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surgery per se can promote cancer metastasis through a series of local and systemic events

surgery results in a serious wound that disrupts the structural barrier preventing the outspreading of cancer cells, change the properties of the cancer cells and stromal cells remaining in the tumor microenvironment, or impairs the host defense systems against cancers

After the primary tumor is surgically removed, the metastases can start to grow vigorously via neoangiogenesis because the circulating inhibitors disappear

infection and inflammation during the postoperative period have been reported to increase the risk of cancer recurrence in patients

Surgeons have long suspected that surgery, even if it is a necessary step in cancer treatment, facilitates cancer metastasis

Surgery-induced cancer metastasis has been well established in animal models

tumor cell dissemination, tumor-favoring immune responses, and neoangiogenesis

the surgical resection of primary tumors is beneficial is controversial

CTCs abruptly increase just after surgery

Even externally palpitating tumors for diagnosis could increase the numbers of CTCs in skin cancer and breast cancer

excessive glucocorticoids negatively modulate immune functions

immune surveillance against tumors is considered to be impaired by surgical stress

In addition to glucocorticoids, during stimulation of the HPA axis, the catecholamine hormones epinephrine and norepinephrine are released from the adrenal medulla

NK cell suppression may be attributed to increased levels of catecholamines as well as glucocorticoids

In mice bearing a primary tumor, it was observed that the removal of the primary tumor facilitated the growth of highly vascularized metastases

primary tumors may secrete angiogenic inhibitors as well as angiogenic activators

second phase of tumor recurrence and metastasis, which are newly acquired events, rather than just outcomes of incomplete treatment.

double-edged sword

HIF-1 in neutrophils plays a critical role in NETosis and bacteria-killing activity

neutrophils play various roles in the initiation and progression of cancer

NETosis

many inflammatory and neoplastic diseases

formation of neutrophil extracellular traps (NETs), which are large extracellular complexes composed of chromatin and cytoplasmic/granular proteins1

NETosis has been highlighted as an inflammatory event that promotes cancer metastasis

Once activated, neutrophils produce intracellular precursors by using DNA, histones, and granular and cytoplasmic proteins and then spread the mature form of NETs out around themselves

A series of these events is called NETosis.

neutrophil elastase, myeloperoxidase, cathepsin G, proteinase 3, lactoferrin, gelatinase, lysozyme C, calprotectin, neutrophil defensins, and cathelicidins

innate immune response against infection

Neutrophils are the most abundant type of granulocytes, comprising 40–70% of all white blood cells

two types of NEToses, suicidal (or lytic) NETosis and vital NETosis

Suicidal NETosis mainly depends on the production of reactive oxygen species (ROS)

Since neutrophils die during this process, it is called suicidal NETosis.

vital NETosis

vital NETosis occurs independently of ROS production

Vital NETosis can be induced by Gram-negative bacteria. LPS

NETs are present in a variety of cancers, such as lung cancer, colon cancer, ovarian cancer, and leukemia

neutrophils actively undergo NETosis in the tumor microenvironment

Hypoxia

NETosis plays a pivotal role in noninfectious autoimmune diseases,

cytokines

tumor-derived proteases

tumor exosomes

NETosis generally actively progresses in the tumor microenvironment.

the proliferative cytokines TGFβ and IL-10 and the angiogenic factor VEGF are representative of neutrophil-derived tissue repair proteins.

NETosis is a defense system to protect the body from invading pathogens

when neutrophils are excessively stimulated, they produce excess NETs, thereby leading to pathological consequences

plasma levels of NETosis markers are elevated after major surgeries

local invasion, intravasation into the blood or lymphatic vessels, escape from the immune system, anchoring to capillaries in target organs, extravasation into the organs, transformation from dormant cells to proliferating cells, colonization to micrometastases, and growth to macrometastases

NETs promote metastasis at multiple steps

NETs loosen the ECM and capillary wall to promote the intravasation of cancer cells

NETs and platelets wrap CTCs, which protects them from attack by immune cells and shearing force by blood flow

NETs promote the local invasion of cancer cells by degrading the extracellular matrix (ECM)

neutrophil elastase, matrix metalloproteinase 9, and cathepsin G

NETs also promote the intravasation of cancer cells

millions of tumor cells are released into the circulation every day,

NETs can wrap up CTCs with platelets

β1-integrin plays an important role in the interaction between CTCs and NETs

NET-platelet-CTC aggregates.

After metastasizing to distant tissues, tumor cells are often found to remain dormant for a period of time and unexpectedly regrow late

NETs are believed to participate in the reactivation of dormant cancer cells in metastatic regions

NET-associated proteases NE and MMP-9 were found to be responsible for the reactivation of dormant cancer cells

NETosis is a special form of programmed cell death in neutrophils, which is characterized by the extrusion of DNA, histones, and antimicrobial proteins in a web-like structure known as neutrophil extracellular traps (NETs)

increased generation of reactive oxygen species (ROS) is a crucial intracellular process that causes NETosis

Another indirect route of SARS-CoV-2-induced NET production is platelet activation

When NETs are activated in the circulation, they can also induce hypercoagulability and thrombosis

In COVID-19, major NET protein cargos of NETs (i.e., NE, MPO, and histones) are significantly elevated.

SARS-CoV-2 can also infect host cells through noncanonical receptors such as C-type lectin receptors

Immunopathological manifestations, including cytokine storms and impaired adaptive immunity, are the primary drivers behind COVID-19, with neutrophil infiltration being suggested as a significant cause

NETosis and NETs are increasingly recognized as causes of vascular injury

SARS-CoV-2 and its components (e.g., spike proteins and viral RNA) attach to platelets and increase their activation and aggregation in COVID-19, resulting in vascular injury and thrombosis, both of which are linked to NET formation

NET formation may be caused by activated platelets rather than SARS-CoV-2 itself

NETosis, leading to aberrant immunity such as cytokine storms, autoimmune disorders, and immunosuppression.

early bacterial coinfections were more prevalent in COVID-19 patients than those infected with other viruses

NETosis and NETs may also have a role in the development of post COVID-19 syndromes, including lung fibrosis, neurological disorders, tumor growth, and worsening of concomitant disease

NETs and other by-products of NETosis have been shown to act as direct inflammation amplifiers. Hyperinflammation

“cytokine storm”

SARS-CoV-2 drives NETosis and NET formation to allow for the release of free DNA and by-products (e.g., elastases and histones). This may trigger surrounding macrophages and endothelial cells to secrete excessive proinflammatory cytokines and chemokines, which, in turn, enhance NET formation and form a positive feedback of cytokine storms in COVID-19

NET release enables self-antigen exposure and autoantibody production, thereby increasing the autoinflammatory response

patients with COVID-19 who have higher anti-NET antibodies are more likely to be detected with positive autoantibodies [e.g., antinuclear antibodies (ANA) and anti-neutrophil cytoplasmic antibodies (ANCA)]

COVID-19 NETs may act as potential inducers for autoimmune responses

have weakened adaptive immunity as well as a high level of inflammation

tumor-associated NETosis and NETs promote an immunosuppressive environment in which anti-tumor immunity is compromised

NETs have also been shown to enhance macrophage pyroptosis in sepsis

facilitating an immunosuppressive microenvironment

persistent immunosuppression may result in bacterial co-infection or secondary infection

can enhance this process by interacting with neutrophils through toll-like receptor 4 (TLR4), platelet factor 4 (PF4), and extracellular vesicle-dependent processes

NET-induced immunosuppression in COVID-19 in the context of co-existing bacterial infection

Following initial onset of COVID-19, an estimated 50% or more of COVID-19 survivors may develop multi-organ problems (e.g., pulmonary dysfunction and neurologic impairment) or have worsening concomitant chronic illness

NETs in the bronchoalveolar lavage fluid of severe COVID-19 patients cause EMT in lung epithelial cells

decreased E-cadherin (an epithelial marker) expression

COVID-19 also has a long-term influence on tumor progression

Patients with tumors have been shown to be more vulnerable to SARS-CoV-2 infection and subsequent development of severe COVID-19

patients who have recovered from COVID-19 may have an increased risk of developing cancer or of cancer progression and metastasis

awaken cancer cells

NETs have been shown to change the tumor microenvironment

enhance tumor progression and metastasis

vitamin C has been tested in phase 2 clinical trials aimed at reducing COVID-19-associated mortality by reducing excessive activation of the inflammatory response

vitamin C is an antioxidant that significantly attenuates PMA-induced NETosis in healthy neutrophils by scavenging ROS

vitamin C may also inhibit NETosis and NET production in COVID-19

Metformin

Vitamin C

Our data show that ascorbic acid selectively killed cancer but not normal cells, using concentrations that could only be achieved by i.v. administration

Ascorbate-mediated cell death was due to protein-dependent extracellular H2O2 generation, via ascorbate radical formation from ascorbate as the electron donor. Like glucose, when ascorbate is infused i.v., the resulting pharmacologic concentrations should distribute rapidly in the extracellular water space (42). We showed that such pharmacologic ascorbate concentrations in media, as a surrogate for extracellular fluid, generated ascorbate radical and H2O2. In contrast, the same pharmacologic ascorbate concentrations in whole blood generated little detectable ascorbate radical and no detectable H2O2. These findings can be accounted for by efficient and redundant H2O2 catabolic pathways in whole blood (e.g., catalase and glutathione peroxidase) relative to those in media or extracellular fluid

ascorbic acid administered i.v. in pharmacologic concentrations may serve as a pro-drug for H2O2 delivery to the extracellular milieu

H2O2 generated in blood is normally removed by catalase and glutathione peroxidase within red blood cells, with internal glutathione providing reducing equivalents

The electron source for glutathione is NADPH from the pentose shunt, via glucose-6-phosphate dehydrogenase. If activity of this enzyme is diminished, the predicted outcome is impaired H2O2 removal causing intravascular hemolysis, the observed clinical finding.

Only recently has it been understood that the discordant clinical findings can be explained by previously unrecognized fundamental pharmacokinetics properties of ascorbate

Intracellular transport of ascorbate is tightly controlled in relation to extracellular concentration

Intravenous ascorbate infusion is expected to drastically change extracellular but not intracellular concentrations

For i.v. ascorbate to be clinically useful in killing cancer cells, pharmacologic but not physiologic extracellular concentrations should be effective, independent of intracellular ascorbate concentrations.

It is unknown why ascorbate, via H2O2, killed some cancer cells but not normal cells.

There was no correlation with ascorbate-induced cell death and glutathione, catalase activity, or glutathione peroxidase activity.

H2O2, as the product of pharmacologic ascorbate concentrations, has potential therapeutic uses in addition to cancer treatment, especially in infections

Neutrophils generate H2O2 from superoxide,

i.v. ascorbate is effective in some viral infections

H2O2 is toxic to hepatitis C

Use of ascorbate as an H2O2-delivery system against sensitive pathogens, viral or bacterial, has substantial clinical implications that deserve rapid exploration.

Recent pharmacokinetics studies in men and women show that 10 g of ascorbate given i.v. is expected to produce plasma concentrations of nearly 6 mM, which are >25-fold higher than those concentrations from the same oral dose

As much as a 70-fold difference in plasma concentrations is expected between oral and i.v. administration,

Complementary and alternative medicine practitioners worldwide currently use ascorbate i.v. in some patients, in part because there is no apparent harm

Human Burkitt's lymphoma cells

We first investigated whether ascorbate in pharmacologic concentrations selectively affected the survival of cancer cells by studying nine cancer cell lines

Clinical pharmacokinetics analyses show that pharmacologic concentrations of plasma ascorbate, from 0.3 to 15 mM, are achievable only from i.v. administration

plasma ascorbate concentrations from maximum possible oral doses cannot exceed 0.22 mM because of limited intestinal absorption

For five of the nine cancer cell lines, ascorbate concentrations causing a 50% decrease in cell survival (EC50 values) were less than 5 mM, a concentration easily achievable from i.v. infusion

All tested normal cells were insensitive to 20 mM ascorbate.

Lymphoma cells were selected because of their sensitivity to ascorbate

As ascorbate concentration increased, the pattern of death changed from apoptosis to pyknosis/necrosis, a pattern suggestive of H2O2-mediated cell death

Apoptosis occurred by 6 h after exposure, and cell death by pyknosis was ≈90% at 14 h after exposure

In contrast to lymphoma cells, there was little or no killing of normal lymphocytes and monocytes by ascorbate

Ascorbate is transported into cells as such by sodium-dependent transporters, whereas dehydroascorbic acid is transported into cells by glucose transporters and then immediately reduced internally to ascorbate

Whether or not intracellular ascorbate was preloaded, extracellular ascorbate induced the same amount and type of death.

extracellular ascorbate in pharmacologic concentrations mediates death of lymphoma cells by apoptosis and pyknosis/necrosis, independently of intracellular ascorbate.

H2O2 as the effector species mediating pharmacologic ascorbate-induced cell death

Superoxide dismutase was not protective

Because these data implicated H2O2 in cell killing, we added H2O2 to lymphoma cells and studied death patterns using nuclear staining (19, 28). The death patterns found with exogenous H2O2 exposure were similar to those found with ascorbate

For both ascorbate and H2O2, death changed from apoptosis to pyknosis/necrosis as concentrations increased

Sensitivity to direct exposure to H2O2 was greater in lymphoma cells compared with normal lymphocytes and normal monocytes

There was no association between the EC50 for ascorbate-mediated cell death and intracellular glutathione concentrations, catalase activity, or glutathione peroxidase activity

H2O2 generation was dependent on time, ascorbate concentration, and the presence of trace amounts of serum in media

ascorbate radical is a surrogate marker for H2O2 formation.

whatever H2O2 is generated should be removed by glutathione peroxidase and catalase within red blood cells, because H2O2 is membrane permeable

The data are consistent with the hypothesis that ascorbate in pharmacologic concentrations is a pro-drug for H2O2 generation in the extracellular milieu but not in blood.

The occurrence of one predicted complication, oxalate kidney stones, is controversial

In patients with glucose-6-phosphate dehydrogenase deficiency, i.v. ascorbate is contraindicated because it causes intravascular hemolysis

ascorbate at pharmacologic concentrations in blood is a pro-drug for H2O2 delivery to tissues.

ascorbate, an electron-donor in such reactions, ironically initiates pro-oxidant chemistry and H2O2 formation

data here showed that ascorbate initiated H2O2 formation extracellularly, but H2O2 targets could be either intracellular or extracellular, because H2O2 is membrane permeant

More than 100 patients have been described, presumably without glucose-6-phosphate dehydrogenase deficiency, who received 10 g or more of i.v. ascorbate with no reported adverse effects other than tumor lysis