Always consult your healthcare provider!

Metabolic Principles in Cancer Treatment

On cancer cells’ unique appetite—and how it might be turned against them. Or why our dietary choices might not be as irrelevant as one might think. (Illustrations should be considered as vignettes.)

Contents, Section 1:

  1. Cancer cells’ unique energy needs (scroll down)
  2. The Warburg effect (scroll to)
  3. Which energy pathways are being targeted (scroll to)
  4. The role of the tumor microenvironment (scroll to)
  5. New treatments on the horizon (scroll to)
  6. Can cancer be starved with diet? (scroll to)
  7. Conclusion: The Future (scroll to)
  8. Reference list for the text (scroll to)

Sektion 2:

  1. Comprehensive reference list for the topic as a whole (scroll to)

Summary: Can Cancer Be Starved – On Metabolic Cancer Treatment

The Warburg Effect:

Cancer cells have a unique way of obtaining energy, known as the Warburg effect, where they primarily use sugar (glucose) to grow rapidly, even in the presence of oxygen. This “unique appetite” distinguishes them from normal cells and opens the door to new treatment strategies.

Dr. Thomas Seyfried:

Researchers and pioneers like Dr. Thomas Seyfried argue that cancer is fundamentally a metabolic disease, and that the vulnerability of cancer cells can be exploited by targeting their energy pathways.

What Is the Main Idea

  1. Target cancer cells’ energy sources: Cancer cells are highly dependent on glucose and glutamine. By limiting access to these nutrients, their growth can potentially be inhibited.
  2. Ketogenic diet as a tool: A ketogenic diet (very low carbohydrate, high fat) can force the body to use ketones as fuel instead of glucose.
    This creates an environment that is unfavorable for many cancer cells, while it is often beneficial for normal cells.
    Dr. Seyfried’s research highlights this as a potential supplement to conventional treatment.
  3. Targeted supplements/herbs: Some substances are being investigated for their ability to affect the spread of cancer cells.
  4. New drugs in development: Research is also developing medications that specifically block enzymes that cancer cells use to convert sugar and other nutrients (e.g., substances that inhibit Hexokinase, PKM2, or Glutaminase).
  5. Understanding the tumor’s “neighborhood”: Cancer cells collaborate with the cells around them. By also affecting the metabolism of these “neighboring cells,” a more hostile environment for the tumor can be created.

Important: Dietary approaches should be seen as potential complementary strategies and, if desired, implemented in collaboration with your healthcare provider. The goal is to exploit the metabolic vulnerability of cancer cells to improve the effectiveness of treatment and the body’s overall health.

Targeting Cancer Metabolism – Starving Cancer

Summary

This review attempts to provide a more detailed introduction to the concept of targeting cancer treatment by utilizing the unique metabolism of cancer cells as a treatment strategy. It explains how cancer cells, unlike normal cells, often exhibit the Warburg effect (aerobic glycolysis) to support rapid growth and survival. It covers the history behind this discovery, the metabolic pathways (glucose, glutamine, lipids) that are central therapeutic targets, and how the tumor microenvironment and dietary approaches play a role. It also highlights clinical trials with metabolic inhibitors and the challenges and perspectives associated with this promising, yet complex, approach to cancer treatment.

1. Introduction: Understanding the Metabolic Vulnerability of Cancer Cells

Metaboliske principper. Her er et billede, der illustrerer de metaboliske veje i kræftceller og deres interaktioner med tumormikromiljøet

Energy

To maintain life and function, all cells in our body depend on a constant supply of energy. This energy is primarily produced through metabolic processes where nutrients such as glucose are converted into adenosine triphosphate (ATP), the cell’s primary energy currency (1).

In normal cells, there is a fine balance between two main pathways for energy production: glycolysis and oxidative phosphorylation (OXPHOS). Glycolysis occurs in the cell’s cytoplasm, where glucose is broken down into pyruvate and produces a small amount of ATP. In the presence of oxygen, pyruvate is primarily directed into the mitochondria, the cell’s “power plants,” where it undergoes the citric acid cycle (also known as the Krebs cycle or TCA cycle) and subsequent OXPHOS, a process that generates a much larger amount of ATP (2). This efficient energy production is crucial for the specialized functions and maintenance of normal cells.

Significant Changes

Cancer cells, however, exhibit significant changes in their metabolic pathways compared to normal cells. To support their rapid growth, uncontrolled division (proliferation), and ability to survive in various and often hostile microenvironments, cancer cells have reprogrammed their metabolic machinery. These changes include increased nutrient uptake, altered direction of metabolic processes (flux), and altered regulation of key metabolic enzymes. One of the most characteristic features of this metabolic reprogramming is the Warburg effect (2), where cancer cells prefer glycolysis as their primary pathway for energy production, even when sufficient oxygen is present.

Targeting Vulnerabilities

The concept of targeting these unique metabolic vulnerabilities in cancer cells represents a promising strategy in cancer treatment. By inhibiting the energy and biosynthetic pathways that are crucial for tumor growth and survival, researchers hope to limit the proliferation of cancer cells, induce cell death (apoptosis), and ultimately control the progression of the disease (3).

This description will attempt to delve deeper into the scientific basis for such an approach, focusing on the central metabolic pathways identified as potential therapeutic targets and the various strategies used in the attempt to “starve” cancer cells.

2. The historical perspective: Otto Warburg and aerobic glycolysis

Metaboliske principper. Her er endnu et billede, der viser kræftceller i interaktion med tumormikromiljøet

Groundbreaking Observation

In the early 20th century, the German biochemist Otto Warburg made a groundbreaking observation that would revolutionize our understanding of cancer metabolism (3). He discovered that cancer cells exhibited an unusually high consumption of glucose and a significant production of lactate (lactic acid), even in environments with sufficient oxygen. This observation, later known as the Warburg effect or aerobic glycolysis, stood in stark contrast to the primary metabolic process used by normal cells in oxygen-rich environments, namely the far more efficient oxidative phosphorylation (2).

The Mechanism Behind the Warburg Effect

The mechanism behind the Warburg effect involves a fundamental change in how cancer cells process glucose (compared to normal cells) to generate both energy and the building blocks necessary to create new cancer cells (4). Like normal cells, cancer cells take up glucose from their surroundings and convert it to pyruvate through glycolysis, which occurs in the cytoplasm. In normal cells, pyruvate is transported under oxygen-rich conditions into the mitochondria to undergo OXPHOS (see above), resulting in high ATP production (about 36 ATP molecules per glucose molecule).

Cancer cells deviate from this pathway by largely limiting the use of OXPHOS, even when there is plenty of oxygen. Instead, they convert pyruvate to lactate in the cytoplasm. This process, known as lactate fermentation, regenerates NAD+, a coenzyme necessary for glycolysis to continue, but it produces only a very limited amount of ATP (just 2 ATP molecules per glucose molecule) (4).

Advantages of the Warburg Effect for Cancer Cells

Although the Warburg effect is much less efficient in terms of ATP production compared to OXPHOS, it is believed that this metabolic reprogramming provides cancer cells with several critical advantages (5):

First, it enables rapid ATP production, which can be beneficial in areas of the tumor with fluctuating oxygen availability. Second, glycolysis generates important intermediates essential for the biosynthesis of macromolecules, such as ribose for DNA and RNA synthesis, and glycerol and citrate for lipid synthesis, which are required in large quantities to build new cells during rapid growth.

Additionally, the increased production of lactate and the resulting acidic environment in the tumor can promote tumor invasion by breaking down surrounding tissue and inhibiting the activity of immune cells in the tumor microenvironment, making it easier for cancer cells to evade the immune system (5).

Diagnostic Significance of the Warburg Effect

The increased glucose uptake, a hallmark of cancer cells due to the Warburg effect, has an important application in cancer diagnostics. Positron emission tomography (PET) scans exploit this metabolic peculiarity to detect tumors in the body (4).

In a PET scan, a radioactively labeled glucose analog, typically 18F-fluorodeoxyglucose (18F-FDG), is injected into the patient’s bloodstream. Due to the elevated metabolic activity and dependence on glucose, malignant cancer cells accumulate a higher concentration of this radioactive tracer compared to the surrounding normal tissue. This difference in uptake allows doctors to visualize and thus locate tumors using PET scans.

The combination of PET scans with computed tomography (CT) scans (PET/CT) provides even more precise information by combining the metabolic data from PET with the detailed anatomical images from CT scans. This diagnostic application underscores the continued clinical relevance of the Warburg effect in managing cancer diseases.

Evolution in the Understanding of the Warburg Effect

Our understanding of the Warburg effect and its role in cancer development has evolved significantly since Warburg’s original discovery. Warburg initially hypothesized that defective mitochondria could be the cause of the increased glycolysis rate in tumor cells and perhaps even a primary cause of cancer development itself.

Today, however, it is widely recognized that genetic mutations in oncogenes (genes that promote cancer) and tumor suppressor genes are the primary drivers behind malignant transformation, and that the Warburg effect is rather a consequence of these genetic changes than a primary cause (6).

The metabolic change is now considered an adaptation that provides cancer cells with selective advantages, such as the ability to survive in low-oxygen environments within tumors or as a result of cancer genes “shutting down” mitochondrial function in programmed cell death (apoptosis) (6).

Nevertheless, the Warburg effect has retained its status as a central hallmark of cancer and an important area for therapeutic interventions.

Dr. Thomas Seyfried

In recent times, Dr. Thomas Seyfried (27) has revived and significantly advanced this line of thinking. He is a prominent advocate for the theory that cancer is primarily a metabolic disease, where mitochondrial dysfunction plays a central role, in contrast to the dominant view that focuses on genetic mutations as the primary cause. His research has intensely focused on how metabolic therapies, not least ketogenic diets and calorie restriction, can affect the energy supply of cancer cells and thus their growth and survival (22).

Seyfried argues that damaged mitochondrial function may be a primary underlying factor in cancer, driving cells to increase glycolysis as a compensatory mechanism. This perspective nuances the established view and highlights the importance of metabolic dysfunctions in the development and treatment of cancer.

Clinical Relevance Today

The Warburg effect, once considered a curiosity, is today a cornerstone in cancer diagnostics and an intense area of research for the development of new treatments. Warburg’s observation from nearly a century ago forms the basis for our understanding of cancer cells’ unique metabolic needs. This fundamental difference from normal cells opened the possibility of therapeutically targeting these specific metabolic pathways. The fact that this metabolic change can be detected using PET scans underscores its continued clinical relevance.

The shift in the view of the Warburg effect—from a primary cause to a consequence of genetic changes—has refined treatment methods. The focus is now on the underlying genetic processes and the cells’ communication and response systems that collectively control metabolic reprogramming.

While Warburg’s original hypothesis about mitochondrial dysfunction was important when it emerged, the later understanding that oncogenes and tumor suppressor genes orchestrate this metabolic shift allows for more targeted interventions that could potentially reverse or normalize cancer metabolism.

It is also important to note that the Warburg effect is not uniform across all cancer types and stages, suggesting the need for personalized strategies for metabolic targeting that account for variations in intensity and the specific mechanisms depending on the cancer type, its progression stage, and the genetic composition of the cancer cells.

See also Cancer as a Metabolic Disorder

3. Central Metabolic Pathways as Therapeutic Targets

Metaboliske principper. Her er et billede, der viser en metabolisk vej i kræftceller, hvor en specifik del er blokeret

Cancer cells’ altered metabolism creates a number of potential “weak points” that researchers are trying to exploit therapeutically. By targeting specific enzymes and transport proteins that are crucial for cancer cells’ energy production and growth, it is hoped that their survival can be disrupted.

Glucose Metabolism as a Target

Glucose metabolism plays a fundamental role in cancer biology, as it provides the necessary energy and building blocks for the rapid growth and division of cancer cells (7). Glycolysis, the primary pathway for glucose metabolism, is particularly important for fast-growing cancer cells.

In addition to producing ATP, albeit inefficiently in the Warburg effect, glycolysis also generates important intermediates necessary for the synthesis of amino acids, nucleotides, and lipids—all crucial for building new cell mass in cancer cells. The characteristically high glucose consumption in many cancer forms is exploited diagnostically in PET scans, as previously mentioned (4).

This strong dependence on glucose has led researchers like Dr. Thomas Seyfried to argue that limiting glucose availability, e.g., through a ketogenic diet, could be an effective therapeutic strategy (22).

Targeting Hexokinase (HK)

A central target in glucose metabolism is the enzyme hexokinase (HK), which initiates glycolysis by catalyzing the phosphorylation of glucose to glucose-6-phosphate (8). Among the various variants of hexokinase, hexokinase II (HK2) is often overexpressed in many cancer forms and is associated with increased growth and poorer prognosis (8).

Therefore, substances that inhibit HK2 are being investigated as potential cancer treatments. Examples include 2-deoxy-D-glucose (2-DG) and 3-bromopyruvate (3-BrPA), which have shown promising results in laboratory studies. A newer substance, benitrobenrazide (BNBZ), is more specific for HK2 and effectively blocks cancer cell growth. Another strategy is to use molecules (PROTACs) to selectively degrade the HK2 protein in cancer cells.

Pyruvate Kinase M2 (PKM2) as a Target

Another important enzyme in glycolysis is pyruvate kinase M2 (PKM2), which catalyzes the final step in the pathway (9). PKM2 is often found at higher levels in cancer and plays a role in the Warburg effect. The enzyme can have different forms with varying activity, and cancer cells favor a form that allows the accumulation of building blocks for cell growth.

Substances that inhibit PKM2 have shown anti-tumor activity in the laboratory, and the same applies to substances that activate another form of PKM2 in certain cancer types. PKM2 also has other functions in the cell, making targeting complex.

Strategies Against Glycolysis

Targeting various steps in glycolysis provides multiple opportunities to disrupt cancer cells’ energy and growth. Inhibiting key enzymes such as HK and PKM2 can block the pathway and deprive cancer cells of important resources.

Research into both inhibitors and activators of these enzymes shows a complexity in targeting metabolism, where the specific context of the cancer type is crucial for the therapeutic approach.

Glutamine Metabolism

Glutamine, another important nutrient, serves as a significant source of both energy and building blocks for cancer cells (10). Many cancer forms are highly dependent on glutamine for their survival and growth.

The enzyme glutaminase (GLS) is the first step in glutamine metabolism, and substances that inhibit GLS are being investigated for use as cancer treatments. Additionally, cancer cells often increase their uptake of glutamine from their surroundings by overexpressing specific transport proteins on the cell surface, which can also be targets for therapy.

Lipid Metabolism as a Target

Abnormal metabolism of fats (lipids) is also a hallmark of cancer (11). Cancer cells often increase their ability to produce fatty acids themselves (de novo lipogenesis) and to uptake and break down fatty acids (fatty acid oxidation) to meet their needs for energy, signaling molecules, and building blocks for cell membranes.

Enzymes involved in fatty acid synthesis, such as fatty acid synthase (FASN) and stearoyl-CoA desaturase (SCD), as well as the enzyme ATP-citrate lyase (ACLY), which connects glucose and fat metabolism, are all under investigation as potential therapeutic targets. Inhibition of these enzymes has shown promising results in laboratory studies.

Other Metabolic Targets

In addition to glucose, glutamine, and lipids, other metabolic pathways and enzymes are being investigated as targets. One example is isocitrate dehydrogenase (IDH), where mutations in certain cancer forms lead to the production of a substance (2-hydroxyglutarate) that promotes cancer development (12).

Drugs have been developed that specifically inhibit the mutated forms of IDH, and these have shown clinical benefits in certain cancer types. This underscores the potential of targeting specific metabolic changes based on genetic mutations.

Table 1: Key metabolic enzymes targeted in cancer treatment

(Here is the table – although I cannot claim that the content is crystal clear to me – perhaps you are more insightful…)

EnzymeRole in cancer metabolismExamples of inhibitors/activators under investigationRelevant cancer types
Hexokinase (HK)First step in glycolysis, glucose phosphorylation2-DG, 3-BrPA, BNBZMany cancers with increased glycolysis
PKM2Last step in glycolysis, PEP to pyruvate conversionShikonin, Compound 3K, TEPP-46Ovarian cancer, prostate cancer, lung cancer, glioblastoma
Glutaminase (GLS)First step in glutamine metabolism, glutamine to glutamateCB-839 (Telaglenastat), DONTriple-negative breast cancer, hematological malignancies
FASNKey enzyme in de novo lipogenesis (DNL)Cerulenin, Orlistat, TVB-2640Prostate cancer, breast cancer, colorectal cancer, lung cancer
SCDConversion of saturated to monounsaturated fatty acidsCAY10566, MK-8245, A939572, CVT-11127Ovarian cancer, glioblastoma, hepatocellular carcinoma, lung cancer, breast cancer, prostate cancer
ACLYLinks glucose metabolism to fatty acid synthesisBMS-303141, SB-204990, Bempedoic acidOvarian cancer, prostate cancer, lung cancer, breast cancer
IDHCatalyzes the conversion of isocitrate to α-ketoglutarateIvosidenib, Enasidenib, Vorasidenib, ZotiraciclibAML, cholangiocarcinoma, glioma, chondrosarcoma

4. The Tumor Microenvironment and Metabolic Interaction

Metaboliske principper illustreret ved cellelignende element i midten og forskellige former i kreds om denne. Tunger ud til baggrund i lilla.

Complex Network

Cancer cells do not exist in isolation; they constantly interact with their surrounding environment, known as the tumor microenvironment (TME) (13). The TME consists of various cell types, including immune cells, fibroblasts (connective tissue cells), blood vessels (endothelial cells), and the extracellular matrix (ECM), a complex network of proteins and other molecules.

The interactions between cancer cells and these components of the TME play a crucial role in tumor growth, invasion, metastasis (spread), and resistance to treatment. Interestingly, metabolism in the TME is also strongly involved in these processes.

Metabolic Symbiosis and Competition

There is a complex metabolic interaction between cancer cells and the other cells in the TME. For example, cancer cells that primarily use glycolysis (the Warburg effect) may secrete large amounts of lactate. This lactate can be taken up by other cancer cells in different areas of the tumor, or by stromal cells such as fibroblasts and endothelial cells, which can use it as an energy source via oxidative phosphorylation (14). This form of metabolic “division of labor” or metabolic symbiosis can promote tumor growth and survival.

Conversely, there may also be metabolic competition within the TME. Cancer cells compete with immune cells for important nutrients such as glucose and glutamine (15). The high consumption of glucose by cancer cells can create a glucose-poor environment that inhibits the activity of certain immune cell types, such as cytotoxic T cells, which are essential for killing cancer cells. Similarly, a lack of other nutrients in the TME may negatively affect the immune response.

Metabolic Reprogramming of TME Components

Cancer cells can also actively reprogram the metabolism of other cells in the TME in order to promote their own survival and growth. For example, cancer cells may secrete signaling molecules that induce a “cancer-associated fibroblast” (CAF) phenotype in normal fibroblasts. CAFs display altered metabolism and produce growth factors, cytokines, and ECM components that support tumor growth, angiogenesis (formation of new blood vessels), and immunosuppression (16).

More specifically, cancer cells may secrete:

Extracellular vesicles (EVs): Small vesicles released from cells containing proteins, RNA, and other molecules that can be transferred to other cells and alter their function.

Cytokines: These are small signaling proteins that can affect immune cells and other cell types in the TME. Examples include TGF-beta and TNF-alpha.

Chemokines: A subgroup of cytokines that specifically attract immune cells and other cells to the tumor. Examples include CXCL12.

Growth factors: Proteins that stimulate cell growth and division. Examples include VEGF (vascular endothelial growth factor), which promotes the formation of new blood vessels (angiogenesis), and PDGF (platelet-derived growth factor).

Enzymes: Cancer cells can secrete enzymes such as matrix metalloproteinases (MMPs), which break down the extracellular matrix and facilitate invasion and metastasis.

Metabolites: Waste products from the altered metabolism of cancer cells, such as lactate, can affect the pH value in the TME and influence the function of immune cells and fibroblasts.

Therapeutic Consequences of TME Metabolism

Understanding the metabolic interactions in the TME provides new opportunities for therapeutic intervention (treatment). By targeting metabolism, not only in the cancer cells themselves but also in the supportive cells within the TME, it may be possible to create a more unfavorable environment for tumor growth and improve the effect of other treatments, such as immunotherapy.

For example, inhibition of lactate transporters (MCT1 and MCT4) on both cancer cells and stromal cells (supportive tissue) may disrupt metabolic symbiosis and potentially inhibit tumor growth (14). Similarly, strategies aimed at “reviving” metabolism in immune cells within the TME may improve their ability to fight cancer.

Metabolic Heterogeneity Within Tumors

It is important to note that there is often considerable metabolic heterogeneity (variation) within a single tumor (17). Cancer cells in different areas of the tumor may have different access to nutrients and oxygen, which can lead to differences in their metabolic profiles.

Cells in oxygen-poor (hypoxic) areas of the tumor are often more dependent on glycolysis, whereas cells closer to blood vessels may have a higher degree of oxidative phosphorylation.

This metabolic heterogeneity may influence treatment response, since different metabolic profiles may make cells more or less sensitive to specific metabolic inhibitors.

5. Clinical Translation and Therapeutic Strategies Under Development

Metaboliske principper. Her er et billede, der viser kulhydratmetabolismen i kræftceller og deres mikromiljø

The promising results from preclinical research into targeting cancer metabolism are increasingly being translated into clinical practice. Several inhibitors of central metabolic enzymes are currently being evaluated in clinical trials, either as stand-alone treatments or in combination with other anticancer drugs.

Inhibitors in Clinical Trials

As mentioned earlier, inhibitors of glutaminase (e.g. telaglenastat/CB-839), MCT1 (e.g. AZD3965), and IDH (e.g. ivosidenib, vorasidenib) are among the metabolic drugs that have shown promising results in early clinical studies (18). Telaglenastat, an oral glutaminase inhibitor, has been investigated in combination with other treatments in various advanced solid tumors.

AZD3965, a selective inhibitor of MCT1 and MCT4, has been evaluated in phase I clinical trials and has been shown to be well tolerated and to have an effect on tumor metabolism.

Among IDH inhibitors, ivosidenib and enasidenib have received FDA approval in the United States for the treatment of certain forms of acute myeloid leukemia (AML) with specific IDH1 or IDH2 mutations, underscoring the clinical validity of targeting cancer-specific metabolic changes.

Vorasidenib is another IDH inhibitor that has shown significant improvement in progression-free survival in patients with low-grade gliomas with IDH1 or IDH2 mutations and has received FDA approval in the United States for this indication.

Bempedoic acid, an ACLY inhibitor, is approved for cholesterol lowering, but its potential as an anticancer drug is also being investigated in clinical studies.

Ketogenic Diet

Dr. Thomas Seyfried has been a driving force behind the research into, and advocacy for, the use of ketogenic diets in clinical trials, especially in aggressive cancers such as glioblastoma. His work has helped initiate (start) and shape many of the studies evaluating the diet’s feasibility, safety, and potential to affect tumor growth and patient survival. This is often in combination with standard treatments or other metabolic inhibitors such as 6-diazo-5-oxo-L-norleucine (DON) (26).

Combination Therapies

An important strategy for improving the effectiveness of metabolic inhibitors and overcoming potential mechanisms of resistance is to combine them with other forms of cancer treatment, such as chemotherapy, radiation therapy, immunotherapy, or other targeted therapies (19). For example, the combination of glutaminase inhibitors with chemotherapy is being investigated in certain cancer types. Preclinical studies have also suggested synergistic effects from combining ACLY inhibition with PD-L1 blockade (a type of immunotherapy) to improve the immune response against tumors. Similarly, combinations of hexokinase and PKM2 inhibitors with traditional chemotherapeutic agents are being evaluated to increase sensitivity and improve treatment outcomes.

Challenges and Perspectives

The development of effective and selective metabolic inhibitors is not without challenges. Many metabolic pathways are closely interconnected, and the enzymes targeted by therapy often also play important roles in the function of normal cells, increasing the risk of toxicity and side effects. In addition, cancer cells may develop resistance mechanisms to metabolic inhibitors by activating alternative metabolic pathways or altering the expression of the target enzyme.

Despite these challenges, the field of metabolic targeting in cancer treatment remains a promising area with significant potential. The growing understanding of the complex metabolic changes in cancer and the interactions within the tumor microenvironment is paving the way for the development of more specific and effective therapeutic strategies.

Future research efforts will likely focus on identifying biomarkers that can predict which patients will benefit most from specific metabolic therapies, developing more selective inhibitors with fewer side effects, and exploring new combination strategies that can attack cancer cells on several metabolic fronts simultaneously.

Table 2: Examples of Clinical Trials With Metabolic Inhibitors

Target enzymeInhibitor(s)Cancer type(s)PhaseStatus
GlutaminaseCB-839Various solid tumors and hematological malignanciesI–IIOngoing / Completed
MCT1AZD3965Various solid tumorsICompleted
IDH1IvosidenibAML, cholangiocarcinoma, chondrosarcoma, gliomaI–IIIApproved for certain indications
IDH1/2VorasidenibLow-grade gliomasIIIApproved
ACLYBempedoic acidDyslipidemia (also being investigated in cancer)IIIApproved for dyslipidemia

6. Can Cancer Be Starved Through Dietary Approaches

Metaboliske principper. Her er et billede, der viser metabolisme generelt i kræftceller og deres mikromiljø

Seyfried’s Central Thesis

The idea of influencing cancer through dietary changes, especially by restricting glucose through a ketogenic diet, is a field of research in which Dr. Thomas Seyfried has been a pioneer and to which he continues to dedicate his research. His central thesis, described in detail in his book Cancer as a Metabolic Disease (25), is that cancer is fundamentally a disease caused by damaged mitochondrial respiration, which forces cells to switch to fermentation (glycolysis) for energy (26). He argues passionately that a ketogenic diet, by reducing blood glucose and insulin and increasing ketone bodies, can exploit this metabolic vulnerability and create a metabolic environment that is directly unfavorable to many cancer cells that primarily depend on glucose for energy, while at the same time supporting the health of normal cells.

The rationale behind this concept is that by depriving cancer cells of their primary fuel sources, one can potentially inhibit their growth and survival (20).

Ketogenic diets, which are characterized by a very low carbohydrate content and a high fat content, force the body to shift its primary energy substrate from glucose to ketone bodies. This shift in energy source is thought to create a metabolic environment that is unfavorable to cancer cells, which in many cases are highly dependent on glucose. Similarly, restriction of glutamine intake is being investigated as a possible strategy, since many cancer cells have an increased need for this amino acid for both energy production and biosynthesis (21).

See also Ketogenic Diet – LCHF

See also Carnivore Diet

Clinical Evidence for Dietary Interventions

Although preclinical studies in cell cultures and animal models have shown some promising results for dietary interventions in specific cancer types, robust clinical evidence in humans is still limited and complex (22). Ketogenic diets have in some smaller clinical studies been shown to be feasible and to have minimal side effects in certain patient groups with specific cancer types, such as glioblastoma (an aggressive brain tumor). These studies have in some cases reported disease stabilization or even some tumor reduction. However, it is important to note that the effectiveness of dietary restriction appears to vary considerably depending on the cancer type, the genetic composition/origin of the tumor, and individual patient factors.

When it comes to glutamine restriction, the picture is even more complex. The body is able to produce glutamine itself, and cancer cells can potentially adapt and obtain glutamine from other metabolic pathways or from the breakdown of proteins (21). This makes it difficult to achieve effective systemic glutamine restriction solely through diet without potentially causing significant malnutrition and other negative health effects.

Some smaller clinical studies, including studies inspired by Dr. Seyfried’s work, have shown that a ketogenic diet can be feasible and, as mentioned above, have certain effects in patients with specific cancer types such as glioblastoma, but more extensive research is needed.

Misconceptions About “Starving Cancer”

There are widespread misconceptions, especially in popular culture and on the internet, that cancer can be treated effectively simply by reducing overall food intake or drastically restricting carbohydrates in order to “starve” tumors.

It should be mentioned here that leading oncologists still emphasize the importance of cancer patients maintaining a healthy and balanced diet in order to support their overall health, preserve muscle mass, strengthen the immune system, and improve tolerance of conventional cancer treatments such as chemotherapy and radiation therapy (23).

Severe and uncontrolled restriction of nutrients can lead to malnutrition, weight loss, muscle wasting (cachexia), and a general deterioration of the patient’s condition, which can have serious and even life-threatening consequences.

Dietary interventions in cancer patients should therefore be considered potential complementary strategies and should only be implemented under the guidance and supervision of qualified healthcare professionals.

One should never regard a diet – however effective it may appear to be – as an intervention that can stand alone as a treatment for cancer. (I do not actually think that a ketogenic diet carries a particularly high risk of muscle loss, since it normally includes relatively large amounts of protein (and fat), but possibly a risk of vitamin deficiencies).

In this context, it should be mentioned that Dr. Seyfried’s approach, although restrictive, is based on a specific scientific hypothesis and differs from more general and uninformed “starvation diets”.

The Role of Evidence-Based Nutritional Guidance

Although the idea of “starving cancer” through dietary interventions is theoretically appealing and has shown some promising results in preclinical models, the scientific basis for its broad effectiveness in humans is still under development and requires careful interpretation (22).

It is biologically plausible that restricting nutrients on which cancer cells are highly dependent (e.g. glucose) could potentially inhibit their growth. However, the complex metabolic system of the human body and the remarkable ability of cancer cells to adapt to changes in their environment make it challenging to effectively “starve” tumors through diet alone, without also negatively affecting the patient’s overall health.

Dietary interventions should therefore be regarded as potential complementary strategies that can be used in combination with conventional cancer treatments. While extreme and uncontrolled dietary restrictions are strongly discouraged, specific dietary approaches, such as a supervised ketogenic diet, may potentially play a supportive role in the treatment of certain cancer types in selected individuals, when integrated into a comprehensive treatment plan and closely monitored by a multidisciplinary treatment team. However, more extensive and well-designed clinical studies are needed to define the specific contexts (cancer types, stages, patient characteristics) and the precise protocols in which these dietary interventions may be beneficial and safe.

Researchers such as Dr. Thomas Seyfried emphasize the importance of understanding cancer as a metabolic disease, which may potentially open up new dietary strategies as a supplement to conventional treatment.

Table 3: Dietary Interventions in Cancer: Rationale and Evidence

Dietary interventionRationaleEvidence
Ketogenic dietRestricts glucose and forces the body to use ketones as an energy sourcePreclinical studies show potential in certain cancer types; robust clinical evidence in humans remains limited, but the approach appears to have minimal toxicity.
Glutamine restrictionRestricts the availability of an important nutrient for cancer cellsCancer cells may produce glutamine themselves or obtain it from alternative sources; evidence for effectiveness as a monotherapy remains limited.
Metaboliske principper. Her er et billede, der viser kræftmetabolismen på en mere abstrakt og stiliseret måde

Significant Progress

Targeting the unique metabolism of cancer cells as a treatment strategy has secured significant advances in our understanding of the complex metabolic changes that characterize cancer cells, and in the development of therapeutic strategies specifically aimed at exploiting these metabolic vulnerabilities (24).

Since the groundbreaking discovery of the Warburg effect almost a century ago, the field of research has developed significantly, and in recent times researchers such as Dr. Thomas Seyfried have played a crucial role in reviving and further developing the metabolic theory of cancer.

Significant Challenges Ahead

Despite these advances, there are still significant challenges that must be overcome in order to realize the full potential of metabolically targeted cancer treatment. Achieving sufficient selectivity for cancer cells, minimizing toxicity to normal cells, understanding and overcoming the complex mechanisms of resistance development, and effectively translating promising preclinical results into broad clinical success remain central areas of research.

Exciting Opportunities

Research into targeting cancer metabolism, from the early observations of Otto Warburg to the continued and dedicated work of contemporary researchers such as Dr. Thomas Seyfried, continues to promise exciting opportunities for the development of new treatment strategies. His insistence on viewing cancer primarily as a metabolic disease has inspired renewed interest in dietary approaches (as complementary treatment) and has led to clinical trials, especially within aggressive cancer types such as glioblastoma.

In summary, targeting cancer metabolism is a highly promising therapeutic field, and Dr. Thomas Seyfried’s contributions have been crucial in advancing the understanding of the role of diets in this context.

Combined Treatment Strategies

The full potential requires continued intensive research, innovative technological advances, and a shift toward more personalized and combined treatment strategies. The integration of metabolic targeting, including the dietary strategies highlighted by Dr. Seyfried, with other groundbreaking cancer therapies, such as immunotherapy, may open up new and more effective ways of treating this complex and challenging disease.

At the same time, it is crucial to address widespread misconceptions about dietary approaches and ensure that patients receive evidence-based nutritional guidance as an integrated part of their cancer treatment.

See also Nutrition and Diet

See also Integrative Oncology

See also Cancer as a Metabolic Disorder

To be continued…

References

Links – Additional

  • Content: Melatonin may reduce abnormal energy metabolism in cancer cells by restoring pyruvate entry into the mitochondria, lowering ROS levels, and inhibiting tumor growth, making it a potential treatment for cancer.
  • Content: Prof. Dr. Thomas Seyfried discusses cancer as a metabolic disease “fed” by glucose and his theory of “starving” cancer cells through diet and fasting.

Site created: May 12, 2025

What you read on Jeg har Kræft is not a recommendation. Seek competent guidance.

Metabolic Principles in Cancer Treatment
Reference List

On cancer cells’ unique appetite—and how it might be turned against them. (Illustrations should be considered as vignettes.)

Contents, Section 1:

Section 2:

(It has not been verified)

Site created: May 12, 2025

What you read on Jeg har Kræft is not a recommendation. Seek competent guidance.

About the Author & Professional Background

Portrætfoto af Hanne til forsiden.

This article has been prepared and validated by the undersigned, Hanne Kjær Uhlig. I am a registered nurse (1975, with clinical experience until 2013) and hold an M.Arch. (1983, specializing in industrial design), and I taught at DTU (Technical University of Denmark) for a number of years.

Following the loss of my mother to cancer in 2000 and my own cancer diagnosis in 2024, I founded this non-profit information site “Jeg har Kræft” (I Have Cancer).

The goal is to use my analytical and academic approach to bring clarity, safety, and scientific evidence to the field of integrative, complementary, and alternative cancer treatment. At the same time, my healthcare experience is utilized to make the articles patient-centered and relevant.

Article characteristics:

  • Clinical and personal background: Created from a combination of decades of experience as a nurse and personal experiences as both a patient and a relative.
  • Scientific methodology: The content is based on systematic research of medical databases and clinical trials. The articles are consistently supported by source references under Links.
  • Independent non-profit project: Operations are funded through voluntary donations and memberships through the Support Association Jeg har Kræft. The site is completely independent of commercial manufacturer interests and works solely to improve the quality of life for cancer patients.
  • The board of directors of the support association consists of:

Community: Join the Facebook group: Jeg har Kræft – Hvad kan jeg gøre? Danish Language only.

What you read on Jeg har Kræft is not a recommendation. Seek professional guidance.