Regenerative and translational medicine in COPD: hype and hope

Pre-clinical studies: from the bench

Experimental evidence from animal models of the migration and homing of mesenchymal precursor cells from bone marrow to the lung was first reported by Pereira et al. [37]. Several authors have subsequently shown the chimerism and migration of bone marrow mononuclear cells (BMMCs) to the lung in experimental models and in bone marrow transplantation in human patients [26]. These results strongly indicate the direction of tests for migration analysis and cell-based therapies in animal models.

Consistent results in experimental cell-based therapy in mice (C57BL/6) with lung injury and subsequent infusion of BMMCs were first reported in 2004 by Yamada et al. [38]. The authors reported the protection of lung parenchyma in animals treated with BMMCs after lipopolysaccharide-induced lung injury. In 2004, Ishizawa et al. [39] reported alveolar regeneration in animals with lipopolysaccharide-induced emphysema that were treated with retinoic acid and granulocyte colony stimulating factor to promote lung regeneration and an increase in BMMC numbers in alveoli; a concomitant treatment with both factors resulted in an additive effect. Rojas et al. [40] showed that infusion of bone marrow-derived mesenchymal stem cells (BM-MSCs) played a role in the repair of bleomycin-injured lungs in mice.

The first study of cell-based therapy with MSCs in an animal model of COPD was conducted in 2006 by Shigemura et al. [41]. Rats underwent emphysema induction by the intratracheal instillation of porcine pancreatic elastase. After 14 days, the treated group received an intravenous infusion of 5×10⁷ MSCs per animal. Alveolar and vascular regeneration, improvements in gas exchange and greater tolerance to exercise were observed when compared with the control group. Since then, various pre-clinical and clinical studies of cell-based therapies for COPD have been published, with several comprehensive and consistent reviews [1, 32, 42–61].

A significant proportion of pre-clinical animal studies of COPD have reported consistent results in terms of the feasibility and efficacy of cell-based therapies with BMMCs and MSCs [1, 47, 56, 62, 63]. Despite these promising findings, animal models have limitations in terms of pathophysiological aspects and the therapeutic translation to human disease. Nonetheless, the consistent results in cell-based therapy in animal models supported the proposition and provided the basis for translational studies and the implementation of cell-based clinical trials in human patients.

Clinical trials: to bedside

The first clinical trial of a cellular therapy in patients with advanced-stage pulmonary emphysema was conducted in Brazil in 2011 by Ribeiro-Paes et al. [64]. In this phase I clinical trial (clinicaltrials.gov identifier: NCT01110252; approved by the Brazilian National Committee of Ethics in Research – CONEP, Report 233/2009), autologous freshly isolated BMMCs were infused in four patients with very severe COPD (GOLD stage IV) out of a total of 10 patients requested in the original project sent to CONEP. All patients underwent stimulation with granulocyte colony stimulating factor for three consecutive days before bone marrow harvest. A total of 1×10⁸ BMMCs were infused per patient in the medial brachial vein. The results showed a slight improvement in forced expiratory volume in 1 s (FEV₁) and forced expiratory volume (FVC) in all patients 30 days post-infusion. After this period, pulmonary function parameters showed a progressive downward trend, returning to pre-procedure baseline values or below. Importantly, during the follow-up period, no serious adverse events were observed that could be directly associated with the BMMC infusion. Complementing this study, Stessuk et al. [5] performed a follow-up of the same patients for to 3 years. Encouraging results were observed in one of these patients (patient IMC 4). During the follow-up period, after 23 months, this patient maintained a stable FEV₁ value and a significant increase in FVC relative to pre-procedure values. During this long follow-up period of patient IMC 4, no adverse events that could be associated with the BMMC infusion procedure were detected, thus corroborating the proposition that cellular therapy with BMMC is safe.

2 years later, the first placebo-controlled randomised trial using MSCs for cell therapy in COPD was published (clinicaltrials.gov identifier: NTC 00683722). This study was sponsored by Osiris Therapeutics Inc. (Columbia, MD, USA) and published by Weiss et al. [65]. In this study, the authors used a pool of nonhuman leukocyte antigen matched MSCs from bone marrow that was commercially registered as Prochymal™ (Osiris Therapeutics Inc.), a pre-manufactured formulation of human MSCs from different donors [66]. Patients enrolled in this study received four monthly infusions (0, 30, 60 and 90 days) of 1×10⁸ MSCs (Prochymal™) per patient or vehicle control and were subsequently followed for 2 years after the first infusion. The results showed a decrease in C-reactive protein (CRP), indicating a possible improvement in the inflammatory process. However, no clinical or laboratory improvements in lung function or the patients’ quality of life were found. No adverse events that were related to the MSC therapy were observed.

In 2016, Stolk et al. [67] published the results of a phase I prospective open-label study for autologous MSC infusion in patients with severe emphysema (clinicaltrials.gov identifier: NCT01306513). Seven patients completed the protocol. They underwent two lung volume reduction surgery (LVRS) procedures and received two autologous BM-MSC infusions, 3 and 4 weeks after the second LVRS. A significant increase in FEV₁ was recorded after 12 months. At the 12-month follow-up, no adverse events were noted. Similar to previous studies, the procedure was considered feasible and safe.

The next year, de Oliveira et al. [68] published a phase I, prospective, patient-blinded, randomised, placebo-controlled study of 10 patients with severe emphysema (clinicaltrials.gov identifier: NCT04018729). In this interesting and innovative study, a one-way endobronchial valve (EBV) insertion was associated with an infusion of allogenic BM-MSCs in patients with severe and very severe COPD (GOLD stages III and IV). Patients (n=5 per group) randomly received either allogeneic BM-MSCs (10⁸ cells) or 0.9% saline solution bronchoscopically immediately before insertion of the one-way EBV. The results showed a systemic decrease in the inflammatory process (CRP) in patients who were treated with an EBV and BM-MSCs. The procedure proved to be safe, but no improvements in the patients’ respiratory parameters were found at the 90-day follow-up.

In 2017, an initial phase I clinical trial by Comella et al. [69] evaluated the early and delayed safety of a stromal vascular fraction (SVF) infusion. In this study, 12 patients were enrolled and received an intravenous infusion of 1.3 and 2.3×10⁸ SVF cells per patient. The SVF approach was innovative and the results showed no adverse effects. It would be important to reassess this study regarding the safety of the infusion volume (1 L), which can lead to cardiorespiratory decompensation when considering the susceptibility of patients with COPD. This protocol was approved by Angeles Hospital (Tijuana, Mexico), but no record of this trial was found on clinicaltrials.gov.

In 2018, Armitage et al. [70] performed a phase I pilot study in a cohort (n=9) of mild-to-very severe stable COPD patients (Australian clinical trials registry no. 12614000731695). The authors evaluated MSC biodistribution and inflammatory and clinical end-points following systemic MSC infusions. The patients received two intravenous infusions of cultured allogeneic BM-MSCs (≈2×10⁶ MSCs·kg⁻¹). The first infusion was performed with radiolabelled cells (indium-111). The second infusion was performed 1 week later with unlabelled cells. The recovered signal was smaller in the emphysematous lung. There was no significant improvement in pulmonary parameters, such as FEV₁ and FVC. In contrast to previous results, there was an increase in CRP levels. However, reductions of several other inflammatory factors were found. The authors hypothesised that these reductions could be attributable to the release of trophic factors, including extracellular vesicles (EVs). Despite no improvements in the spirometric results, the authors concluded that systemic MSC infusions may be useful for attenuating inflammation in COPD patients.

In 2020, Le Thi Bich et al. [71] performed a clinical trial with 20 patients with moderate-to-severe COPD (ISRCTN Register: ISRCTN70443938) [72]. The patients received expanded allogeneic umbilical cord-derived MSCs (UC-MSCs) (1×10⁶ cells·kg⁻¹ infusion) and were followed for 6 months. The authors evaluated different pulmonary function parameters and inflammation (CRP). The results showed a significant decrease in the dyspnoea modified Medical Research Council (mMRC) score and a decrease in the number of exacerbations during the 6-month follow-up. However, no significant improvements in FEV₁, the 6-min walk test or CRP were observed relative to initial values before treatment. In this pioneering pilot clinical study with UC-MSCs, no severe adverse events that were directly related to UC-MSC administration were reported.

Another group from Vietnam published a phase I/II matched case-control trial to evaluate the safety and efficacy of allogeneic human UC-MSCs in patients with moderate-to-severe COPD (clinicaltrials.gov identifier: NCT04433104) [73]. In this study, 40 patients were enrolled and assigned to two age-matched, gender-matched and COPD condition-matched groups (UC-MSC-treated group and control group). This is a very well-structured clinical protocol. It is expected that after conclusion of the trial and publication of the pulmonary function results, this study may provide new data on the safety and therapeutic efficacy of UC-MSCs in COPD patients. Each of these clinical trial procedures are summarised in table 1 and figure 3.

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FIGURE 3

Outline of cell-based therapy methodologies for COPD treatment in nine published clinical trials. Studies by a) Ribeiro-Paes et al. [64] and Stessuk et al. [5], b) Weiss et al. [65], c) Stolk et al. [67], d) de Oliveira et al. [68], e) Armitage et al. [70], f) Le Thi Bich et al. [71], g) Hoang et al. [73] and h) Squassoni et al. [74]. 6MWT: 6-min walk test; AD-MSC: adipose tissue-derived mesenchymal stem cell; BM-MSC: bone marrow-derived mesenchymal stem cell; BMMC: bone marrow mononuclear cell; CBC: complete blood count; CSE: clinical simulation; CT: computed tomography; EBV: endobronchial valve; LVRS: lung volume reduction surgery; PFT: pulmonary function test; UC-MSC: umbilical cord-derived mesenchymal stem cell.

Co-infusion of BMMCs and MSCs: additive or synergistic therapeutic effects

The results with cell-based therapy in COPD reporting morphological regeneration of the parenchyma in pre-clinical animal models and the improvement of pulmonary function parameters in human patients has been attributed to local paracrine effects resulting from the modulation of the inflammatory response and the release of cytokines and growth factors that can stimulate tissue regeneration. Several research groups have proposed that BMMCs are related to neoangiogenesis and tissue neovascularisation, thereby promoting the regeneration of damaged tissue [48, 62, 75–79]. In parallel, there are some consistent results from pre-clinical animal studies that show that MSC from different sources (e.g. bone marrow and adipose tissue) play a modulatory role in the immune response and can attenuate and modulate the inflammatory response by inhibiting the expression of pro-inflammatory cytokines and chemokines, such as interleukin (IL)-1β, IL-6 and tumour necrosis factor-α, and promoting anti-inflammatory cytokines, such as IL-4 and IL-10 [50, 58, 59, 80–87]. Infusions of MSCs may also increase the release of various growth factors, such as vascular endothelial growth factor [77, 78, 81, 83–85, 88–90], fibroblast growth factor 2, hepatocyte growth factor and insulin-like growth factor 1 [58, 59, 83, 84, 86, 88, 91, 92].

Another important effect in the context of COPD is related to a decrease in the synthesis of metalloproteinases (MMP), mainly MMP1, MMP9 and MMP12, in alveolar macrophages that act in the degradation of alveolar walls and thus play a fundamental role in the pathophysiology of pulmonary emphysema [59, 83, 90, 93].

Considering the properties and mechanisms of action of BMMCs and MSCs, we hypothesise that concomitant infusions of BMMCs and MSCs may result in additive or synergistic effects in stimulating neoangiogenesis, decreasing the inflammatory process and delaying disease progression. Starting from this premise, we proposed a new randomised, open and controlled phase I clinical trial. The first end-point was to assess the procedure's safety. As a secondary end-point, we evaluated the efficacy of concomitant infusions of BMMCs and autologous adipose tissue-derived mesenchymal stromal cells (ADSCs) in patients with advanced COPD [74]. The experimental design of this clinical trial is shown in figure 4. This clinical protocol was approved by the National Commission of Ethics in Research (CONEP) in Brazil (Report 926.672) and registered at clinicaltrials.gov (NTC02412332).

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FIGURE 4

Experimental design of the clinical protocol proposed by Squassoni et al. [74]. Reproduced from [74] with permission.

In this study, 20 patients with moderate-to-severe COPD who met the inclusion criteria were enrolled. The patients were randomly distributed into four groups (n=5 per group), as follows: the control group (patients who were maintained on conventional clinical treatment for COPD), the BMMC group (patients who were treated with autologous BM-MSCs), the ADSC group (patients who were treated with ADSCs) and the co-infusion group (patients who received concomitant infusions of ADSCs and BMMCs). The infusions of BMMCs, ADSCs and ADSCs+BMMCs were performed through the middle brachial vein. The total number of cells per infusion was 1×10⁸ cells per patient. Patients who received ADSCs+BMMCs were infused with a total of 5×10⁷ of each cell type. Patients were evaluated relative to the pre-treatment baseline with regard to their biochemical profile, pulmonary function, cardiopulmonary test, radiological examinations, 6-min walk test result and quality of life. The control and treated groups were periodically evaluated for 12 months. No adverse events were detected that were directly related to the BMMC, ADSC and ADSC+BMMC infusion procedures, thus corroborating previous results from our group and other research groups demonstrating that BMMC and ADSC infusions are safe. Regarding efficacy, the best results were obtained for some pulmonary function parameters in the BMMC group (i.e. decrease in partial pressure of CO₂) and the ADSC+BMMC group (i.e. lung capacity, including oxygen uptake and diffusing capacity of the lung for CO). The small number of patients in each group likely impacted the results and did not allow validation of the hypothesis that co-infusions of BMMCs and ADSCs could result in additive or synergistic therapeutic effects in COPD [74]. Additional studies are needed with more patients to allow more valid and confirmatory assessments of possible additive or synergistic therapeutic effects of concomitant BMMC and ADSC infusions. Despite a number of limitations, this study represents a starting point for the evaluation and review of the influence on the biological and clinical response as a function of the source of MSCs employed.

Clinical trials registered at clinicaltrials.gov

Approximately 5100 clinical trials for stem cell/cell therapy are registered at clinicaltrials.gov (accessed: 9 September 2022). Despite notable advances, as well as many potentially promising results and well-conducted studies with regard to the safety of stem cell-based therapies, there is still no broad consolidation of clinical efficacy [60]. In the literature and the clinicaltrials.gov database, there is a marked predominance of studies that have as an end-point or outcome measure the safety of clinical protocols (phase I). For COPD, there are 22 studies that are registered in clinicaltrials.gov, as shown in table 2. Most of these studies used MSCs from different sources (adipose tissue and umbilical cord), with a predominance of phase I or phase I/II studies.

Therapeutic potential of cell-based therapy: issues to be better understood

A consistent result in all the previously published clinical trials of cell therapy in COPD patients refers to safety of the procedure. No notable adverse effects were described during the different follow-up periods in any of the previously published protocols, which ranged from 3 to 30 months [64, 65, 67, 68, 70–72, 74]. However, several questions remain unanswered about the cell-based therapies’ effectiveness and mechanisms of action, especially for MSCs from different sources [60, 94, 95].

Among the numerous issues that need to be better understood regarding the therapeutic potential of cell-based regenerative medicine for COPD are the tissue of origin, intrinsic factors of the donor/recipient, culture conditions, the number of passages during the cell proliferation process, dose and timing of administration (acute or chronic phase of the disease), the route of administration (intratracheal or intravenous), and conditions related to the homing and engraftment of infused cells [33, 74, 95]. Some of the answers to these questions may come from new pre-clinical study models, as well as from new clinical trials that can objectively and unquestionably prove clinical efficacy.

Standardisation of cell culture protocols

One important aspect that requires better evaluation and standardisation among different research groups is linked to the cultivation conditions of protocols of cell therapy for COPD, particularly the number of passages of MSCs during the cell proliferation phase. In cell therapy procedures, many cells are necessary to achieve the desired therapeutic effect. Ex vivo cell proliferation represents an artificial and inhospitable condition for the cell, which can result in genetic instability and a risk of genotoxic effects [57, 96].

Dose and timing of infusion

The dose and infusion timing that have been adopted in clinical protocols for COPD/emphysema have been extrapolated from results of experimental models, especially in rats and mice, and previous studies of cell-based therapies in other human pathologies, such as myocardial infarction [97, 98]. Kim et al. [99] performed a comparative analysis between different doses in an experimental model of elastase-induced emphysema in C57BL/6J mice. Doses of the order of 5×10⁴ MSCs exerted a significant effect on the emphysematous mouse lung. Kennelly et al. [100] proposed that the most effective doses in an animal model would be between 5×10⁴ and 5×10⁵ cells per mouse. In clinical trials of human patients that have been published to date, doses of 1×10⁸ BMMCs per patient were used [5, 64]. The same dose of MSCs was used in the study with Prochymal™ [65]. In the clinical trial by Stolk et al. [67], 1–2×10⁶ BM-MSCs·kg⁻¹ was used. Equivalent doses were used in the nine published protocols with human patients. However, controversies remain about dose-response effects. Kennelly et al. [100] showed that doses above 10⁵ cells per mouse are less effective. In Crohn's disease, for example, high doses were shown to not improve therapeutic efficacy [101]. The issue of dosage is one aspect that needs to be reviewed in human therapy, considering that the number of cells that are used in clinical trials is much lower than in mouse models. Considering the standard mouse weight of 20 g, the range of effective doses in mice that was proposed by Kim et al. [99] and Kennelly et al. [100] would correspond to patients who weigh 70 kg. By extrapolation, the human dose would be approximately 1.8–18 times higher than in clinical studies of COPD [64, 65, 67, 68, 70, 71, 74].

With regard to timing of the infusion, there is no consensus in the literature about the disease stage that best responds to BMMC or MSC infusions. Considering the anti-inflammatory effect of MSCs and considering the chronicity of inflammation in COPD, two approaches can be proposed. Therapeutic efficacy could be maximised if treatment is initiated in the acute phase, thereby limiting progression of the disease. In the case of diagnosis in more advanced or severe phases of the disease with repeated exacerbations (which are more common in COPD), chronic therapy with repeated infusions could be adopted. In animal models, Richardson et al. [97] compared the immediate and late administration of two doses of MSCs in a rat model of myocardial infarction. The authors used allogeneic MSCs (1×10⁶ “low” dose or 2×10⁶ “high” dose) by trans-epicardial injection immediately after myocardial infarction (“early-low” and “early-high”) or 1 week later (“late-low” and “late-high”). The results showed that the therapeutic effects of MSC infusions that occurred after acute myocardial infarction are strongly influenced by the timing of cell delivery, with dose-dependent effects that are most evident with early intervention. Similar results were reported by Kennelly et al. [100], indicating that the effectiveness of treatment with MSCs is time dependent and more effective in the acute phase, but lung function may improve when therapy is introduced in the chronic phase; in this case, however, it has lower efficacy.

The results of Longhini-dos-Santos et al. [85] found time-dependent morphological improvements in the lung parenchyma (mean alveolar diameter) in mice with induced emphysema that were treated with BMMCs 7, 14 and 21 days after intranasal porcine elastase administration, but the response was directly proportional to the infusion time, which was contrary to the results that are reported above. The best and most statistically significant response was obtained with BMMC infusion after 21 days. Wang et al. [98] published a systematic review and meta-analysis of the ideal time and dose for MSC infusion to obtain the best end-points in patients with acute myocardial infarction. The authors concluded that infusion of no more than 10⁷ MSCs within 1 week after a percutaneous coronary intervention might improve left ventricular systolic function. In human patients, however, further controlled studies of the most appropriate infusion timing are needed. Additionally, a particular problem is related to the fact that COPD is usually diagnosed in symptomatic and later stages of the disease.

Route and multiple infusions

Another aspect that is still scarcely explored in clinical cell therapy protocols for COPD is the possibility of adopting cell therapy with multiple infusions when considering its chronic inflammatory characteristics and repeated exacerbations during the clinical course of the disease. Poggio et al. [102] performed a comparative study of the effects of one or two infusions of MSCs that were administered 1 week apart in a mouse model of elastase-induced emphysema. The results showed that both one and two doses of MSCs improved lung function, but two doses resulted in improvements in ventilatory mechanics, histological recovery of the lung parenchyma and the recovery of cardiac function in animals with elastase-induced emphysema. A clinical trial by Weiss et al. [65] repeatedly infused Prochymal™ and found no improvements in any of the analysed clinical parameters, with the exception of a drop in CRP levels in treated patients compared with controls.

Hoang et al. [73] published a very well-designed phase I/II clinical trial of the safety and efficacy of UC-MSC infusions in 20 COPD patients. In this clinical trial, patients received two intravenous infusions of 1×10⁶ cells·kg⁻¹ at a 3-month interval between the first and the second dose. It is hoped that consistent data on the use of UC-MSCs for COPD will be added to the literature with the publication of these results. In a study that was published by our group that assessed the safety (phase I) of cell therapy, improvements in FEV₁ and FVC were observed 30 days after intravenous BMMC infusion in the brachial vein. After this period, there was a progressive decrease in pulmonary function parameters, which returned to pre-treatment values in the four patients who underwent the procedure [64]. These findings suggest the possibility of maintaining pulmonary function parameters through repeated infusions, but the low number of patients who were enrolled in this phase I study did not allow more thorough analyses of the results. This hypothesis needs to be tested with a greater number of patients to allow more robust statistical analyses.

With regard to the most appropriate cell infusion route, results from animal models of the intra-tracheal instillation of BM-MSCs or ADSCs show that it is safe and effective. Liu et al. [47] suggested that intra-tracheal or intra-bronchial infusion is a preferred and safer route of MSC administration. Our research group adopted the intravenous route for ADSCs [64, 74]. The rationale for using intravenous infusion is based on the principle that the lung acts as a primary cell retention filter in the microvasculature of the lung. This transient trap and homing triggers a paracrine action on the lung parenchyma, stimulating chemotaxis and the release of growth factors and anti-inflammatory cytokines. Additionally, in our view, infusion into a peripheral vein (e.g. brachial) in human patients has fewer risks when considering that patients with COPD are in a borderline unstable pathological condition and intratracheal interventions or intrabronchial infusions can trigger disease exacerbation or serious adverse effects.

Target tissue microenviroment, homing and engraftment of the transplanted cells

Another important aspect that is still debatable refers to possible pathophysiological conditions of donor patients (i.e. heterologous infusions), recipient patients as a whole and target tissue, which may be an inhospitable microenvironment that can compromise the homing, engraftment, viability and survival of transplanted cells [103–108]. Considering that survival and viability of MSCs in target tissue are key factors for the success of cell-based therapies, the biochemical and molecular regulatory mechanisms that are involved in homing and engraftment processes need to be precisely defined to improve the therapeutic efficacy of these cells [103–109]. In addition to these aspects, in the case of COPD, the possible influence of pharmacological therapies, such as bronchodilators and corticosteroids, needs to be considered.

Source and conditions of the donor/receptor cells

Regarding the source of cells for cell therapy (e.g. conditions of donor tissue), Varghese et al. [110] performed a systematic review of the effects of different donor-related factors on ADSC functionality. These authors analysed 41 scientific papers and found that decreases in the proliferation and differentiation potential of ADSCs are directly related to age, a high body mass index, diabetes mellitus, radiation exposure and tamoxifen use. Advanced patient age has also been related to lower angiogenesis capacity [111] and changes in morphological patterns and cellular senescence factors, such as telomere shortening and genetic instability [52, 112–119]. Therefore, these factors may play a key role in therapeutic efficacy. The use of cells from neonatal tissues, such as the placenta and umbilical cord, which have greater differentiation potential and a higher proliferation rate [71, 73, 120], represent an attractive and potentially promising therapeutic alternative for the treatment of COPD. Additionally, the secretome may vary, depending on the origin tissue of MSC donor and recipient patients [58, 59]. Another important aspect that needs to be explored, as pointed out by Glassberg et al. [60], is to identify potential markers and patient phenotypes that correlate with the clinical response of patients who undergo cell-therapy procedures. Hoang et al. [95], in a recently published consistent and comprehensive review, emphasised the impact of MSC sources as a current challenge for MSC-based therapies. A better understanding of the molecular, functional mechanism and phenotypic determinants of the regenerative process of MSCs should broaden perspectives regarding the use and efficacy of cell-based therapy [32, 33, 60, 121].

Lung structure and cell-based regenerative medicine

Lung tissue regeneration is impacted by its complex tissue structure, which is composed of many ramifications and cell types. Furthermore, COPD and emphysema are diseases with a multifactorial aetiopathogenesis. The clinical course of these diseases is impacted by interactions among environmental, epigenetic and genetic factors that are patient specific [1, 4, 74, 122]. The lung represents a particular challenge in the context of tissue engineering and regenerative and translational medicine. As proposed by Squassoni et al. [74], new studies and well-designed randomised trials with large numbers of patients that allow statistically significant results and consistently support the initiation of randomised phase III, placebo-controlled clinical trials and large national and international multicentre collaborative studies of cell therapy for COPD are needed [32].

Due to the complex factors described above, advances in our knowledge of the cell therapies for COPD have occurred slowly. However, significant advances in terms of both safety and therapeutic efficacy have been made for other inflammatory conditions, such as graft-versus-host disease [123, 124], perianal fistulas and Crohn's disease [101, 125–127]. These and other promising advances in our understanding and management of chronic inflammatory conditions open up future promising perspectives in regenerative medicine and new clinical trials of cell-based therapies for COPD.