohort study. Cancer Med. 2020, 9, 4686–4698.
  72. Cotogni, P.; Caccialanza, R.; Pedrazzoli, P.; Bozzetti, F.; De Francesco, A. Monitoring Response to Home Parenteral Nutrition in Adult Cancer Patients. Healthcare 2020, 8, 183.
  73. Sowerbutts, A.M.; Lal, S.; Sremanakova, J.; Clamp, A.R.; Jayson, G.C.; Teubner, A.; Hardy, L.; Todd, C.; Raftery, A.M.; Sutton, E.; et al. Palliative home parenteral nutrition in patients with ovarian cancer and malignant bowel obstruction: Experiences of women and family caregivers. BMC Palliat. Care 2019, 18, 120.
  74. Cotogni, P.; De Carli, L.; Passera, R.; Amerio, M.L.; Agnello, E.; Fadda, M.; Ossola, M.; Monge, T.; De Francesco, A.; Bozzetti, F. Longitudinal study of quality of life in advanced cancer patients on home parenteral nutrition. Cancer Med. 2017, 6, 1799–1806.
  75. Prigerson, H.G.; Bao, Y.; Shah, M.A.; Paulk, M.E.; LeBlanc, T.W.; Schneider, B.J.; Garrido, M.M.; Reid, M.C.; Berlin, D.A.; Adelson, K.B.; et al. Chemotherapy Use, Performance Status, and Quality of Life at the End of Life. JAMA Oncol. 2015, 1, 778–784.
  76. Cotogni, P.; Mussa, B.; Degiorgis, C.; De Francesco, A.; Pittiruti, M. Comparative complication rates of 854 central venous access devices for home parenteral nutrition in cancer patients: A prospective study of over 169,000 catheter-days. J. Parenter. Enteral. Nutr. 2020.
  77. Cotogni, P.; Ossola, M.; Passera, R.; Monge, T.; Fadda, M.; De Francesco, A.; Bozzetti, F. Home parenteral nutrition versus artificial hydration in malnourished patients with cancer in palliative care: A prospective, cohort survival study. BMJ Support. Palliat. Care 2020.
More
© Text is available under the terms and conditions of the Creative Commons Attribution (CC BY) license; additional terms may apply. By using this site, you agree to the Terms and Conditions and Privacy Policy.
Upload a video for this entry
Information
Subjects: Nutrition & Dietetics
Contributor MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register :
Paolo Cotogni
View Times: 468
Revisions: 2 times (View History)
Update Date: 07 Apr 2021
Table of Contents
    1000/1000
    Hot Most Recent
    ScholarVision Creations
    Feedback